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GIFT OF 
 ASTRONOMICAL SOCIETY OF THE 
 
J BR A R Y 
 
 OF THE 
 
 AL SOCIETY 
 Ci-Th'Z PAC5FIC 
 
 O -2 !",' 
 
THE 
 
 PHILOSOPHY 
 
 OF THE 
 
 INDUCTIVE SCIENCES, 
 
 FOUNDED UPON THEIR HISTORY. 
 
 BY WILLIAM VHEWELL, D.D., 
 
 p 
 
 MASTER OF TRINITY COLLEGE, CAMBRIDGE. 
 
 A NEW EDITION, 
 
 WITH CORRECTIONS AND ADDITIONS, AND 
 AN APPENDIX, CONTAINING 
 
 PHILOSOPHICAL ESSAYS PREVIOUSLY PUBLISHED. 
 
 IN TWO VOLUMES. : f .'/ 
 
 VOLUME THE FIEST, 
 
 LONDON: 
 JOHN W. PARKER, WEST STRAND. 
 
 M.DCCC.XLVII. 
 
M I 
 
 Attro 
 
 ASTRONOMY 
 
 &fr <A QA&+* 
 
REV. ADAM SEDGWICK, M.A., 
 
 SENIOR FELLOW OF TRINITY COLLEGE, 
 
 WOODWARDIAN PROFESSOR OF GEOLOGY IN THE UNIVERSITY OF 
 CAMBRIDGE, AND PREBENDARY OF NORWICH. 
 
 MY DEAR SEDGWICK, 
 
 WHEN I showed you the last sheet of my History of the In- 
 ductive Sciences in its transit through the press, you told me that 
 I ought to add a paragraph or two at the end, by way of Moral 
 to the story ; and I replied that the Moral would be as long as 
 the story itself. The present work, the Moral which you then 
 desired, I have, with some effort, reduced within a somewhat 
 smaller compass than I then spoke of; and I cannot dedicate it 
 to any one with so much pleasure as to you. 
 
 It has always been my wish that, as far and as long as men 
 might know anything of me by my writings, they should hear of me 
 along with the friends with whom I have lived, whom I have loved, 
 and by whose conversation I have been animated to hope that I 
 too might add something to the literature of our country. There 
 is no one whose name has, on such grounds, a better claim than 
 yours to stand in the front of a work, which has been the subject 
 of my labours for no small portion of our long period of friend- 
 ship. But there is another reason which gives a peculiar pro- 
 priety to this dedication of my Philosophy to you. I have little 
 doubt that if your life had not been absorbed in struggling 
 with many of the most difficult problems of a difficult science, 
 you would have been my fellow-labourer or master in the work 
 which I have here undertaken. The same spirit which dictated 
 your vigorous protest against some of the errours which I also 
 attempt to expose, would have led you, if your thoughts had been 
 
 e2 
 
 701543 
 
IV DEDICATION. 
 
 more free, to take a leading share in that Reform of Philosophy, 
 which all who are alive to such errours, must see to be now in- 
 dispensable. To you I may most justly inscribe a work which 
 contains a criticism of the fallacies of the ultra- Lockian school. 
 
 I will mention one other reason which enters into the satisfac- 
 tion with which I place your name at the head of my Philosophy. 
 By doing so, I may consider myself as dedicating it to the College 
 to which we both belong, to which we both owe so much of all 
 that we are, and in which we have lived together so long and so 
 happily; and that, be it remembered, the College of Bacon and of 
 Newton. That College, I know, holds a strong place in your affec- 
 tions, as in mine ; and among many reasons, not least on this 
 account ; we believe that sound and enduring philosophy ever 
 finds there a congenial soil and a fostering shelter. If the doc- 
 trines which the present work contains be really true and valu- 
 able, my unhesitating trust is, that they will spread gradually 
 from these precincts to every part of the land. 
 
 That this office of being the fosterer and diffuser of truth may 
 ever belong to our common Nursing Mother, and that you, my 
 dear Sedgwick, may long witness and contribute to these bene- 
 ficial influences, is the hearty wish of 
 
 Yours affectionately, 
 
 W. WHEWELL. 
 
 Trinity College, May 1. 1840. 
 
PREFACE 
 
 TO THE 
 
 SECOND EDITION. 
 
 IN the Preface to the first edition of this work, it was 
 stated that the work was intended as an application of 
 the plan of Bacon's Novum Organon to the present con- 
 dition of Physical Science. Such an undertaking, it was 
 there said, plainly belongs to the present generation. 
 Bacon only divined how sciences might be constructed ; 
 we can trace, in their history, how their construction 
 has taken place. However sagacious were his conjec- 
 tures, it may be expected that they will be further illus- 
 trated by facts which we know to have really occurred. 
 However large were his anticipations, the actual progress 
 of science since his time may aid in giving comprehen- 
 siveness to our views. And with respect to the methods 
 by which science is to be promoted, the structure and 
 operation of the Organ by which truth is to be collected 
 from nature, we know that, though Bacon's general 
 maxims still guide and animate philosophical enquirers 
 yet that his views, in their detail, have all turned out 
 inapplicable : the technical parts of his method failed in 
 his hands, and are forgotten among the cultivators of 
 science. It cannot be an unfit task, at the present day, 
 to endeavour to extract from the actual past progress 
 of science, the elements of a more effectual and sub- 
 
VI PREFACE TO 
 
 stantial Method of Discovery. The advances which 
 have, during the last three centuries, been made in the 
 physical sciences; in Astronomy, in Physics, in Che- 
 mistry, in Natural History, in Physiology ; these are 
 allowed by all to be real, to be great, to be striking : 
 may it not be, then, that these steps of progress have 
 in them something alike? that in each advancing move- 
 ment there is some common process, some common prin- 
 ciple? that the organ by which discoveries have been 
 made has had something uniform in its structure and 
 working ? If this be so, and if we can, by attending to 
 the past history of science, discover something of this 
 common element and common process in all discoveries, 
 we shall have a Philosophy of Science, such as our times 
 may naturally hope for : we shall have the New Organ 
 of Bacon, renovated according to our advanced intellec- 
 tual position and office. 
 
 It was with the view to such a continuation and 
 extension of Bacon's design, that I undertook that sur- 
 vey of the History of Science which I have given in 
 another work ; and that analysis of the advance of each 
 science which the present work contains. Of the doc- 
 trines promulgated by Bacon, none has more completely 
 remained with us, as a stable and valuable truth, than 
 his declaration that true knowledge is to be obtained 
 from Facts by Induction : and in order to denote that I 
 start at once from the point to which Bacon thus led us, 
 I have, both in the History and in the Philosophy, termed 
 the sciences with which I have to do, the Inductive Sci- 
 ences. By treating of the Physical Sciences only, while 
 I speak of the Inductive Sciences in the description of 
 
THE SECOND EDITION. Vli 
 
 my design, I do not, (as I have already elsewhere said"*) 
 intend to deny the character of Inductive Sciences to 
 many other branches of knowledge, as for instance, Eth- 
 nology, Glossology, Political Economy, and Psychology. 
 But I think it will be allowed that by taking, as I have 
 done, the Physical Sciences alone, in which the truths 
 established are universally assented to, and regarded with 
 comparative calmness, we are better able to discuss the 
 formal conditions and general processes of scientific 
 discovery, than we could do if we entangled ourselves 
 among subjects where the interest is keener and the 
 truth more controverted. Perhaps a more exact descrip- 
 tion of the present -work would be, The Philosophy of 
 the Inductive Sciences, founded upon the History of the 
 principal Physical Sciences. 
 
 I am well aware how much additional interest and 
 attractiveness are given to speculations concerning the 
 progress of human knowledge, when we include in them, 
 as examples of such knowledge, views on subjects of 
 politics, morals, beauty in art and literature, and the like. 
 Prominent instances of the effect of this mode of treating 
 such subjects have recently appeared. But I still think 
 that the real value and import of Inductive Philosophy, 
 even in its application to such subjects, are best brought 
 into view by making the progress of political, and moral 
 and callesthetical-\ truth a subject of consideration apart 
 from physical science. 
 
 It can hardly happen that a work which treats of 
 Methods of Scientific Discovery shall not seem to fail in 
 
 * Hist. Iiid. Sci. Second Edition. Note to the Introduction, 
 t Sec Vol. ii. On the Language of Science, Aphorism, xvii. 
 
Vlll PREFACE TO 
 
 the positive results which it offers. For an Art of Dis- 
 covery is not possible. At each step of the progress of 
 science, are needed invention, sagacity, genius ; elements 
 which no Art can give. We may hope in vain, as Bacon 
 hoped, for an organ which shall enable all men to construct 
 scientific truths, as a pair of compasses enables all men 
 to construct exact circles *. The practical results of the 
 Philosophy of Science must, we are persuaded, be rather 
 classification and analysis than precept and method. I 
 think however that the methods of discovery which 
 I have to recommend, though gathered from a wider 
 survey of scientific history, as to subject and as to 
 time, than, (so far as I am aware,) has been elsewhere 
 attempted, are quite as definite and practical as any 
 others which have been proposed ; with the great addi- 
 tional advantage of being the methods by which all great 
 discoveries in physical science really have been made. 
 This may be said, for instance, of the Method of Grada- 
 tion, and the Method of Natural Classification, spoken 
 of Book xin. Chap. vm. ; and in a narrower sense, of 
 the Method of Curves, the Method of Means, the Method 
 of Least Squares, and the Method of Residues, spoken 
 of in Chap. vn. of the same Book. Also the Remarks 
 on the Use of Hypotheses and on the Tests of Hypotheses 
 (Book xi. Chap, v.) point out features which mark the 
 usual course of discovery. 
 
 But undoubtedly one of the principal lessons which 
 
 results from the views here given is that different 
 
 sciences may be expected to advance by different modes 
 
 of procedure, according to their present condition ; and 
 
 * Noe. Ory. Lib. i. A ph. 61. 
 
THE SECOND EDITION. IX 
 
 that, in many of these sciences, an Induction per- 
 formed by any of the methods just referred to, is not 
 the step which we may expect to see next made. 
 Several of the sciences may not be in a condition which 
 fits them for such a Colligation of Facts, (to use the 
 phraseology to which the succeeding analysis has led 
 me. See B. xi. C. i). The Facts may, at the present 
 time, require to be more fully observed, or the Idea by 
 which they are to be colligated may require to be more 
 fully unfolded. 
 
 But in this point also, our speculations are far from 
 being barren of practical results. The Philosophy of 
 each Science, as given in the present work, affords us 
 means of discerning whether that which is needed for 
 the further progress of the Science has its place in the 
 Observations, or in the Ideas, or in the union of the two. 
 If Observations be wanted, the Methods of Observation 
 given in Book xm. Chap. n. may be referred to; if 
 those who are to make the next discoveries need, for 
 that purpose, a developement of their Ideas, the modes 
 in which such a developement has usually taken place 
 are treated of in Chapters in. and iv. of that Book. 
 
 Perhaps one of the most prominent points of this 
 work is the attempt to show the place which discussions 
 concerning Ideas have had in the progress of science. 
 The metaphysical aspect of each of tfye physical sciences 
 is very far from being, as some have tried to teach, an 
 aspect which it passes through previously to the most 
 decided progress of the science. On the contrary, the 
 metaphysical is a necessary part of the inductive move- 
 ment. This, which is evidently so by the nature of the 
 
X PREFACE TO 
 
 case, is proved by a copious collection of historical evi- 
 dences in the first ten Books of the present work. Those 
 Books contain an account of the principal philosophical 
 controversies which have taken place in all the physical 
 sciences, from Mathematics to Physiology ; and these 
 controversies, which must be called metaphysical if any- 
 thing be so called, have been conducted by the greatest 
 discoverers in each science, and have been an essential 
 part of the discoveries made. Physical discoverers have 
 differed from barren speculators, not by having no meta- 
 physics in their heads, but by having good metaphysics 
 while their adversaries had bad ; and by binding their 
 metaphysics to their physics, instead of keeping the two 
 asunder. I trust that the ten Books of which I have 
 spoken are of some value, even as a series of analyses of 
 a number of remarkable controversies ; but I cannot con- 
 ceive how any one, after reading these Books, can fail 
 to see that there is in progressive science a metaphysical 
 as well as a physical element ; ideas, as well as facts, 
 thoughts, as well as things : in short, that the Funda- 
 mental Antithesis, for which I contend, is there most 
 abundantly and strikingly exemplified. 
 
 On the subject of this doctrine of a Fundamental 
 Analysis, which our knowledge always involves, I will 
 venture here to add a remark, which looks beyond the 
 domain of the physical sciences. This doctrine is suited 
 to throw light upon Moral and Political Philosophy, no 
 less than upon Physical. In Morality, in Legislation, in 
 National Polity, we have still to do with the opposition 
 and combination of two Elements ; of Facts and Ideas ; 
 of History, and an Ideal Standard of Action ; of actual 
 
THE SECOND EDITION. xi 
 
 character and position, and of the aims which are placed 
 above the Actual. Each of these is in conflict with the 
 other ; each modifies and moulds the other. We can never 
 escape the control of the first ; we must ever cease to 
 strive to extend the sway of the second. In these cases, 
 indeed, the Ideal Element assumes a new form. It in- 
 cludes the Idea of Duty. The opposition, the action 
 and re-action, the harmony at which we must ever 
 aim, and can never reach, are between what is and what 
 ought to be; between the past or present Fact, and 
 the Supreme Idea. The Idea can never be independ- 
 ent of the Fact, but the Fact must ever be drawn 
 towards the Idea. - The History of Human Societies, 
 and of each Individual, is by the moral philosopher, 
 regarded in reference to this Antithesis ; and thus both 
 Public and Private Morality becomes an actual progress 
 towards an Ideal Form ; or ceases to be a moral reality. 
 
 I have made very slight alterations in the first 
 edition, except that the First Book is remodelled with 
 a view of bringing out more clearly the basis of the 
 work ; this doctrine of the Fundamental Antithesis of 
 Philosophy. This doctrine, and its relation to the rest 
 of the work, have become more clear in the years 
 which have elapsed since the first edition. 
 
 A separate Essay, in which this doctrine was ex- 
 plained, and a few other Essays previously published in 
 various forms, and containing discussions of special 
 points belonging to the scheme of philosophy here de- 
 livered, have attracted some notice, both in this and in 
 other countries. I have therefore added them as an 
 Appendix to the present edition. 
 
Xll PREFACE TO 
 
 I have added a few Notes, in answer to arguments 
 brought against particular parts of this work. I have 
 written these in what I have elsewhere called an im- 
 personal manner; wishing to avoid controversy, so far 
 as justice to philosophical Truth will allow me to do so. 
 
 I have not given any detailed reply to the criticisms 
 of this work' which occur in Mr. Mill's System of Logic. 
 The consideration of these criticisms would be interest- 
 ing to me, and I think would still further establish the 
 doctrines which I have here delivered. But such a dis- 
 cussion would involve me in a critique of Mr. Mill's 
 work ; which if I were to offer to the world, I should 
 think it more suitable to publish separately. 
 
 More than one of my critics has expressed an opinion 
 that when I published this work, I had not given due at- 
 tention to the Cours de Philosophie Positive of M. Comte. 
 I had, and have, an opinion of the value of M. Comte's 
 speculations very different from that entertained by my 
 monitors. I had in the former edition discussed, and, 
 as I conceive, confuted, some of M. Comte's leading 
 doctrines*. In order further to show that I had not 
 lightly passed over those portions of M. Comte's work 
 which had then appeared, I now publish f an additional 
 portion of a critique of the work which, though I had 
 written, I excluded from the former edition. This is 
 printed exactly as it existed in manuscript at the 
 period of that publication. To return to the subject and 
 to take it up in all its extent, would be an undertaking 
 out of the range of a new edition of my published 
 work. 
 
 * B. xi. c. vii. B. xin. c. iv. t B. xn. c. xvi. 
 
THE SECOND EDITION. Xlll 
 
 Bacon delivered his philosophy in Aphorisms ; a 
 series of Sentences which profess to exhibit rather the 
 results of thought than the process of thinking. A 
 mere Aphoristic Philosophy unsupported by reasoning, 
 is not suited to the present time. No writer upon 
 such subjects can expect to be either understood or 
 assented to, beyond the limits of a narrow school, who 
 is not prepared with good arguments as well as magis- 
 terial decisions upon the controverted points of philo- 
 sophy. But it may be satisfactory to some readers to 
 see the Philosophy, to which in the present work we are 
 led, presented in the Aphoristic form. I have therefore 
 placed a Series of Aphorisms at the end of the work. 
 In the former edition these, by being placed at the begin- 
 ning of the work, might mislead the reader ; seeming 
 to some, perhaps, to be put forwards as the grounds, not 
 as the results, of our philosophy. I have also prefixed 
 an analysis of the work, in the form of a Table of Con- 
 tents to each volume. 
 
 In that part of the second volume which treats of 
 the Language of Science, I have made a few alterations 
 and additions, tending to bring my recommendations 
 into harmony with the present use of the best scientific 
 works. 
 
CONTENTS 
 
 OF 
 
 THE FIRST VOLUME. 
 
 PREFACE 
 
 PAGK 
 V 
 
 PART I. 
 
 OF IDEAS, 
 
 BOOK I. 
 OF IDEAS IN GENERAL. 
 
 CHAP. I. INTRODUCTION 
 
 CHAP. II. OF THE FUNDAMENTAL ANTITHESIS OF PHILOSOPHY 
 
 Sect. 1. Thoughts and Things. 
 
 2. Necessary and Experiential Truths 
 
 3. Deduction and Induction .... 
 
 4. Theories and Facts ..... 
 
 5. Ideas and Sensations ..... 
 
 6. Reflexion and Sensation .... 
 
 7- Subjective and Ofy'ective ..... 
 
 8. Matter and Form ..... 
 
 9. Man the Interpreter of Nature 
 
 10. The Fundamental Antithesis is inseparable . 
 
 11. Successive Generalization .... 
 
 CHAP. III. OF TECHNICAL TERMS .... 
 
 Art. 1. Examples. 
 
 2. Use of Terms. 
 
 CHAP. IV. OF NECESSARY TRUTHS .... 
 
 Art. 1. The two Elements of Knowledge, 
 
 2. Shewn by necessary Truths. 
 
 3. Examples of necessary Truths in numbers. 
 
 4. The opposite cannot be distinctly conceived. 
 
 5. Other Examples. 
 
 6. Universal Truths. 
 
 CHAP. V. OF EXPERIENCE 
 
 Art. 1. Experience cannot prove necessary Truths, 
 2. Except when aided by Ideas. 
 
 1 
 16 
 
 19 
 21 
 23 
 24 
 27 
 29 
 33 
 37 
 38 
 46 
 
 51 
 
 54 
 
 62 
 
XVI CONTENTS OF 
 
 PAGE 
 
 CHAP. VI. OF THE GROUNDS OF NECESSARY TRUTHS . . 66 
 
 Art. 1. These Grounds are Fundamental Ideas. 
 
 2. These are to be reviewed. 
 
 3. Definitions and Axioms. 
 
 4. Syllogism, 
 
 5. Produces no new Truths. 
 
 6. Axioms needed. 
 
 7. Axioms depend on Ideas : 
 
 8. So do Definitions. 
 
 9. Idea not completely expressed. 
 
 CHAP. VII. THE FUNDAMENTAL IDEAS ARE NOT DERIVED FROM 
 
 EXPERIENCE ..... 74 
 
 Art. 1. No connexion observed. 
 
 2. Faculties implied in observation. 
 
 3. We are to examine our Faculties. 
 
 CHAP. VIII. OF THE PHILOSOPHY OF THE SCIENCES . . . 78 
 Sciences arranged according to Ideas. 
 
 BOOK II. 
 
 THE PHILOSOPHY OF THE PURE SCIENCES. 
 CHAP. I. OF THE PURE SCIENCES ...... 82 
 
 Art. 1. Geometry, Arithmetic, Algebra, 
 
 2. Are not Inductive Sciences : 
 
 3. Are Mathematical Sciences. 
 
 4. Mixed Mathematics. 
 
 5. Space, Time, Number. 
 
 CHAP. II. OF THE IDEA OF SPACE . ... 84 
 
 Art. 1. Space is an Idea, 
 
 2. Not derived from Experience, 
 
 3. As Geometrical Truth shews. 
 
 4. Space is a Form of Experience. 
 
 5. The phrase not essential. 
 
 CHAP. III. OF SOME PECULIARITIES OP THE IDEA OF SPACE . 88 
 
 Art. 1. Space is not an Abstract Notion. 
 
 2. Space is infinite. 
 
 3. Space is real. 
 
 4. Space is a Form of Intuition. 
 
 5. Figure. 
 
 6. Three Dimensions. 
 
THE FIRST VOLUME. XV11 
 
 PAGE 
 
 CHAP. IV. OF THE DEFINITIONS AND AXIOMS WHICH RELATE TO 
 
 SPACE 91 
 
 Art. 1. Geometry. 
 
 2. Definitions. 
 
 3. Axioms. 
 
 4. Not Hypotheses. 
 
 5. Axioms necessary. 
 
 6. Straight lines. 
 
 7. Planes. 
 
 8. Elementary Geometry. 
 
 CHAP. V. OF SOME OBJECTIONS WHICH HAVE BEEN MADE TO THE 
 
 DOCTRINES STATED IN THE PREVIOUS CHAPTER . 101 
 Art. 1. How is Geometry hypothetical? 
 
 2. "What was Stewart's view ? 
 
 3. " Legitimate filiations " of Definitions. 
 
 4. Is a Definition a complete explanation ? 
 
 5. Are some Axioms Definitions ? 
 
 6. Axiom concerning Circles. 
 
 7. Can Axioms become truisms ? 
 
 8. Use of such. 
 
 CHAP. VI. OF THE PERCEPTION OF SPACE . . . .111 
 
 Art. 1. Which Senses apprehend Space? 
 
 2. Perception of solid figure. 
 
 3. Is an interpretation. 
 
 4. May be analysed. 
 
 5. Outline. 
 
 6. Reversed convexity. 
 
 7- Do we perceive Space by Touch ? 
 
 8. Brown's Opinion. 
 
 9. The Muscular Sense. 
 
 10. Bell's Opinion. 
 
 11. Perception includes Activity. 
 
 12. Perception of the Skiey Dome. 
 
 13. Reid's Idomenians. 
 
 14. Motion of the Eye. 
 J5. Searching Motion. 
 16. . Sensible Spot. 
 
 17- Expressions implying Motion. 
 
 CHAP. VII. OF THE IDEA OF TIME ...'.. 125 
 
 Art. 1. Time an Idea not derived from Experience. 
 
 2. Time is a Form of Experience. 
 
 VOL. I. W. P. 
 
XV111 CONTENTS OF 
 
 PAGE 
 
 Art. 3. Number. 
 
 4. Is Time derived from Motion ? 
 
 CHAP. VIII. OF SOME PECULIARITIES IN THE IDEA OF TIME . . 128 
 
 Art. 1. Time is not an Abstract Notion. 
 
 2. Time is infinite. 
 
 3. Time is a Form of Intuition. 
 
 4. Time is of one Dimension, 
 
 5. And no more. 
 
 6. Rhythm. 
 
 7- Alternation. 
 8. Arithmetic. 
 
 CHAP. IX. OF THE AXIOMS WHICH RELATE TO NUMBER . . 132 
 
 Art. 1. Grounds of Arithmetic. 
 
 2. Intuition. 
 
 3. Arithmetical Axioms, 
 
 4. Are Conditions of Numerical Reasoning 
 
 5. In all Arithmetical Operations. 
 
 6. Higher Numbers. 
 
 CHAP. X. OF THE PERCEPTION OF TIME AND NUMBER . . 135 
 Art. 1. Memory. 
 
 2. Sense of Successiveness 
 
 3. Implies Activity. 
 
 4. Number also does so. 
 
 5. And apprehension of Rhythm. 
 
 Note to Chapter X . . 139 
 
 CHAP. XI. OF MATHEMATICAL REASONING . . . 141 
 
 Art. 1. Discursive Reasoning. 
 
 2. Technical Terms of Reasoning. 
 
 3. Geometrical Analysis and Synthesis. 
 
 CHAP. XII. OF THE FOUNDATIONS OF THE HIGHER MATHEMATICS 145 
 
 Art. 1. The Idea of a Limit. 
 
 2. The use of General Symbols. 
 
 3. Connexion of Symbols and Analysis. 
 
 CHAP. XIII. THE DOCTRINE OF MOTION . . . . 150 
 
 Art. 1. Pure Mechanism. 
 2. Formal Astronomy. 
 
 CHAP. XIV. OF THE APPLICATION OF MATHEMATICS TO THE 
 
 INDUCTIVE SCIENCES 153 
 
 Art. 1. The Ideas of Space and Number are clear from the 
 first. 
 
THE FIRST VOLUME XIX 
 
 PAGK 
 
 Art. 2. Their application in Astronomy. 
 
 3. Conic Sections, &c. 
 
 4. Arabian Numerals. 
 
 5. Newton's Lemmas. 
 
 6. Tides. 
 7- Mechanics. 
 
 8. Optics. 
 
 9. Conclusion. 
 
 BOOK III. 
 THE PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 CHAP. I. OF THE MECHANICAL SCIENCES . . . 164 
 
 CHAP. II. OF THE IDEA OF CAUSE . . . . .165 
 
 Art. 1. Not derived from Observation. 
 
 2. As appears by its use. 
 
 3. Cause cannot be observed. 
 
 4. Is Cause only constant succession ? 
 
 5. Other reasons. 
 
 CHAP. III. MODERN OPINIONS RESPECTING THE IDEA OF CAUSE . 701 
 
 Art. 1. Hume's Doctrine. 
 
 2. Stewart and Brown. 
 
 3. Kant. 
 
 4. Relation of Kant and Brown. 
 
 5. Axioms flow from the Idea. 
 
 6. The Idea implies activity in the Mind. 
 
 CHAP. IY. OF THE AXIOMS WHICH RELATE TO THE IDEA OF CAUSE 177 
 
 Art. 1. Causes are Abstract Conceptions. 
 
 2. First Axiom. 
 
 3. Second Axiom. 
 
 4. Limitation of the Second Axiom. 
 
 5. Third Axiom. 
 
 6. Extent of the Third Axiom. 
 
 CHAP. V. OF THE ORIGIN OF OUR CONCEPTIONS OF FORCE AND 
 
 MATTER ...... 185 
 
 Art- 1. Force. 
 
 2. Matter. 
 
 3. Solidity. 
 
 4. Inertia. 
 
 5. Application. 
 
XX CONTENTS OF 
 
 PAGE 
 
 CHAP. VI. OP THE ESTABLISHMENT OP THE PRINCIPLES OF 
 
 STATICS .... 
 
 Art. 1. Object of the Chapter. 
 
 2. Statics and Dynamics. 
 
 3. Equilibrium. 
 
 4. Measure of Statical Forces. 
 
 5. The Center of Gravity. 
 
 6. Oblique Forces. 
 
 7' Force acts at any point of its Direction. 
 
 8. The Parallelogram of Forces 
 
 9. Is a necessary Truth. 
 
 10. Center of Gravity descends. 
 
 11. Stevinus's Proof. 
 
 12. Principle of Virtual Velocities. 
 
 13. Fluids press equally. 
 
 14. Foundation of this Axiom. 
 
 CHAP. VII. OF THE ESTABLISHMENT OF THE PRINCIPLES OF 
 
 DYNAMICS 215 
 
 Art. 1. History. 
 
 2. The First Law of Motion. 
 
 3. Gravity is a Uniform Force. 
 
 4. The Second Law of Motion. 
 
 5. The Third Law of Motion. 
 
 6. Action and Reaction in Moving Bodies. 
 7- D'Alembert's Principle. 
 
 8. Connexion of Statics and Dynamics. 
 
 9. Mechanical Principles grow more evident. 
 10. Controversy of the Measure of Force. 
 
 CHAP. VIII. OF THE PARADOX OF UNIVERSAL PROPOSITIONS 
 
 OBTAINED FROM EXPERIENCE . . 245 
 
 Art. 1. Experience cannot establish necessary Truths ; 
 
 2. But can interpret Axioms 
 
 3. Gives us the Matter of Truths. 
 
 4. Exemplifies Truths. 
 
 5. Cannot shake Axioms. 
 
 6. Is this applicable in other cases ? 
 
 CHAP. IX. OF THE ESTABLISHMENT OF THE LAW OF UNIVERSAL 
 
 GRAVITATION ... . 254 
 
 Art. 1 . General course of the History. 
 2. Particulars as to the Law. 
 
THE FIRST VOLUME. XXI 
 
 PAGE 
 
 Art. 3. As to the Gravity of Matter. 
 
 4. Universality of the Law. 
 
 5. Is Gravity an essential quality ? 
 
 6. Newton's Rule of Philosophizing. 
 7- Hypotheses respecting Gravity. 
 8. Do Bodies act at a distance ? 
 
 CHAP. X. OF THE GENERAL DIFFUSION OF CLEAR MECHANICAL 
 
 IDEAS 262 
 
 Art. ]. Nature of the Process 
 
 2. Among the Ancients. 
 
 3. Kepler, &c. 
 
 4. Lord Monboddo, &c. 
 
 5. Schelling, &c. 
 
 6. Common usage. 
 7- Effect of Phrases. 
 
 8. Contempt of Predecessors. 
 
 9. Less detail hereafter. 
 
 10. Mechanico-Chemical Sciences. 
 
 11. Secondary Mechanical Sciences. 
 
 Additional Note to Chapter IV. On the Axioms which relate to 
 
 the Idea of Cause 274 
 
 Additional Note to Chapter VI. Sect. 5. On the Center of Gravity 275 
 
 BOOK IV. 
 
 THE PHILOSOPHY OF THE SECONDARY MECHANICAL 
 SCIENCES. 
 
 CHAP. I. OF THE IDEA OF A MEDIUM AS COMMONLY EMPLOYED . 277 
 Art. 1. Of Primary and Secondary Qualities. 
 
 2. The Idea of Externality. 
 
 3. Sensation by a Medium. 
 
 4. Process of Perception of Secondary Qualities. 
 
 CHAP. II. ON PECULIARITIES IN THE PERCEPTIONS OF THE DIF- 
 FERENT SENSES ....... 286 
 
 Art. 1. Difference of Senses. 
 Sect. I. Prerogatives of Sight. 
 Art. 2. Position. 
 3. Distance. 
 
Xxii CONTENTS OF 
 
 PAGE 
 
 Sect. II. Prerogatives of Hearing. 
 Art. 4. Musical Intervals. 
 
 5. Chords. 
 
 6. Rhythm. 
 
 Sect. III. The Paradoxes of Vision. 
 
 Art. 7- First Paradox. 
 
 8. Second Paradox. 
 
 9. The same for near Objects. 
 10. Objections answered. 
 
 Sect. IV. The Perception of Visible Figures. 
 Art. 11. Brown's Opinion. 
 
 CHAP. III. SUCCESSIVE ATTEMPTS AT THE SCIENTIFIC APPLICA- 
 TION OF THE IDEA OF A MEDIUM 307 
 Art. 1. Introduction. 
 
 2. Sound. 
 
 3. Light. 
 
 4. Heat. 
 
 CHAP. IV. OF THE MEASURE OF SECONDARY QUALITIES 
 Sect. I. Scales of Qualities in General. 
 Art. 1. Intensity. 
 
 2. Quantity and Quality. 
 
 Sect. II. The Musical Scale. 
 
 Art. 3. Musical Relations. 
 
 4. Musical Standard. 
 
 Sect. III. Scales of Colour. 
 
 Art. 5. The Prismatic Scale. 
 
 6. Newton's Scale. 
 
 7. Scales of Impure Colours. 
 
 8. Chromatometer. 
 
 Sect., IV. Scales of Light. 
 Art. 9. Photometer. 
 
 10. Cyanometer. 
 
 Sect. V. Scales of Heat. 
 
 Art. 11. Thermometers. 
 
 12. Their progress. 
 
 13. Fixed Points. 
 
 14. Concordance of Thermometers. 
 
 15. Natural Measure. 
 
THE FIRST VOLUME. XX111 
 
 PAGE 
 
 Art. 16. Law of Cooling. 
 
 17. Theory of Exchanges. 
 
 18. Air Thermometer. 
 
 19. Theory of Heat. 
 
 20. Other Instruments. 
 
 Sect. VI. Scales of other Quantities. 
 Art. 21. Tastes and Smells. 
 
 22. Quality of Sounds. 
 
 23. Articulate Sounds. 
 
 24. Transition. 
 
 BOOK V. 
 
 OF THE PHILOSOPHY OF THE MECHANICO-CHEMICAL 
 SCIENCES. 
 
 CHAP. I. ATTEMPTS AT THE SCIENTIFIC APPLICATION OF THE IDEA 
 
 OF POLARITY ....... 345 
 
 Art. 1. Introduction of the Idea. 
 
 2. Magnetism. 
 
 3. Electricity. 
 
 4. Voltaic Electricity. 
 
 5. Light. 
 
 6. Crystallization. 
 
 7- Chemical Affinity. 
 8. General Remarks. 
 9.' Like repels like. 
 
 CHAP. II. OF THE CONNEXION OF POLARITIES . . 357 
 
 Art. 1. Different Polar Phenomena from one Cause. 
 
 2. Connexion of Magnetic and Electric Polarity. 
 
 3. Ampere's Theory. 
 
 4. Faraday's views. 
 
 5. Connexion of Electrical and Chemical Polarity. 
 
 6. Davy's and Faraday's views 
 
 7. Depend upon Ideas as well as Experiments. 
 
 8. Faraday's Anticipations. 
 
 9. Connexion of Chemical and Crystalline Polarities. 
 
 10. Connexion of Crystalline and Optical Polarities. 
 
 11. Connexion of Polarities in general. 
 
 12. Schelling's Speculations. 
 
 13. Hegel's vague notions. 
 
 14. Ideas must guide Experiment. 
 
XXIV CONTENTS OF 
 
 PAGE 
 
 BOOK VI. 
 
 THE PHILOSOPHY OF CHEMISTRY. 
 CHAP. I. ATTEMPTS TO CONCEIVE ELEMENTARY COMPOSITION . 376 
 
 Art. 1. Fundamental Ideas of Chemistry. 
 
 2. Elements. 
 
 3. Do Compounds resemble their Elements? 
 
 4. The Three Principles. 
 
 5. A Modern Errour. 
 
 6. Are Compounds determined by the Figure of Ele- 
 
 ments ? 
 
 7. Crystalline Form depends on Figure of Elements. 
 
 8. Are Compounds determined by Mechanical Attrac- 
 
 tion of Elements ? 
 
 9. Newton's followers. 
 
 10. Imperfection of their Hypotheses. 
 
 CHAP. II. ESTABLISHMENT AND DEVELOPMENT OF THE IDEA OF 
 
 CHEMICAL AFFINITY 388 
 
 Art. 1. Early Chemists. 
 
 2. Chemical Affinity. 
 
 3. Affinity or Attraction ? 
 
 4. Affinity preferable. 
 
 5. Analysis is possible. 
 
 6. Affinity is Elective. 
 
 7. Controversy on this. 
 
 8. Affinity is Definite. 
 
 9. Are these Principles necessarily true ? 
 10. Composition determines Properties. 
 
 ] 1. Comparison on this subject. 
 
 12. Composition determines Crystalline Form. 
 
 CHAP. III. OF THE IDEA OF SUBSTANCE .... 404 
 Art. \. Indestructibility of Substance. 
 
 2. The Idea of Substance. 
 
 3. Locke's Denial of Substance. 
 
 4. Is all Substance heavy ? 
 
 CHAP. IV. APPLICATION OF THE IDEA OF SUBSTANCE IN CHE- 
 MISTRY 412 
 
 Art. 1. A Body is Equal to its Elements. 
 
 2. Lavoisier. 
 
 3. Are there Imponderable Elements ? 
 
THE FIRST VOLUME. XXV 
 
 PAOK 
 
 Art. 4. Faraday's views. 
 
 5. Composition of Water. 
 
 6. Heat in Chemistry. 
 
 CHAP. V. THE ATOMIC THEORY 421 
 
 Art. 1. The Theory on Chemical Grounds. 
 
 2. Hypothesis of Atoms. 
 
 3. Its Chemical Difficulties. 
 
 4. Grounds of the Atomic Doctrine. 
 
 5. Ancient Atomists. 
 
 6. Francis Bacon. 
 
 7- Modern Atomists. 
 
 8. Arguments for and against. 
 
 9. Boscovich's Theory. 
 
 10. Molecular Hypothesis. 
 
 11. Poisson's Inference. 
 
 12. Wollaston's Argument. 
 
 13. Properties -are Permanent. 
 
 BOOK VII. 
 
 THE PHILOSOPHY OF MORPHOLOGY, INCLUDING 
 CRYSTALLOGRAPHY. 
 
 CHAP. I. EXPLICATION OF THE IDEA OP SYMMETRY . . 439 
 
 Art. 1. Symmetry what. 
 
 2. Kinds of Symmetry. 
 
 3. Examples in Nature. 
 
 4. Vegetables and Animals. 
 
 5. Symmetry a Fundamental Idea. 
 
 6. Result of Symmetry. 
 
 CHAP. II. APPLICATION OF THE IDEA OF SYMMETRY TO CRYSTALS 447 
 Art. 1. " Fundamental Forms." 
 
 2. Their use. 
 
 3. " Systems of Crystallization." 
 
 4. Cleavage. 
 
 5. Other Properties. 
 
 CHAP. III. SPECULATIONS FOUNDED UPON THE SYMMETRY OF 
 
 CRYSTALS 452 
 
 Art. 1. Integrant Molecules 
 
 2. Difficulties of the Theory. 
 
 3. Merit of the Theory. 
 
 4. "Wollaston's Hypothesis. 
 
XXVI CONTENTS OF 
 
 PAGE 
 
 Art. 5. Maxim for such Hypotheses. 
 
 6. Dalton's Hypothesis. 
 
 7. Ampere's Hypothesis. 
 
 8. Difficulty of such Hypotheses. 
 
 9. Isomorphism. 
 
 BOOK VIII. 
 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 CHAP. I. THE IDEA OF LIKENESS AS GOVERNING THE USE OF 
 
 COMMON NAMES 466 
 
 Art. 1. Object of the Chapter. 
 
 2. Unity of the Individual. 
 
 3. Condition of Unity. 
 
 4. Kinds. 
 
 5. Not made by Definitions. 
 
 6. Condition of the Use of Terms. 
 7- Terms may have different Uses. 
 
 8. Gradation of Kinds. 
 
 9. Characters of Kinds. 
 
 10. Difficulty of Definitions. 
 
 11. "The Five Words." 
 
 CHAP. II. THE METHODS OF NATURAL HISTORY, AS REGULATED 
 
 BY THE IDEA OF LIKENESS . 479 
 
 Sect. I. Natural History in General. 
 
 Art. 1. Idea of Likeness in Natural History. 
 2. Condition of its Use. 
 
 Sect. II. Terminology. 
 
 Art. 3. Meaning of the word. 
 
 Sect. III. The Plan of the System. 
 
 Art. 4. Its Meaning. 
 
 5. Latent Reference to Natural Affinity. 
 
 6. Natural Classes. 
 
 7. Artificial Classes. 
 
 8. Are Genera Natural? 
 
 9. Natural History and Mathematics. 
 
 10. Natural Groups given by Type, not by Definition. 
 
 11. Physiography. 
 
 12. Artificial and Natural Systems. 
 
THE FIRST VOLUME. XXV11 
 
 PAGE 
 
 Sect. IV. Methods of framing Natural Systems. 
 
 Art. 13. Method of Blind Trial. 
 
 14. Method of General Comparison. 
 
 Sect. V. Gradation of Groups. 
 
 Art. 15. Series of Subdivisions. 
 
 16. "What is a Species ? 
 
 17- The words " Species" and " Genus." 
 
 18. Varieties. Races. 
 
 Sect. VI. Nomenclature. 
 
 Art. 19. Binary Nomenclature. 
 . Sect. VII. Diagnosis. 
 
 Art. 20. Characteristick and Systematick. 
 
 CHAP. III. APPLICATION OF THE NATURAL HISTORY METHOD TO 
 
 MINERALOGY ....... 512 
 
 Art.}. Mohs's System. 
 
 2. His " Characteristick." 
 
 3. Mineral Species not yet well fixed. 
 
 4. Orders of Minerals. 
 
 5. Nomenclature of Minerals. 
 
 6. M. Necker's " Regne Mineral." 
 
 7- Inconvenience of taking a Chemical basis of Mineral 
 Systems. 
 
 8. Relation of Natural History and Chemistry. 
 
 9. What is a Mineralogical Individual ? 
 
 10. A well-formed Crystal is an Individual. 
 
 11. Not the Integrant Molecules, 
 
 12. Nor the Cleavage Forms. 
 
 13. Compound Crystals are not individuals. 
 
 14. Crystalline Forms are sufficiently complete for this. 
 
 15. Including aggregate Masses. 
 
 16. Do Artificial Crystals belong to Mineralogy ? 
 
 17. The Mineralogical Individual extends as far as 
 
 the same Crystalline Axes extend. 
 
 18. Artificial Crystals do belong to Mineralogy : 
 
 19. Cannot be excluded. 
 
 20. Species to be determined by the Crystalline Power. 
 
 21. Secondary Derivative Forms are Varieties: 
 
 22. Are not Species, as M. Necker holds. 
 
XXV111 CONTENTS OF 
 
 PAGE 
 
 CHAP. IV. OF THE IDEA OF NATURAL AFFINITY 535 
 
 Art. 1. The Idea of Affinity 
 
 2. Is not to be made out by Arbitrary Rules. 
 
 3. Functions of Living things are many, 
 
 4. But all lead to the same arrangement. 
 
 5. This is Cuvier's principle : 
 
 6. And Decandolle's. 
 
 7- Is this applicable to Inorganic Bodies ? 
 8. Yes ; by the agreement of Physical and Chemical 
 Arrangement. 
 
 BOOK IX. 
 
 THE PHILOSOPHY OF BIOLOGY. 
 CHAP. I. ANALOGY OF BIOLOGY WITH OTHER SCIENCES . 543 
 
 Art. 1. Biology involves the Idea of Life. 
 
 2. This Idea to be historically traced. 
 
 3. The Idea at first expressed by means of other Ideas, 
 
 4. Mystical, Mechanical, Chemical, and Vital Fluid 
 
 Hypotheses. 
 
 CHAP. II. SUCCESSIVE BIOLOGICAL HYPOTHESES . . . 548 
 
 Sect. I. The Mystical School. 
 Sect. II. The latrochemical School. 
 Sect. III. The lairomathematical School. 
 Sect. IV. The Vital Fluid School. 
 Sect. V. The Psychical School. 
 
 CHAP. III. ATTEMPTS TO ANALYSE THE IDEA OF LIFE . . 571 
 
 Art. 1. Definitions of Life, 
 
 2. By Stahl, Humboldt, Kant. 
 
 3. Definition of Organization by Kant. 
 
 4. Life is a System of Functions. 
 
 5. Bichat. Sum of Functions. 
 
 6. Use of Definition. 
 
 7. Cuvier's view. 
 
 8. Classifications of Functions. 
 
 9. Vital, Natural, and Animal Functions. 
 
 10. Bichat. Organic and Animal Life. 
 
 11. Use of this Classification. 
 
THE FIRST VOLUME. XXIX 
 
 PAGE 
 
 CHAP. IV. ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL 
 
 FORCES, AND FIRST, OF ASSIMILATION AND SECRE- 
 TION 580 
 
 Sect. I. Course of Biological Research. 
 
 Art. 1. Observation and New Conceptions. 
 
 Sect. II. Attempts to form a distinct Conception of Assimila- 
 tion and Secretion. 
 Art. 2. The Ancients. 
 
 3. Buffon. Interior Mould. 
 
 4. Defect of this view. 
 
 5. Cuvier. Life a Vortex. 
 
 6. Defect of this view. 
 
 7. Schelling. Matter and Form. 
 
 8. Life a constant Form of circulating Matter, &c. 
 
 Sect. III. Attempts to conceive the Forces of Assimilation and 
 
 Secretion. 
 
 Art. 9. Assimilation is a Vital Force. 
 
 10. The name "Assimilation." 
 
 11. Several processes involved in Assimilation. 
 
 12. Absorption. Endosmose. 
 
 13. Absorption involves a Vital Force. 
 
 14. Secretion. Glands. 
 
 15. Motions of Vital Fluids. 
 
 Sect. IV. Attempts to conceive the Process of Generation. 
 
 Art. 16. Reproduction figuratively used for Generation. 
 
 17. Nutrition different from 
 
 18. Generation. 
 
 19. Generations successively included. 
 
 20. Pre-existence of Germs. 
 
 21. Difficulty of this view. 
 
 22. Communication of Vital Forces. 
 
 23. Close similarity of Nutrition and Generation. 
 
 24. The Identity of the two Processes exemplified. 
 
 CHAP. V. ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES, 
 
 continued. VOLUNTARY MOTION . . . (iOO 
 
 Art. 1. Voluntary Motion one of the animal Functions. 
 
 2. Progressive knowledge of it. 
 
 3. Nervous Fluid not electric. 
 
 4. Irritability. Glisson. 
 
 5. Haller. 
 
XXX CONTENTS OF 
 
 PAGE 
 
 Art. 6. Contractility. 
 
 7- Organic Sensibility and Contractility not separable. 
 
 8. Improperly described by Bichat. 
 
 9. Brown. 
 
 10. Contractility a peculiar Power. 
 
 11. Cuvier's view. 
 
 12. Elementary contractile Action. 
 
 13. Strength of Muscular Fibre. 
 
 14. Sensations become Perceptions 
 
 15. By means of Ideas ; 
 
 16. And lead to Muscular Actions. 
 
 17- Volition comes between Perception and Action. 
 
 18. Transition to Psychology. 
 
 19. A center is introduced. 
 
 20. The central consciousness may be obscure. 
 
 21. Reflex Muscular Action. 
 
 22. Instinct. 
 
 23. Difficulty of conceiving Instinct. 
 
 24. Instinct opposed to Insight. 
 
 CHAP. VI. OF THE IDEA or FINAL CAUSES . . . 618 
 
 Art. 1. Organization. Parts are Ends and Means. 
 
 2. Not merely mutually dependent. 
 
 3. Not merely mutually Cause and Effect. 
 
 4. Notion of End not derived from Facts. 
 
 5. This notion has regulated Physiology. 
 
 6. Notion of Design comes from within. 
 7- Design not understood by Savages. 
 
 8. Design opposed to Morphology. 
 
 9. Impression of Design when fresh. 
 
 10. Acknowledgement of an End by adverse Physiolo- 
 
 gists. 
 
 1 1 . This included in the Notion of Disease. 
 
 12. It belongs to Organized Creatures only. 
 
 13. The term Final Cause. 
 
 14. Law and Design. 
 
 15. Final Causes and Morphology. 
 
 16. Expressions of physiological Ends. 
 
 17. The Conditions of Existence. 
 
 18. The asserted presumption of Teleology. 
 
 19. Final Causes in other subjects. 
 
 20. Transition to Palaetiology. 
 
THE FIRST VOLUME. XXXI 
 
 PAGE 
 
 BOOK X. 
 
 THE PHILOSOPHY OF PAIwETIOLOGY. 
 
 CHAP. I. OP PAL^ETIOLOGICAL SCIENCES IN GENERAL . . 637 
 Art. 1. Description of Palaetiology. 
 
 2. Its Members. 
 
 3. Other Members. 
 
 4. Connexion of the whole subject. 
 
 5. We shall take Material Sciences only; 
 
 6. But these are connected with others. 
 
 CHAP. II. OF THE THREE MEMBERS OF A PALJETIOLOGICAL 
 
 SCIENCE . . . . . . . . 642 
 
 Art. 1. Divisions of such Sciences. 
 
 2. The Study of Causes. 
 
 3. jEtiology. 
 
 4. Phenomenology requires Classification. Phenomenal 
 
 Geology., 
 
 5. Phenomenal Uranology. 
 
 6. Phenomenal Geography of Plants and Animals. 
 7- Phenomenal Glossology. 
 
 8. The Study of Phenomena leads to Theory. 
 
 9. No sound Theory without ./Etiology. 
 
 10. Causes in Palsetiology. 
 
 11. Various kinds of Cause. 
 
 12. Hypothetical Order of Palaetiological Causes. 
 
 13. Mode of Cultivating ^Etiology : In Geology : 
 
 14. In the Geography of Plants and Animals : 
 
 15. In Languages. 
 
 16. Construction of Theories. 
 
 17. No sound Palastiological Theory yet extant. 
 CHAP. III. OF THE DOCTRINE OF CATASTROPHES AND THE DOC- 
 TRINE OF UNIFORMITY ..... 665 
 
 Art. 1. Doctrine of Catastrophes. 
 
 2. Doctrine of Uniformity. 
 
 3. Is Uniformity probable a priori ? 
 
 4. Cycle of Uniformity indefinite. 
 
 5. Uniformitarian Arguments are Negative only. 
 
 6. Uniformity in the Organic World. 
 
 7' Origin of the present Organic World. 
 
 8. Nebular Origin of the Solar System. 
 
 9. Origin of Languages. 
 
 10. No Natural Origin discoverable. 
 
XXX11 CONTENTS OF THE FIRST VOLUME. 
 
 PAGE 
 
 CHAP. IV. OF THE RELATION OP TRADITION TO PAL^ETIOLOGY 680 
 
 Art. 1. Importance of Tradition. 
 
 2. Connexion of Tradition and Science. 
 
 3. Natural and Providential History of the World. 
 
 4. The Sacred Narrative. 
 
 5. Difficulties in interpreting the Sacred Narrative. 
 
 6. Such Difficulties inevitable. 
 
 7- Science tells us nothing concerning Creation. 
 
 8. Scientific views, when familiar, do not disturb the 
 
 authority of Scripture. 
 
 9. When should Old Interpretations be given up? 
 
 10. In what Spirit should the Change be accepted ? 
 
 11. In what Spirit should the Change be urged? 
 
 12. Duty of Mutual Forbearance. 
 
 13. Case of Galileo. 
 
 CHAP. V. OF THE CONCEPTION OF A FIRST CAUSE . *uu 
 
 Art. 1. The Origin of things is not naturally discoverable; 
 
 2. Yet has always been sought after. 
 
 3. There must be a First Cause. 
 
 4. This is an Axiom. 
 
 5. Involved in the Proof of a Deity. 
 
 6. The Mind is not satisfied without it. 
 
 7- The Whole Course of Nature must have a Cause. 
 
 8. Necessary Existence of God. 
 
 9. Forms of the Proof. 
 
 10. Idea of a First Cause is Necessary. 
 
 11. Conception of a First Cause. 
 
 12. The First Cause in all Sciences is the same. 
 
 13. We are thus led to Moral Subjects. 
 Conclusion of Part I. 
 
THE 
 
 PHILOSOPHY 
 
 OF THE 
 
 INDUCTIVE SCIENCES. 
 
 PART I. 
 
 OF IDEAS. 
 
 VOL. I. W. P. 
 
Quee adhuc iuventa suiit in Scientiis, ea hujusrnodi sunt 
 ut Notionibus Vulgaribus fere subjaceant : ut vero ad inte- 
 riora et reinotiora Naturae penetretur, necesse est ut tarn 
 NOTIONES quam AXIOMATA magis certa et munita via a 
 particularibus abstrahantur ; atque omnino melior et certior 
 intellectus adoperatio in usum veniat. 
 
 BACON, Nov. Org., Lib. i. Aphor. xviii. 
 
BOOK I. 
 
 OF IDEAS IN GENERAL. 
 
 CHAPTER I. 
 INTRODUCTION. 
 
 THE PHILOSOPHY OF SCIENCE, if the phrase were to be 
 understood in the comprehensive sense which most na- 
 turally offers itself to our thoughts, would imply nothing 
 less than a complete insight into the essence and con- 
 ditions of all real knowledge, and an exposition of the 
 best methods for the discovery of new truths. We must 
 narrow and lower this conception, in order to mould it 
 into a form in which we may make it the immediate 
 object of our labours with a good hope of success ; yet 
 still it may be a rational and useful undertaking, to 
 endeavour to make some advance towards such a Philo- 
 sophy, even according to the most ample conception 
 of it which we can form. The present work has been 
 written with a view of contributing, in some measure, 
 however small it may be, towards such an undertaking. 
 
 But in this, as in every attempt to advance beyond 
 the position which we at present occupy, our hope of 
 success must depend mainly upon our being able to 
 profit, to the fullest extent, by the progress already 
 made. We may best hope to understand the nature and 
 conditions of real knowledge, by studying the nature 
 and conditions of the most certain and stable portions of 
 knowledge which we already possess : and we are most 
 likely to learn the best methods of discovering truth, by 
 VOL, i. w. P. B 
 
2 OF IDEAS IN GENERAL. 
 
 examining how truths, now universally recognized, have 
 really been discovered. Now there do exist among us 
 doctrines of solid and acknowledged certainty, and 
 truths of which the discovery has been received with 
 universal applause. These constitute what we com- 
 monly term Sciences ; and of these bodies of exact and 
 enduring knowledge, we have within our reach so large 
 aniyaHefl'.a; collection, that we may examine them, and 
 ihe., history. of* their formation, with a good prospect of 
 ^derividg-from **the study such instruction as we seek. 
 We may best hope to make some progress towards the 
 Philosophy of Science, by employing ourselves upon THE 
 PHILOSOPHY OF THE SCIENCES. 
 
 The Sciences to which the name is most commonly 
 and unhesitatingly given, are those which are concerned 
 about the material world ; whether they deal with the 
 celestial bodies, as the sun and stars, or the earth and 
 its products, or the elements ; whether they consider the 
 differences which prevail among such objects, or their 
 origin, or their mutual operation. And in all these 
 Sciences it is familiarly understood and assumed, that 
 their doctrines are obtained by a common process of 
 collecting general truths from particular observed facts, 
 which process is termed Induction. It is further assumed 
 that both in these and in other provinces of knowledge, 
 so long as this process is duly and legitimately per- 
 formed, the results will be real substantial truth. And 
 although this process, with the conditions under which 
 it is legitimate, and the general laws of the formation of 
 Sciences, will hereafter be subjects of discussion in this 
 work, I shall at present so far adopt the assumption of 
 which I speak, as to give to the Sciences from which 
 our lessons are to be collected the name of Inductive 
 Sciences. And thus it is that I am led to designate my 
 work as THE PHILOSOPHY OF THE INDUCTIVE SCIENCES. 
 
INTRODUCTION, 3 
 
 The views respecting the nature and progress of 
 knowledge, towards which we shall be directed by such 
 a course of inquiry as I have pointed out, though derived 
 from those portions of human knowledge which are 
 more peculiarly and technically termed Sciences, will by 
 no means be confined, in their bearing, to the domain of 
 such Sciences as deal with the material world, nor even 
 to the whole range of Sciences now existing. On the 
 contrary, we shall be led to believe that the nature of 
 truth is in all subjects the same, and that its discovery 
 involves, in all cases, the like conditions. On one sub- 
 ject of human speculation after another, man's know- 
 ledge assumes that exact and substantial character which 
 leads us to term it Science ; and in all these cases, whe- 
 ther inert matter or living bodies, whether permanent 
 relations or successive occurrences, be the subject of our 
 attention, we can point out certain universal characters 
 which belong to truth, certain general laws which have 
 regulated its progress among men. And we naturally 
 expect that, even when we extend our range of specu- 
 lation wider still, when we contemplate the world within 
 us as well as the world without us, when we consider 
 the thoughts and actions of men as well as the motions 
 and operations of unintelligent bodies, we shall still find 
 some general analogies which belong to the essence of 
 truth, arid run through the whole intellectual universe. 
 Hence we have reason to trust that a just Philosophy of 
 the Sciences may throw light upon the nature and extent 
 of our knowledge in every department of human specu- 
 lation. By considering what is the real import of our 
 acquisitions, where they are certain and definite, we may 
 learn something respecting the difference between true 
 knowledge and its precarious or illusory semblances ; by 
 examining the steps by which such acquisitions have 
 been made, we may discover the conditions under which 
 
 B2 
 
4 OF IDEAS IN GENERAL. 
 
 truth is to be obtained; by tracing the boundary-line 
 between our knowledge and our ignorance, we may 
 ascertain in some measure the extent of the powers of 
 man's understanding. 
 
 But it may be said, in such a design there is nothing 
 new; these are objects at which inquiring men have 
 often before aimed. To determine the difference be- 
 tween real and imaginary knowledge, the conditions 
 under which we arrive at truth, the range of the powers 
 of the human mind, has been a favourite employment of 
 speculative men from the earliest to the most recent 
 times. To inquire into the original, certainty, and com- 
 pass of man's knowledge, the limits of his capacity, the 
 strength and weakness of his reason, has been the pro- 
 fessed purpose of many of the most conspicuous and 
 valued labours of the philosophers of all periods up to 
 our own day. It may appear, therefore, that there is 
 little necessity to add one more to these numerous 
 essays ; and little hope that any new attempt will make 
 any very important addition to the stores of thought 
 upon such questions, which have been accumulated by 
 the profoundest and acutest thinkers of all ages. 
 
 To this I reply, that without at all disparaging the 
 value or importance of the labours of those who have 
 previously written respecting the foundations and con- 
 ditions of human knowledge, it may still be possible to 
 add something to what they have done. The writings of 
 all great philosophers, up to our own time, form a series 
 which is not yet terminated. The books and systems of 
 philosophy which have, each in its own time, won the 
 admiration of men, and exercised a powerful influence 
 upon their thoughts, have had each its own part and 
 functions in the intellectual history of the world ; and 
 other labours which shall succeed these may also have 
 their proper office and useful effect. We may not be 
 
INTRODUCTION. 5 
 
 able to do much, and yet still it may be in our power to 
 effect something. Perhaps the very advances made by 
 former inquirers may have made it possible for us, at 
 present, to advance still further. In the discovery of 
 truth, in the developement of man's mental powers and 
 privileges, each generation has its assigned part ; and it 
 is for us to endeavour to perform our portion of this 
 perpetual task of our species. Although the terms 
 which describe our undertaking may be the same which 
 have often been employed by previous writers to express 
 their purpose, yet our position is different from theirs, 
 and thus the result may be different too. We have, as 
 they had, to run our appropriate course of speculation 
 Avith the exertion of our best powers ; but our course 
 lies in a more advanced part of the great line along 
 which Philosophy travels from age to age. However 
 familiar and old, therefore, be the design of such a work 
 as this, the execution may have, and if it be performed 
 in a manner suitable to the time, will have, something 
 that is new and not unimportant. 
 
 Indeed, it appears to be absolutely necessary, in 
 order to check the prevalence of grave and pernicious 
 errour, that the doctrines which are taught concerning 
 the foundations of human knowledge and the powers of 
 the human mind, should be from time to time revised 
 and corrected or extended. Erroneous and partial views 
 are promulgated and accepted ; one portion of the truth 
 is insisted upon to the undue exclusion of another ; or 
 principles true in themselves are exaggerated till they 
 produce on men's minds the effect of falsehood. When 
 evils of this kind have grown to a serious height, a 
 Reform is requisite. The faults of the existing systems 
 must be remedied by correcting what is wrong, and sup- 
 plying what is wanting. In such cases, all the merits 
 and excellencies of the labours of the preceding times do 
 
6 OF IDEAS IN GENERAL. 
 
 not supersede the necessity of putting forth new views 
 suited to the emergency which has arrived. The new 
 form which errour has assumed makes it proper to 
 endeavour to give a new and corresponding form to 
 truth. Thus the mere progress of time, and the natural 
 growth of opinion from one stage to another, leads to 
 the production of new systems and forms of philosophy. 
 It will be found, I think, that some of the doctrines now 
 most widely prevalent respecting the foundations and 
 nature of truth are of such a kind that a Reform is 
 needed. The present age seems, by many indications, to 
 be called upon to seek a sounder Philosophy of Know- 
 ledge than is now current among us. To contribute 
 towards such a Philosophy is the object of the present 
 work. The work is, therefore, like all works which 
 take into account the most recent forms of speculative 
 doctrine, invested with a certain degree of novelty in its 
 aspect and import, by the mere time and circumstances 
 of its appearance. 
 
 But, moreover, we can point out a very important 
 peculiarity by which this work is, in its design, distin- 
 guished from preceding essays on like subjects ; and this 
 difference appears to be of such a kind as may well 
 entitle us to expect some substantial addition to our 
 knowledge as the result of our labours. The peculiarity 
 of which I speak has already been announced ; it is 
 this : that we purpose to collect our doctrines concerning 
 the nature of knowledge, and the best mode of acquiring 
 it, from a contemplation of the Structure and History of 
 those Sciences (the Material Sciences), which are univer- 
 sally recognized as the clearest and surest examples of 
 knowledge and of discovery. It is by surveying and 
 studying the whole mass of such Sciences, and the 
 various steps of their progress, that we now hope to 
 approach to the true Philosophy of Science. 
 
INTRODUCTION. 7 
 
 Now this, I venture to say, is a new method of pur- 
 suing the philosophy of human knowledge. Those who 
 have hitherto endeavoured to explain the nature of 
 knowledge, and the process of discovery, have, it is true, 
 often illustrated their views by adducing special exam- 
 ples of truths which they conceived to be established, 
 and by referring to the mode of their establishment. 
 But these examples have, for the most part, been taken 
 at random, not selected according to any principle or 
 system. Often they have involved doctrines so pre- 
 carious or so vague that they confused rather than eluci- 
 dated the subject ; and instead of a single difficulty, 
 What is the nature of Knowledge? these attempts at 
 illustration introduced two, What was the true analysis 
 of the Doctrines thus adduced? and, Whether they 
 might safely be taken as types of real Knowledge ? 
 
 This has usually been the case when there have 
 been adduced, as standard examples of the formation of 
 human knowledge, doctrines belonging to supposed sci- 
 ences other than the material sciences; doctrines, for 
 example, of Political Economy, or Philology, or Morals, 
 or the Philosophy of the Fine Arts. I am very far from 
 thinking that, in regard to such subjects, there are no 
 important truths hitherto established : but it would seem 
 that those truths which have been obtained in these 
 provinces of knowledge, have not yet been fixed by 
 means of distinct and permanent phraseology, and sanc- 
 tioned by universal reception, and formed into a con- 
 nected system, and traced through the steps of their 
 gradual discovery and establishment, so as to make them 
 instructive examples of the nature and progress of truth 
 in general. Hereafter we trust to be able to show that 
 the progress of moral, and political, and philological, 
 and other knowledge, is governed by the same laws as 
 that of physical science. But since, at present, the 
 
'8 OF IDEAS IN GENERAL. 
 
 former class of subjects are full of controversy, doubt, 
 and obscurity, while the latter consist of undisputed 
 truths clearly understood and expressed, it may be con- 
 sidered a wise procedure to make the latter class of 
 doctrines the basis of our speculations. And on the 
 having taken this course, is, in a great measure, my 
 hope founded, of obtaining valuable truths which have 
 escaped preceding inquirers. 
 
 But it may be said that many preceding writers on 
 the nature and progress of knowledge have taken their 
 examples abundantly from the Physical Sciences. It 
 would be easy to point out admirable works, which have 
 appeared during the present and former generations, in 
 which instances of discovery, borrowed from the Phy- 
 sical Sciences, are introduced in a manner most happily 
 instructive. And to the works in which this has been 
 done, I gladly give my most cordial admiration. But at 
 the same time I may venture to remark that there still 
 remains a difference between my design and theirs : and 
 that I use the Physical Sciences as exemplifications of 
 the general progress of knowledge in a manner very 
 materially different from the course which is followed in 
 works such as are now referred to. For the conclusions 
 stated in the present work, respecting knowledge and 
 discovery, are drawn from a connected and systematic 
 survey of the whole range of Physical Science and its 
 History ; whereas, hitherto, philosophers have contented 
 themselves with adducing detached examples of scientific 
 doctrines, drawn from one or two departments of science. 
 So long as we select our examples in this arbitrary and 
 limited manner, we lose the best part of that philosophi- 
 cal instruction, which the sciences are fitted to afford 
 when we consider them as all members of one series, 
 and as governed by rules which are the same for all. 
 Mathematical and chemical truths, physical and physio- 
 
INTRODUCTION. 9 
 
 logical doctrines, the sciences of classification and of 
 causation, must alike be taken into our account, in order 
 that we may learn what are the general characters of 
 real knowledge. When our conclusions assume so com- 
 prehensive a shape that they apply to a range of sub- 
 jects so vast and varied as these, we may feel some con- 
 fidence that they represent the genuine form of universal 
 and permanent truth. But if our exemplification is of a 
 narrower kind, it may easily cramp and disturb our phi- 
 losophy. We may, for instance, render our views of 
 truth and its evidence so rigid and confined as to be 
 quite worthless, by founding them too much on the con- 
 templation of mathematical truth. We may overlook 
 some of the most important steps in the general course 
 of discovery, by fixing our attention too exclusively 
 upon some one conspicuous group of discoveries, as, for 
 instance, those of Newton. We may misunderstand the 
 nature of physiological discoveries, by attempting to 
 force an analogy between them and discoveries of me- 
 chanical laws, and by not attending to the intermediate 
 sciences which fill up the vast interval between these 
 extreme terms in the series of material sciences. In 
 these and in many other ways, a partial and arbitrary 
 reference to the material sciences in our inquiry into 
 human knowledge may mislead us ; or at least may fail 
 to give vis those wider views, and that deeper insight, 
 which should result from a systematic study of the whole 
 range of sciences with this particular object. 
 
 The design of the following work, then, is to form a 
 Philosophy of Science, by analyzing the substance and 
 examining the progress of the existing body of the sci- 
 ences. As a preliminary to this undertaking, a survey 
 of the history of the sciences was necessary. This, 
 accordingly, I have already performed; and the result 
 of the labour thus undertaken has been laid before the 
 public as a History of the Inductive Sciences. 
 
10 OF IDEAS IN GENERAL. 
 
 In that work I have endeavoured to trace the steps 
 by which men acquired each main portion of that know- 
 ledge on which they now look with so much confidence 
 and satisfaction. The events which that History relates, 
 the speculations and controversies which are there de- 
 scribed, and discussions of the same kind, far more 
 extensive, which are there omitted, must all be taken 
 into our account at present, as the prominent and 
 standard examples of the circumstances which attend 
 the progress of knowledge. With so much of real his- 
 torical fact before us, we may hope to avoid such views 
 of the processes of the human mind as are too partial 
 and limited, or too vague and loose, or too abstract and 
 unsubstantial, to represent fitly the real forms of dis- 
 covery and of truth. 
 
 Of former attempts, made with the same view of 
 tracing the conditions of the progress of knowledge, that 
 of Bacon is perhaps the most conspicuous : and his 
 labours on this subject were opened by his book on the 
 Advancement of Learning, which contains, among other 
 matter, a survey of the then existing state of knowledge. 
 But this review was undertaken rather with the object 
 of ascertaining in what quarters future advances were to 
 be hoped for, than of learning by what means they were 
 to be made. His examination of the domain of human 
 knowledge was conducted rather with the view of dis- 
 covering what remained undone, than of finding out how 
 so much had been done. Bacon's survey was made for 
 the purpose of tracing the boundaries, rather than of 
 detecting the principles of knowledge. "I will now 
 attempt," he says*, "to make a general and faithful 
 perambulation of learning, with an inquiry what parts 
 thereof lie fresh and waste, and not improved and con- 
 verted by the industry of man ; to the end that such a 
 plot made and recorded to memory, may both minister 
 
 * Advancement of Learning* b. i. p. 74. 
 
INTRODUCTION, 11 
 
 light to any public designation, and also serve to excite 
 voluntary endeavours." Nor will it be foreign to our 
 scheme also hereafter to examine with a like purpose 
 the frontier-line of man's intellectual estate. But the 
 object of our perambulation in the first place, is not so 
 much to determine the extent of the field, as the sources 
 of its fertility. We would learn by what plan and rules 
 of culture, conspiring with the native forces of the boun- 
 teous soil, those rich harvests have been produced which 
 fill our garners. Bacon's maxims, on the other hand, 
 respecting the mode in which he conceived that know- 
 ledge was thenceforth to be cultivated, have little refer- 
 ence to the failures, still less to the successes, which are 
 recorded in his Review of the learning of his time. His 
 precepts are connected with his historical views in a 
 slight and unessential manner. His Philosophy of the 
 Sciences is not collected from the Sciences which are 
 noticed in his survey. Nor, in truth, could this, at the 
 time when he wrote, have easily been otherwise. At 
 that period, scarce any branch of physics existed as a 
 science, except Astronomy. The rules which Bacon gives 
 for the conduct of scientific researches are obtained, as 
 it were, by divination, from the contemplation of sub- 
 jects with regard to which no sciences as yet were. His 
 instances of steps rightly or wrongly made in this path, 
 are in a great measure cases of his own devising. He 
 could not have exemplified his Aphorisms by references 
 to treatises then extant, on the laws of nature ; for the 
 constant burden of his exhortation is, that men up to 
 his time had almost universally followed an erroneous 
 course. And however we may admire the sagacity with 
 which he pointed the way along a better path, we have 
 this great advantage over him ; that we can interrogate 
 the many travellers who since his time have journeyed 
 on this road. At the present day, when we have under 
 
12 OF IDEAS IN GENERAL. 
 
 our notice so many sciences, of such wide extent, so well 
 established ; a Philosophy of the Sciences ought, it must 
 seem, to be founded, not upon conjecture, but upon an 
 examination of many instances ; should not consist of 
 a few vague and unconnected maxims, difficult and 
 doubtful in their application, but should form a system 
 of which every part has been repeatedly confirmed and 
 verified. 
 
 This accordingly it is the purpose of the present 
 work to attempt. But I may further observe, that as 
 my hope of making any progress in this undertaking is 
 founded upon the design of keeping constantly in view 
 the whole result of the past history and present con- 
 dition of science, I have also been led to draw my les- 
 sons from my examples in a manner more systematic 
 and regular, as appears to me, than has been done by 
 preceding writers. Bacon, as I have just said, was led 
 to his maxims for the promotion of knowledge by the 
 sagacity of his own mind, with little or no aid from 
 previous examples. Succeeding philosophers may often 
 have gathered useful instruction from the instances of 
 scientific truths and discoveries which they adduced, but 
 their conclusions were drawn from their instances casu- 
 ally and arbitrarily. They took for their moral any 
 which the story might suggest. But such a proceeding 
 as this cannot suffice for us, whose aim is to obtain a 
 consistent body of philosophy from a contemplation of 
 the whole of Science and its History. For our purpose 
 it is necessary to resolve scientific truths into their con- 
 ditions and ingredients, in order that we may see in 
 what manner each of these has been and is to be pro- 
 vided, in the cases which we may have to consider. This 
 accordingly is necessarily the first part of our task : to 
 analyze Scientific Truth into its Elements. This attempt 
 will occupy the earlier portion of the present work ; and 
 
INTRODUCTION. 1 3 
 
 will necessarily be somewhat long, and perhaps, in many 
 parts, abstruse and uninviting. The risk of such an 
 inconvenience is inevitable ; for the inquiry brings before 
 us many of the most dark and entangled questions in 
 which men have at any time busied themselves. And 
 even if these can now be made clearer and plainer than 
 of yore, still they can be made so only by means of men- 
 tal discipline and mental effort. Moreover this analysis 
 of scientific truth into its elements contains much, both 
 in its principles and in its results, different from the 
 doctrines most generally prevalent among us in recent 
 times : but on that very account this analysis is an 
 essential part of the doctrines which I have now to lay 
 before the reader: and I must therefore crave his 
 indulgence towards any portion of it which may appear 
 to him obscure or repulsive. 
 
 There is another circumstance which may tend to 
 make the present work less pleasing than others on the 
 same subject, in the nature of the examples of human 
 knowledge to which I confine myself; all my instances 
 being, as I have said, taken from the material sciences. 
 For the truths belonging to these sciences are, for the 
 most part, neither so familiar nor so interesting to the 
 bulk of readers as those doctrines which belong to some 
 other subjects. Every general proposition concerning 
 politics or morals at once stirs up an interest in men's 
 bosoms, which makes them listen with curiosity to the 
 attempts to trace it to its origin and foundation. Every 
 rule of art or language brings before the mind of culti- 
 vated men subjects of familiar and agreeable thought, 
 and is dwelt upon with pleasure for its own sake, as well 
 as on account of the philosophical lessons which it may 
 convey. But the curiosity which regards the truths of 
 physics or chemistry, or even of physiology and astro- 
 nomy, is of a more limited and less animated kind. 
 
14 OF IDEAS IN GENERAL. 
 
 Hence, in the mode of inquiry which I have prescribed 
 to myself, the examples which I have to adduce will not 
 amuse and relieve the reader's mind as much as they 
 might do, if I could allow myself to collect them from 
 the whole field of human knowledge. They will have in 
 them nothing to engage his fancy, or to warm his heart. 
 I am compelled to detain the listener in the chilly air 
 of the external world, in order that we may have the 
 advantage of full daylight. 
 
 But although I cannot avoid this inconvenience, so 
 far as it is one, I hope it will be recollected how great 
 are the advantages which we obtain by this restriction. 
 We are thus enabled to draw all our conclusions from 
 doctrines which are universally allowed to be eminently 
 certain, clear, and definite. The portions of knowledge 
 to which 1 refer are well known, and well established 
 among men, Their names are familiar, their assertions 
 uncontested. Astronomy and Geology, Mechanics and 
 Chemistry, Optics and Acoustics, Botany and Physiology, 
 are each recognized as large and substantial collections 
 of undoubted truths. Men are wont to dwell with pride 
 and triumph on the acquisitions of knowledge which 
 have been made in each of these provinces ; and to speak 
 with confidence of the certainty of their results. And all 
 can easily learn in what repositories these treasures of 
 human knowledge are to be found. When, therefore, 
 we begin our inquiry from such examples, we proceed 
 upon a solid foundation. With such a clear ground of 
 confidence, we shall not be met with general assertions 
 of the vagueness and uncertainty of human knowledge ; 
 with the question, What truth is, and How we are to 
 recognize it ; with complaints concerning the hopeless- 
 ness and unprofitableness of such researches. We have, 
 at least, a definite problem before us. We have to 
 examine the structure and scheme, not of a shapeless 
 
INTRODUCTION. 15 
 
 mass of incoherent materials, of which we doubt whether 
 it be a ruin or a natural wilderness, but of a fair and 
 lofty palace, still erect and tenanted, where hundreds of 
 different apartments belong to a common plan, where 
 every generation adds something to the extent and mag- 
 nificence of the pile. The certainty and the constant 
 progress of science are things so unquestioned, that we 
 are at least engaged in an intelligible inquiry, when we 
 are examining the grounds and nature of that certainty, 
 the causes and laws of that progress. 
 
 To this enquiry, then, we now proceed. And in 
 entering upon this task, however our plan or our prin- 
 ciples may differ from those of the eminent philosophers 
 who have endeavoured, in our own or in former times, 
 to illustrate or enforce the philosophy of science, we 
 most willingly acknowledge them as in many things our 
 leaders and teachers. Each reform must involve its own 
 peculiar principles, and the result of our attempts, so 
 far as they lead to a result, must be, in some respects, 
 different from those of former works. But we may still 
 share with the great writers who have treated this 
 subject before us, their spirit of hope and trust, their 
 reverence for the dignity of the subject, their belief in 
 the vast powers and boundless destiny of man. And we 
 may once more venture to use the words of hopeful 
 exhortation, with which the greatest of those who have 
 trodden this path encouraged himself and his followers 
 when he set out upon his way. 
 
 " Concerning ourselves we speak not ; but as touch- 
 ing the matter which we have in hand, this we ask ; 
 that men deem it not to be the setting up an Opinion, 
 but the performing of a Work : and that they receive 
 this as a certainty; that we are not laying the founda- 
 tions of any sect or doctrine, but of the profit and 
 dignity of mankind. Furthermore, that being well dis- 
 
16 OF IDEAS IN GENERAL. 
 
 posed to what shall advantage themselves, and putting 
 off factions and prejudices, they take common counsel 
 with us, to the end that being by these our aids and 
 appliances freed and defended from wanderings and 
 impediments, they may lend their hands also to the 
 labours which remain to be performed : and yet further, 
 that they be of good hope ; neither imagine to them- 
 selves this our Reform as something of infinite dimen- 
 sion, and beyond the grasp of mortal man, when in truth 
 it is the end and true limit of infinite errour ; and is by 
 no means unmindful of the condition of mortality and 
 humanity, not confiding that such a thing can be carried 
 to its perfect close in the space of one single age, but 
 assigning it as a task to a succession of generations." 
 
 CHAPTER II. 
 
 OF THE FUNDAMENTAL ANTITHESIS OF 
 PHILOSOPHY. 
 
 SECT. 1. Thoughts and Things. 
 
 IN order that we may do something towards determining 
 the nature and conditions of human knowledge, (which 
 I have already stated as the purpose of this work,) I 
 shall have to refer to an antithesis or opposition, which 
 is familiar and generally recognized, and in which the 
 distinction of the things opposed to each other is com- 
 monly considered very clear and plain. I shall have to 
 attempt to make this opposition sharper and stronger 
 than it is usually conceived, and yet to shew that the 
 distinction is far from being so clear and definite as it is 
 usually assumed to be : I shall have to point the con- 
 trast, yet shew that the things which are contrasted 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 17 
 
 cannot be separated: I must explain that the anti- 
 thesis is constant and essential, but yet that there is no 
 fixed and permanent line dividing its members. I may 
 thus appear, in different parts of my discussion, to be 
 proceeding in opposite directions, but I hope that the 
 reader who gives me a patient attention will see that 
 both steps lead to the point of view to which I wish to 
 lead him. 
 
 The antithesis or opposition of which I speak is 
 denoted, with various modifications, by various pairs of 
 terms : I shall endeavour to show the connexion of these 
 different modes of expression, and I will begin with that 
 form which is the simplest and most idiomatic. 
 
 The simplest and most idiomatic expression of the 
 antithesis to which I refer is that in which we oppose to 
 each other THINGS and THOUGHTS. The opposition is 
 familiar and plain. Our Thoughts are something which 
 belongs to ourselves; something which takes place 
 within us ; they are what we think ; they are actions of 
 our minds. Things, on the contrary, are something 
 different from ourselves and independent of us ; some- 
 thing which is without us ; they are ; we see them, 
 touch them, and thus know that they exist ; but we do 
 not make them by seeing or touching them, as we make 
 our Thoughts by thinking them ; we are passive, and 
 Things act upon our organs of perception. 
 
 Now what I wish especially to remark is this : that 
 in all human KNOWLEDGE both Thoughts and Things are 
 concerned. In every part of my knowledge there must 
 be some thing about which I know, and an internal act 
 of me who know. Thus, to take simple yet definite parts 
 of our knowledge, if I know that a solar year consists of 
 365 days, or a lunar month of 30 days, I know some- 
 thing about the sun or the moon; namely, that those 
 objects perform certain revolutions and go through cer- 
 VOL. i. w. P. C 
 
18 OF IDEAS IN GENERAL. 
 
 tain changes, in those numbers of days ; but I count 
 such numbers and conceive such revolutions and changes 
 by acts of my own thoughts. And both these elements 
 of my knowledge are indispensable. If there were not 
 such external Things as the sun and the moon I could 
 not have any knowledge of the progress of time as 
 marked by them. And however regular were the mo- 
 tions of the sun and moon, if I could not count their 
 appearances and combine their changes into a cycle, or 
 if I could not understand this when done by other men, 
 I could not know anything about a year or a month. In 
 the former case I might be conceived as a human being, 
 possessing the human powers of thinking and reckoning, 
 but kept in a dark world with nothing to mark the pro- 
 gress of existence. The latter is the case of brute ani- 
 mals, which see the sun and moon, but do not know how 
 many days make a month or a year, because they have 
 not human powers of thinking and reckoning. 
 
 The two elements which are essential to our know- 
 ledge in the above cases, are necessary to human know- 
 ledge in all cases. In all cases, Knowledge implies a 
 combination of Thoughts and Things. Without this 
 combination, it would not be Knowledge. Without 
 Thoughts, there could be no connexion ; without Things, 
 there could be no reality. Thoughts and Things are so 
 intimately combined in our Knowledge, that we do not 
 look upon them as distinct. One single act of the mind 
 involves them both ; and their contrast disappears in 
 their union. 
 
 But though Knowledge requires the union of these 
 two elements, Philosophy requires the separation of 
 them, in order that the nature and structure of Know- 
 ledge may be seen. Therefore I begin by considering 
 this separation. And I now proceed to speak of another 
 way of looking at the antithesis of which I have spoken ; 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 19 
 
 and which I may, for the reasons which I have just 
 mentioned, call the FUNDAMENTAL ANTITHESIS OF PHI- 
 LOSOPHY. 
 
 SECT. 2. Necessary and Experiential Truths. 
 
 MOST persons are familiar with the distinction of ne- 
 cessary and contingent truths. The former kind are 
 Truths which cannot but be true; as that 19 and 11 
 make 30 ; that parallelograms upon the same base and 
 between the same parallels are equal: that all the 
 angles in the same segment of a circle are equal. The 
 latter are Truths which it happens (contingit] are true ; 
 but which, for any thing which we can see, might have 
 been otherwise ; as that a lunar month contains 30 days, 
 or that the stars revolve in circles round the pole. The 
 latter kind of Truths are learnt by experience, and hence 
 we may call them Truths of Experience, or, for the sake 
 of convenience, Experiential Truths, in contrast with 
 Necessary Truths. 
 
 Geometrical propositions are the most manifest ex- 
 amples of Necessary Truths. All persons who have read 
 and understood the elements of geometry, know that the 
 propositions above stated (that parallelograms upon the 
 same base and between the same parallels are equal ; 
 that all the angles in the same segment of a circle are 
 equal,) are necessarily true ; not only they are true, but 
 they must be true. The meaning of the terms being 
 understood, and the proof being gone through, the truth 
 of the propositions must be assented to. We learn these 
 propositions to be true by demonstrations deduced from 
 definitions and axioms ; and when we have thus learnt 
 them, we see that they could not be otherwise. In the 
 same manner, the truths which concern numbers are 
 necessary truths: 19 and 11 not only do make 30, but 
 must make that number, and cannot make anything else. 
 
 C2 
 
20 OF IDEAS IN GENERAL. 
 
 In the same manner, it is a necessary truth that half the 
 sum of two numbers added to half their difference is 
 equal to the greater number. 
 
 It is easy to find examples of Experiential Truths ; 
 propositions which we know to be true, but know by 
 experience only. We know, in this way, that salt will 
 dissolve in water ; that plants cannot live without light ; 
 in short, we know in this way all that we do know 
 in chemistry, physiology, and the material sciences in 
 general. I take the Sciences as my examples of human 
 knowledge, rather than the common truths of daily life, 
 or moral or political truths ; because, though the latter 
 are more generally interesting, the former are much 
 more definite and certain, and therefore better starting- 
 points for our speculations, as I have already said. And 
 we may take elementary astronomical truths as the most 
 familiar examples of Experiential Truths in the domain 
 of science. 
 
 With these examples, the distinction of Necessary 
 and Experiential Truths is, I hope, clear. The former 
 kind, we see to be true by thinking about them, and see 
 that they could not be otherwise. The latter kind, men 
 could never have discovered to be true without looking 
 at them ; and having so discovered them, still no one will 
 pretend to say they might not have been otherwise. For 
 aught we can see, the astronomical truths which express 
 the motions and periods of the sun, moon and stars, 
 might have been otherwise. If we had been placed in 
 another part of the solar system, our experiential truths 
 respecting days, years, and the motions of the heavenly 
 bodies, would have been other than they are, as we 
 know from astronomy itself. 
 
 It is evident that this distinction of Necessary and 
 Experiential Truths involves the same antithesis which 
 we have already considered ; the antithesis of Thoughts 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 21 
 
 and Things. Necessary Truths are derived from our own 
 Thoughts : Experiential Truths are derived from our 
 observation of Things about us. The opposition of 
 Necessary and Experiential Truths is another aspect of 
 the Fundamental Antithesis of Philosophy. 
 
 SECT. 3. Deduction and Induction. 
 
 I HAVE already stated that geometrical truths are 
 established by demonstrations deduced from definitions 
 and axioms. The term Deduction is specially applied 
 to such a course of demonstration of truths from defini- 
 tions and axioms. In the case of the parallelograms 
 upon the same base and between the same parallels, we 
 prove certain triangles to be equal, by supposing them 
 placed so that their two bases have the same extremi- 
 ties; and hence, referring to an Axiom respecting straight 
 lines, we infer that the bases coincide. We combine 
 these equal triangles with other equal spaces, and in this 
 way make up both the one and the other of the paral- 
 lelograms, in such a manner as to shew that they are 
 equal. In this manner, going on step by step, deducing 
 the equality of the triangles from the axiom, and the 
 equality of the parallelograms from that of the triangles, 
 we travel to the conclusion. And this process of suc- 
 cessive deduction is the scheme of all geometrical proof. 
 We begin with Definitions of the notions which we reason 
 about, and with Axioms, or self-evident truths, respecting 
 these notions; and we get, by reasoning from these, other 
 truths which are demonstratively evident ; and from 
 these truths again, others of the same kind, and so on. 
 We begin with our own Thoughts, which supply us with 
 Axioms to start from; and we reason from these, till we 
 come to propositions which are applicable to the Things 
 about us; as for instance, the propositions respecting 
 circles and spheres are applicable to the motions of the 
 
22 OF IDEAS IN GENERAL. 
 
 heavenly bodies. This is Deduction, or Deductive Rea- 
 soning, 
 
 Experiential truths are acquired in a very different 
 way. In order to obtain such truths, we begin with 
 Things. In order to learn how many days there are in. 
 a year, or in a lunar month, we must begin by observing 
 the sun and the moon. We must observe their changes 
 day by day, and try to make the cycle of change fit into 
 some notion of number which we supply from our own 
 Thoughts. We shall find that a cycle of 30 days nearly 
 will fit the changes of phase of the moon; that a cycle 
 of 365 days nearly will fit the changes of daily motion 
 of the sun. Or, to go on to experiential truths of 
 which the discovery comes within the limits of the his- 
 tory of science we shall find (as Hipparchus found) 
 that the unequal motion of the sun among the stars, 
 such as observation shews it to be, may be fitly repre- 
 sented by the notion of an eccentric; a circle in which 
 the sun has an equable annual motion, the spectator not 
 being in the center of the circle. Again, in the same 
 manner, at a later period, Kepler started from more 
 exact observations of the sun, and compared them with 
 a supposed motion in a certain ellipse; and was able to 
 shew that, not a circle about an eccentric point, but an 
 ellipse, supplied the mode of conception which truly 
 agreed with the motion of the sun about the earth ; or 
 rather, as Copernicus had already shewn, of the earth 
 about the sun. In such cases, in which truths are ob- 
 tained by beginning from observation of external things 
 and by finding some notion with which the Things, as 
 observed, agree, the truths are said to be obtained by 
 Induction. The process is an Inductive Process. 
 
 The contrast of the Deductive and Inductive process 
 is obvious. In the former, we proceed at each step 
 from general truths to particular applications of them ; 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 23 
 
 in the latter, from particular observations to a general 
 truth which includes them. In the former case we 
 may be said to reason downwards, in the latter case, 
 upwards; for general notions are conceived as stand- 
 ing above particulars. Necessary truths are proved, 
 like arithmetical sums, by adding together the portions 
 of which they consist. An inductive truth is proved, 
 like the guess which answers a riddle, by its agreeing 
 with the facts described. Demonstation is irresistible 
 in its effect on the belief, but does not produce surprize, 
 because all the steps to the conclusion are exhibited, 
 before we arrive at the conclusion. Inductive infer- 
 ence is not demonstrative, but it is often more striking 
 than demonstrative reasoning, because the intermediate 
 links between the particulars and the inference are not 
 shown. Deductive truths are the results of relations 
 among our own Thoughts. Inductive Truths are re- 
 lations which we discern among existing Things; and 
 thus, this opposition of Deduction and Induction is again 
 an aspect of the Fundamental Antithesis already spoken 
 of. 
 
 SECT. 4. Theories and Facts. 
 
 GENERAL experiential Truths, such as we have just 
 spoken of, are called Theories, and the particular 
 observations from which they are collected, and which 
 they include and explain, are called Facts. Thus Hip- 
 parchus's doctrine, that the sun moves in an eccentric 
 about the earth, is his Theory of the Sun, or the Eccen- 
 tric Theory. The doctrine of Kepler, that the Earth 
 moves in an Ellipse about the Sun, is Kepler s Theory 
 of the Earth, the Elliptical Theory. Newton's doctrine 
 that this elliptical motion of the Earth about the Sun 
 is produced and governed by the Sun's attraction upon 
 the Earth, is the Newtonian theory, the Theory of 
 Attraction. Each of these Theories was accepted, be- 
 
24 OF IDEAS IN GENERAL. 
 
 cause it included, connected and explained the Facts; 
 the Facts being, in the two former cases, the motions 
 of the Sun as observed; and in the other case, the ellip- 
 tical motion of the Earth as known by Kepler's Theory. 
 This antithesis of Theory and Fact is included in what 
 has just been said of Inductive Propositions. A Theory 
 is an Inductive Proposition, and the Facts are the par- 
 ticular observations from which, as I have said, such 
 Propositions are inferred by Induction. The Antithesis 
 of Theory and Fact implies the fundamental Antithesis 
 of Thoughts and Things; for a Theory (that is, a true 
 Theory) may be described as a Thought which is con- 
 templated distinct from Things and seen to agree with 
 them; while a Fact is a combination of our Thoughts 
 with Things in so complete agreement that we do not 
 regard them as separate. 
 
 Thus the antithesis of Theory and Fact involves the 
 antithesis of Thoughts and Things, but is not identical 
 with it. Facts involve Thoughts, for we know Facts only 
 by thinking about them. The Fact that the year consists 
 of 365 days; the Fact that the month consists of 30 days, 
 cannot be known to us, except we have the Thoughts 
 of Time, Number and Recurrence. But these Thoughts 
 are so familiar, that we have the Fact in our mind 
 as a simple Thing without attending to the Thought 
 which it involves. When we mould our Thoughts into a 
 Theory, we consider the Thought as distinct from the 
 Facts; but yet, though distinct, not independent of them; 
 for it is a true Theory, only by including and agreeing 
 with the Facts. 
 
 SECT. 5. Ideas and Sensations. 
 
 WE have just seen that the antithesis of Theory and 
 Fact, although it involves the antithesis of Thoughts and 
 Things, is not identical with it. There are other modes 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 25 
 
 of expression also, which involve the same Fundamental 
 Antithesis, more or less modified. Of these, the pair of 
 words which in their relations appear to separate the 
 members of the antithesis most distinctly are Ideas and 
 Sensations. We see and hear and touch external things, 
 and thus perceive them by our senses; but in perceiving 
 them, we connect the impressions of sense according to 
 relations of space, time, number, likeness, cause, &c. 
 Now some at least of these kinds of connexion, as space, 
 time, number, may be contemplated distinct from the 
 things to which they are applied; and so contemplated, 
 I term them Ideas. And the other element, the impres- 
 sions upon our senses which they connect, are called 
 Sensations. 
 
 I term space, time, cause, &c., Ideas, because they 
 are general relations among our sensations, apprehend- 
 ed by an act of the mind, not by the senses simply. 
 These relations involve something beyond what the 
 senses alone could furnish. By the sense of sight we 
 see various shades and colours and shapes before us, but 
 the outlines by which they are separated into distinct 
 objects of definite forms, are the work of the mind itself. 
 And again, when we conceive visible things, not only as 
 surfaces of a certain form, but as solid bodies, placed at 
 various distances in space, we again exert an act of the 
 mind upon them. When we see a body move, we see 
 it move in a path or orbit, but this orbit is not itself 
 seen; it is constructed by the mind. In like manner 
 when we see the motions of a needle towards a mag- 
 net, we do not see the attraction or force which pro- 
 duces the effects; but we infer the force, by having in 
 our minds the Idea of Cause. Such acts of thought, 
 such Ideas, enter into our perceptions of external things. 
 
 But though our perceptions of external things in- 
 volve some act of the mind, they must involve some- 
 
26 OF IDEAS IN GENERAL. 
 
 thing else besides an act of the mind. If we must exer- 
 cise an act of thought in order to see force exerted, or 
 orbits described by bodies in motion, or even in order 
 to see bodies existing in space, and to distinguish one 
 kind of object from another, still the act of thought 
 alone does not make the bodies. There must be some- 
 thing besides, on mhwli the thought is exerted. A 
 colour, a form, a sound, are not produced by the mind, 
 however they may be moulded, combined, and inter- 
 preted by our mental acts. A philosophical poet has 
 spoken of 
 
 All the world 
 
 Of eye and ear, both what they half create, 
 And what perceive. 
 
 But it is clear, that though they half create, they do not 
 wholly create: there must be an external world of colour 
 and sound to give impressions to the eye and ear, as 
 well as internal powers by which we perceive what is 
 offered to our organs. The mind is in some way passive 
 as well as active: there are objects without as well as 
 faculties within; Sensations, as well as acts of Thought. 
 Indeed this is so far generally acknowledged, that 
 according to common apprehension, the mind is passive 
 rather than active in acquiring the knowledge which 
 it receives concerning the material world. Its sensa- 
 tions are generally considered more distinct than its 
 operations. The world without is held to be more clearly 
 real than the faculties within. That there is some- 
 thing different from ourselves, something external to us, 
 something independent of us, something which no act 
 of our minds can make or can destroy, is held by all 
 men to be at least as evident, as that our minds can 
 exert any effectual process in modifying and appreciating 
 the impressions made upon them. Most persons are 
 more likely to doubt whether the mind be always actively 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 27 
 
 applying Ideas to the objects which it perceives, than 
 whether it perceive them passively by means of Sen- 
 sations. 
 
 But yet a little consideration will show us that an 
 activity of the mind, and an activity according to certain 
 Ideas, is requisite in all our knowledge of external 
 Objects. We see objects, of various solid forms, and at 
 various distances from us. But we do not thus perceive 
 them by sensation alone. Our visual impressions can- 
 not, of themselves, convey to us a knowledge of solid 
 form, or of distance from us. Such knowledge is inferred 
 from what we see : inferred by conceiving the objects 
 as existing in space, and by applying to them the Idea of 
 Space. Again : day after day passes, till they make up a 
 year : but we do not know that the days are 365, except 
 we count them; and thus apply to them our Idea of Num- 
 ber. Again : we see a needle drawn to a magnet : but, 
 in truth, the drawing is what we cannot see. We see the 
 needle move, and infer the attraction, by applying to the 
 fact our Idea of Force, as the cause of motion. Again: 
 we see two trees of different kinds ; but we cannot know 
 that they are so, except by applying to them our Idea 
 of the resemblance and difference which makes kinds. 
 And thus Ideas, as well as Sensations, necessarily enter 
 into all our knowledge of objects : and these two words 
 express, perhaps more exactly than any of the pairs 
 before mentioned, that Fundamental Antithesis, in the 
 union of which, as I have said, all knowledge consists. 
 
 SECT 6. Reflexion and Sensation. 
 
 IT will hereafter be my business to show what the 
 Ideas are, which thus enter into our knowledge; and 
 how each Idea has been, as a matter of historical fact, 
 introduced into the Science to which it especially be- 
 longs. But before I proceed to do this, I will notice 
 
28 OF IDEAS IN GENERAL. 
 
 some other terms, besides the phrases already noticed, 
 which have a reference, more or less direct, to the Funda- 
 mental Antithesis of Ideas and Sensations. I will mention 
 some of these, in order that if they should come under 
 the reader's notice, he may not be perplexed as to their 
 bearing upon the view here presented to him. 
 
 The celebrated doctrine of Locke, that all our 
 " Ideas," (that is, in his use of the word, all our objects 
 of thinking,) come from Sensation or Reflexion, will 
 naturally occur to the reader as connected with the 
 antithesis of which I have been speaking. But there is 
 a great difference between Locke's account of Sensation 
 and Reflexion, and our view of Sensation and Ideas. He 
 is speaking of the origin of our knowledge ; we, of its 
 nature and composition. He is content to say that all 
 the knowledge which we do not receive directly by 
 Sensation, we obtain by Reflex Acts of the mind, which 
 make up his Reflexion. But we hold that there is no 
 Sensation without an act of the mind, and that the 
 mind's activity is not only reflexly exerted upon itself, 
 but directly upon objects, so as to perceive in them con- 
 nexions and relations which are not Sensations. He is 
 content to put together, under the name of Reflexion, 
 everything in our knowledge which is not Sensation : we 
 are to attempt to analyze all that is not Sensation ; not 
 only to say it consists of Ideas, but to point out what 
 those Ideas are, and to show the mode in which each of 
 them enters into our knowledge. His purpose was, to 
 prove that there are no Ideas, except the reflex acts of 
 the mind : our endeavour will be to show that the acts of 
 the mind, both direct and reflex, are governed by certain 
 Laws, which may be conveniently termed Ideas. His 
 procedure was, to deny that any knowledge could be 
 derived from the mind alone : our course will be, to 
 show that in every part of our most certain and exact 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 29 
 
 knowledge, those who have added to our knowledge in 
 every age have referred to principles which the mind 
 itself supplies. I do not say that my view is contrary to 
 his : but it is altogether different from his. If I grant 
 that all our knowledge comes from Sensation and Re- 
 flexion, still my task then is only begun; for I want 
 further to determine, in each science, what portion 
 comes, not from mere Sensation, but from those Ideas 
 by the aid of which either Sensation or Reflexion can 
 lead to Science. 
 
 Locke's use of the word "idea" is, as the reader will 
 perceive, different from ours. He uses the word, as he 
 says, which " serves best to stand for whatsoever is the 
 object of the understanding when a man thinks." " I 
 have used it," he adds, " to express whatever is meant by 
 phantasm, notion, species, or whatever it is to which the 
 mind can be employed about in thinking." It might be 
 shown that this separation of the mind itself from the 
 ideal objects about which it is employed in thinking, may 
 lead to very erroneous results. But it may suffice to ob- 
 serve that we use the word Ideas, in the manner already 
 explained, to express that element, supplied by the mind 
 itself, which must be combined with Sensation in order 
 to produce knowledge. For us, Ideas are not Objects of 
 Thought, but rather Laws of Thought. Ideas are not 
 synonymous with Notions; they are Principles which 
 give to our Notions whatever they contain of truth. But 
 our use of the term Idea will be more fully explained 
 hereafter. 
 
 SECT. 7 Subjective and Objective. 
 
 THE Fundamental Antithesis of Philosophy of which I 
 have to speak has been brought into great prominence 
 in the writings of modern German philosophers, and has 
 conspicuously formed the basis of their systems. They 
 
30 OF IDEAS IN GENERAL. 
 
 have indicated this antithesis by the terms subjective and 
 objective. According to the technical language of old 
 writers, a thing and its qualities are described as subject 
 and attributes ; and thus a man's faculties and acts are 
 attributes of which he is the subject. The mind is the 
 subject in which ideas inhere. Moreover, the man's 
 faculties and acts are employed upon external objects; 
 and from objects all his sensations arise. Hence the 
 part of a man's knowledge which belongs to his own 
 mind, is subjective : that which flows in upon him from 
 the world external to him, is objective. And as in man's 
 contemplation of nature, there is always some act of 
 thought which depends upon himself, and some matter 
 of thought which is independent of him, there is, in every 
 part of his knowledge, a subjective and an objective 
 element. The combination of the two elements, the 
 subjective or ideal, and the objective or observed, is 
 necessary, in order to give us any insight into the laws of 
 nature. But different persons, according to their mental 
 habits and constitution, may be inclined to dwell by 
 preference upon the one or the other of these two 
 elements. It may perhaps interest the reader to see 
 this difference of intellectual character illustrated in two 
 eminent men of genius of modern times, Gothe and 
 Schiller. 
 
 Gothe himself gives us the account to which I refer, 
 in his history of the progress of his speculations con- 
 cerning the Metamorphosis of Plants; a mode of viewing 
 their structure by which he explained, in a very striking 
 and beautiful manner, the relations of the different parts 
 of a plant to each other ; as has been narrated in the 
 History of the Inductive Sciences. Gothe felt a delight 
 in the passive contemplation of nature, unmingled with 
 the desire of reasoning and theorizing ; a delight such as 
 naturally belongs to those poets who merely embody the 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 31 
 
 images which a fertile genius suggests, and do not mix 
 with these pictures, judgments and reflexions of their 
 own. Schiller, on the other hand, both by his own 
 strong feeling of the value of a moral purpose in poetry, 
 and by his adoption of a system of metaphysics in which 
 the subjective element was made very prominent, was 
 well disposed to recognize fully the authority of ideas 
 over external impressions. 
 
 Gothe for a time felt a degree of estrangement 
 towards Schiller, arising from this contrariety in their 
 views and characters. But on one occasion they fell 
 into discussion on the study of natural history; and 
 Gothe endeavoured to impress upon his companion his 
 persuasion that nature was to be considered, not as com- 
 posed of detached and incoherent parts, but as active 
 and alive, and unfolding herself in each portion, in 
 virtue of principles which pervade the whole. Schiller 
 objected that no such view of the objects of natural 
 history had been pointed out by observation, the only 
 guide which the natural historians recommended; and 
 was disposed on this account to think the whole of their 
 study narrow and shallow. "Upon this," says Gothe, 
 " I expounded to him, in as lively a way as I could, the 
 metamorphosis of plants, drawing on paper for him, as I 
 proceeded, a diagram to represent that general form of 
 a plant which shows itself in so many and so various 
 transformations. Schiller attended and understood; and, 
 accepting the explanation, he said, ' This is not observa- 
 tion, but an idea.' I replied," adds Gothe, "with some 
 degree of irritation ; for the point which separated us 
 was most luminously marked by this expression : but I 
 smothered my vexation, and merely said, ' I was happy 
 to find that I had got ideas without knowing it; nay, 
 that I saw them before my eyes.' " Gothe then goes on 
 to say, that he had been grieved to the very soul by 
 
32 OF IDEAS IN GENERAL. 
 
 maxims promulgated by Schiller, that no observed fact 
 ever could correspond with an idea. Since he himself 
 loved best to wander in the domain of external observa- 
 tion, he had been led to look with repugnance and 
 hostility upon anything which professed to depend upon 
 ideas. "Yet," he observes, "it occurred to me that if 
 my Observation was identical with his Idea, there must 
 be some common ground on which we might meet." 
 They went on with their mutual explanations, and be- 
 came intimate and lasting friends. "And thus," adds 
 the poet, "by means of that mighty and interminable 
 controversy between object and subject, we two concluded 
 an alliance which remained unbroken, and produced 
 much benefit to ourselves and others." 
 
 The general diagram of a plant, of which Gothe 
 here speaks, must have been a combination of lines and 
 marks expressing the relations of position and equiva- 
 lence among the elements of vegetable forms, by which 
 so many of their resemblances and differences may be 
 explained. Such a symbol is not an Idea in that general 
 sense in which we propose to use the term, but is a 
 particular modification of the general Ideas of symmetry, 
 developement, and the like ; and we shall hereafter see, 
 according to the phraseology which we shall explain in 
 the next chapter, how such a diagram might express 
 the ideal conception of a plant. 
 
 The antithesis of subjective and objective is very 
 familiar in the philosophical literature of Germany and 
 France; nor is it uncommon in any age of our own 
 literature. But though efforts have recently been made 
 to give currency among us to this phraseology, it has 
 not been cordially received, and has been much com- 
 plained of as not of obvious meaning. Nor is the com- 
 plaint without ground : for when we regard the mind as 
 the subject in which ideas inhere, it becomes for us an 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 33 
 
 object, and the antithesis vanishes. We are not so 
 much accustomed to use subject in this sense, as to 
 make it a proper contrast to object. The combination 
 "ideal and objective" would more readily convey to a 
 modern reader the opposition which is intended between 
 the ideas of the mind itself, and the objects which it 
 contemplates around it. 
 
 To the antitheses already noticed Thoughts and 
 Things ; Necessary and Experiential Truths ; Deduction 
 and Induction ; Theory and Fact ; Ideas and Sensations ; 
 Reflexion and Sensation ; Subjective and Objective ; we 
 may add others, by which distinctions depending more 
 or less upon the fundamental antithesis have been de- 
 noted. Thus we speak of the internal and external 
 sources of our knowledge ; of the world within and the 
 world without us ; of Man and Nature. Some of the 
 more recent metaphysical writers of Germany have 
 divided the universe into the Me and the Not-me (Ich 
 and Nicht-ich). Upon such phraseology we may observe, 
 that to have the fundamental antithesis of which we 
 speak really understood, is of the highest consequence 
 to philosophy, but that little appears to be gained by 
 expressing it in any novel manner. The most weighty 
 part of the philosopher's task is to analyze the operations 
 of the mind ; and in this task, it can aid us but little to 
 call it, instead of the mind, the subject, or the me. 
 
 SECT. 8. Matter and Form. 
 
 THERE are some other ways of expressing, or rather 
 of illustrating, the fundamental antithesis, which I may 
 briefly notice. The antithesis has been at different times 
 presented by means of various images. One of the most 
 ancient of these, and one which is still very instructive, 
 is that which speaks of Sensations as the Matter, and 
 Ideas as the Form, of our knowledge ; just as ivory is 
 VOL. i. w. P. D 
 
34 OF IDEAS IN GENERAL. 
 
 the matter, and a cube the form, of a die. This com- 
 parison has the advantage of showing that two elements 
 of an antithesis which cannot be separated in fact, may 
 yet be advantageously separated in our reasonings. For 
 Matter and Form cannot by any means be detached 
 from each other. All matter must have some form ; all 
 form must be the form of some material thing. If the 
 ivory be not a cube, it must have a spherical or some 
 other form. And the cube, in order to be a cube, must 
 be of some material ; if not of ivory, of wood, or stone, 
 for instance. A figure without matter is merely a geo- 
 metrical conception ; a modification of the idea of 
 space. Matter without figure is a mere abstract term ; 
 a supposed union of certain sensible qualities which, 
 so insulated from others, cannot exist. Yet the distinc- 
 tion of Matter and Form is real; and, as a subject of 
 contemplation, clear and plain. Nor is the distinction by 
 any means useless. The speculations which treat of the 
 two subjects, Matter and Figure, are very different. 
 Matter is the subject of the sciences of Mechanics and 
 Chemistry ; Figure, of Geometry. These two classes of 
 Sciences have quite different sets of principles. If we 
 refuse to consider the Matter and the Form of bodies 
 separately, because we cannot exhibit Matter and Form 
 separately, we shut the door to all philosophy on such 
 subjects. In like manner, though Sensations and Ideas 
 are necessarily united in all our knowledge, they can be 
 considered as distinct; and this distinction is the basis of 
 all philosophy concerning knowledge. 
 
 This illustration of the relation of Ideas and Sensa- 
 tions may enable us to estimate a doctrine which has been 
 put forwards at various times. In a certain school of spe- 
 culators there has existed a disposition to derive all our 
 Ideas from our Sensations, the term Idea being, in this 
 school, used in its wider sense, so as to include all modifi- 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 35 
 
 cations and limitations of our Fundamental Ideas. The 
 doctrines of this school have been summarily expressed 
 by saying that " Every Idea is a transformed Sensation." 
 Now, even supposing this assertion to be exactly true, 
 we easily see, from what has been said, how little we 
 are likely to answer the ends of philosophy by putting 
 forward such a maxim as one of primary importance. 
 For we might say, in like manner, that every statue is 
 but a transformed block of marble, or every edifice but 
 a collection of transformed stones. But what would 
 these assertions avail us, if our object were to trace the 
 rules of art by which beautiful statues were formed, or 
 great works of architecture erected ? The question 
 naturally occurs, What is the nature, the principle, the 
 law of this Transformation ? In what faculty resides the 
 transforming power? What train of ideas of beauty, 
 and symmetry, and stability, in the mind of the statuary 
 or the architect, has produced those great works which 
 mankind look upon as among their most valuable pos- 
 sessions ; the Apollo of the Belvidere, the Parthenon, 
 the Cathedral of Cologne ? When this is what we want 
 to know, how are we helped by learning that the Apollo 
 is of Parian marble, or the Cathedral of basaltic stone ? 
 We must know much more than this, in order to acquire 
 any insight into the principles of statuary or of archi- 
 tecture. In like manner, in order that we may make 
 any progress in the philosophy of knowledge, which is 
 our purpose, we must endeavour to learn something 
 further respecting ideas than that they are transformed 
 sensations, even if they were this. 
 
 But, in reality, the assertion that our ideas are trans- 
 formed sensations, is erroneous as well as frivolous. For 
 it conveys, and is intended to convey, the opinion that 
 our sensations have one form which properly belongs to 
 them ; and that, in order to become ideas, they are con- 
 
 D 2 
 
36 OF IDEAS IN GENERAL. 
 
 verted into some other form. But the truth is, that our 
 sensations, of themselves, without some act of the mind, 
 such as involves what we have termed an Idea, have no 
 form. We cannot see one object without the idea of 
 space ; we cannot see two without the idea of resem- 
 blance or difference; and space and difference are not 
 sensations. Thus, if we are to employ the metaphor of 
 Matter and Form, which is implied in the expression to 
 which I have referred, our sensations, from their first 
 reception, have their Form not changed, but given by 
 our Ideas. Without the relations of thought which we 
 here term Ideas, the sensations are matter without form. 
 Matter without form cannot exist : and in like manner 
 sensations cannot become perceptions of objects, without 
 some formative power of the mind. By the very act of 
 being received as perceptions, they have a formative 
 power exercised upon them, the operation of which 
 might be expressed, by speaking of them, not as trans- 
 formed, but simply as formed ; as invested with form, 
 instead of being the mere formless material of percep- 
 tion. The word inform, according to its Latin etymo- 
 logy, at first implied this process by which matter is 
 invested with form. Thus Virgil 4 " speaks of the thunder- 
 bolt as informed by the hands of Brontes, and Steropes, 
 and Pyracmon. And Dryden introduces the word in 
 another place : 
 
 Let others better mould the running mass 
 Of metals, or inform the breathing brass. 
 
 Even in this use of the word, the form is something 
 superior to the brute manner, and gives it a new signi- 
 ficance and purpose. And hence the term is again used 
 
 * Ferrum exercebant vasto Cyclopes in Antro 
 
 Brontesque Steropesque et nudus membra Pyracmon ; 
 His informatum manibus, jam parte polita 
 Fulmen erat. JEn. viii. 424. 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 37 
 
 to denote the effect produced by an intelligent principle 
 of a still higher kind : 
 
 He informed 
 
 This ill-shaped body with a daring soul. 
 
 And finally even the soul itself, in its original condition, 
 is looked upon as matter, when viewed with reference 
 to education and knowledge, by which it is afterwards 
 moulded ; and hence these are, in our language, termed 
 information. If we confine ourselves to the first of 
 these three uses of the term, we may correct the erro- 
 neous opinion of which we have just been speaking, 
 and retain the metaphor by which it is expressed, by 
 saying, that ideas are not transformed, but informed 
 sensations. 
 
 SECT. 9. Man the Interpreter of Nature. 
 
 THERE is another image by which writers have repre- 
 sented the acts of thought through which knowledge is 
 obtained from the observation of the external world. 
 Nature is the Book, and Man is the Interpreter. The 
 facts of the external world are marks, in which man 
 discovers a meaning, and so reads them. Man is the 
 Interpreter of Nature, and Science is the right Interpre- 
 tation. And this image also is, in many respects, instruc- 
 tive. It exhibits to us the necessity of both elements ; 
 the marks which man has to look at, and the knowledge 
 of the alphabet and language which he must possess and 
 apply before he can find any meaning in what he sees. 
 Moreover this image presents to us, as the ideal element, 
 an activity of the mind of that very kind which we wish 
 to point out. Indeed the illustration is rather an 
 example than a comparison of the composition of our 
 knowledge. The letters and symbols which are pre- 
 sented to the Interpreter are really objects of sensation : 
 the notion of letters as signs of words, the notion of 
 
38 OF IDEAS IN GENERAL. 
 
 connexions among words by which they have meaning, 
 really are among our Ideas ; Signs and Meaning are 
 Ideas, supplied by the mind, and added to all that sensa- 
 tion can disclose in any collection of visible marks. The 
 Sciences are not figuratively, but really, Interpretations 
 of Nature. But this image, whether taken as example or 
 comparison, may serve to show both the opposite charac- 
 ter of the two elements of knowledge, and their neces- 
 sary combination, in order that there may be knowledge. 
 This illustration may also serve to explain another 
 point in the conditions of human knowledge which we 
 shall have to notice : namely, the very different degrees 
 in which, in different cases, we are conscious of the 
 mental act by which our sensations are converted into 
 knowledge. For the same difference occurs in reading 
 an inscription. If the inscription were entire and plain, 
 in a language with which we were familiar, we should 
 be unconscious of any mental act in reading it. We 
 should seem to collect its meaning by the sight alone. 
 But if we had to decipher an ancient inscription, of 
 which only imperfect marks remained, with a few entire 
 letters among them, we should probably make several 
 suppositions as to the mode of reading it, before we 
 found any mode which was quite successful ; and thus, 
 our guesses, being separate from the observed facts, and 
 at first not fully in agreement with them, we should be 
 clearly aware that the conjectured meaning, on the one 
 hand, and the observed marks on the other, were dis- 
 tinct things, though these two things would become 
 united as elements of one act of knowledge when we 
 had hit upon the right conjecture. 
 
 SECT. 10. The Fundamental Antithesis inseparable. 
 
 THE illustration just referred to, as well as other 
 ways of considering the subject, may help us to get over 
 
FUNDAMENTAL ANTJTHKSLS OF PHILOSOPHY. 39 
 
 a difficulty which at first sight appears perplexing. We 
 have spoken of the common opposition of Theory and 
 Fact as important, and as involving what we have called 
 the Fundamental Antithesis of Philosophy. But after 
 all, it may be asked, Is this distinction of Theory and 
 Fact really tenable? Is it not often difficult to say 
 whether a special part of our knowledge is a Fact or 
 a Theory? Is it a Fact or a Theory that the stars 
 revolve round the pole? Is it a Fact or a Theory that 
 the earth is a globe revolving on its axis? Is it a Fact 
 or a Theory that the earth travels in an ellipse round 
 the sun? Is it a Fact or a Theory that the sun attracts 
 the earth? Is it a Fact or a Theory that the loadstone 
 attracts the needle? In all these cases, probably some 
 persons would answer one way, and some persons the 
 other. There are many persons by whom the doctrine 
 of the globular form of the earth, the doctrine of the 
 earth's elliptical orbit, the doctrine of the sun's attrac- 
 tion on the earth, would be called theories, even if they 
 allowed them to be true theories. But yet if each of 
 these propositions be true, is it not &fact? And even 
 with regard to the simpler facts, as the motion of the 
 stars round the pole, although this may be a Fact to one 
 who has watched and measured the motions of the stars, 
 one who has not done this, and who has only carelessly 
 looked at these stars from time to time, may naturally 
 speak of the circles which the astronomer makes them 
 describe as Theories. It would seem, then, that we 
 cannot in such cases expect general assent, if we say, 
 This is a Fact and not a Theory, or, This is a Theory 
 and not a Fact. And the same is true in a vast range 
 of cases. It would seem, therefore, that we cannot rest 
 any reasoning upon this distinction of Theory and Fact; 
 and we cannot avoid asking whether there is any real 
 distinction in this antithesis, and if so, what it is. 
 
40 OF IDEAS IN GENERAL. 
 
 To this I reply : the distinction between Theory 
 (that is, true Theory) and Fact, is this: that in Theory 
 the Ideas are considered as distinct from the Facts: in 
 Facts, though Ideas may be involved, they are not, in 
 our apprehension, separated from the sensations. In a 
 Fact, the Ideas are applied so readily and familiarly, and 
 incorporated with the sensations so entirely, that we 
 do not see them, we see through them. A person who 
 carefully notes the motion of a star all night, sees the 
 circle which it describes, as he sees the star, though 
 the circle is, in fact, a result of his own Ideas. A 
 person who has in his mind the measures of different 
 lines and countries on the earth's surface, and who can 
 put them together into one conception, finds that they 
 can make no figure but a globular one: to him, the 
 earth's globular form is a Fact, as much as the square 
 form of his chamber. A person to whom the grounds 
 of believing the earth to travel round the sun are as 
 familiar as the grounds for believing the movements 
 of the mail-coaches in this country, looks upon the 
 former event as a Fact, just as he looks upon the latter 
 events as Facts. And a person who, knowing the Fact 
 of the earth's annual motion, refers it distinctly to its 
 mechanical cause, conceives the sun's attraction as a 
 Fact, just as he conceives as a Fact, the action of the 
 wind which turns the sails of a mill. He cannot see 
 the force in either case ; he supplies it out of his own 
 Ideas. And thus, a true Theory is a Fact ; a Fact is 
 a familiar Theory. That which is a Fact under one 
 aspect, is a Theory under another. The most recondite 
 Theories when firmly established are Facts: the sim- 
 plest Facts involve something of the nature of Theory. 
 Theory and Fact correspond, in a certain degree, with 
 Ideas and Sensations, as to the nature of their opposi- 
 tion. But the Facts are Facts, so far as the Ideas have 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 41 
 
 been combined with the Sensations and absorbed in 
 them: the Theories are Theories, so far as the Ideas 
 are kept distinct from the Sensations, and so far as it is 
 considered still a question whether those can be made 
 to agree with these. 
 
 We may, as I have said, illustrate this matter by 
 considering man as interpreting the phenomena which 
 he sees. He often interprets without being aware that 
 he does so. Thus when we see the needle move towards 
 the magnet, we assert that the magnet exercises an 
 attractive force on the needle. But it is only by an 
 interpretative act of our own minds that we ascribe 
 this motion to attraction. That, in this case, a force is 
 exerted something of the nature of the pull which we 
 could apply by our own volition is our interpretation 
 of the phenomena; although we may be conscious of the 
 act of interpretation, and may then regard the attrac- 
 tion as a Fact. 
 
 Nor is it in such cases only that we interpret phe- 
 nomena in our own way, without being conscious of 
 what we do. We see a tree at a distance, and judge it 
 to be a chestnut or a lime ; yet this is only an inference 
 from the colour or form of the mass according to pre- 
 conceived classifications of our own. Our lives are full 
 of such unconscious interpretations. The farmer recog- 
 nizes a good or a bad soil ; the artist a picture of a 
 favourite master ; the geologist a rock of a known local- 
 ity, as we recognize the faces and voices of our friends ; 
 that is, by judgments formed on what we see and hear ; 
 but judgments in which we do not analyze the steps, or 
 distinguish the inference from the appearance. And in 
 these mixtures of observation and inference, we speak of 
 the judgment thus formed, as a Fact directly observed. 
 
 Even in the case in which our perceptions appear to 
 be most direct, and least to involve any interpretations 
 
42 OF IDEAS IN GENERAL. 
 
 of our own, in the simple process of seeing, who does 
 not know how much we, by an act of the mind, add to 
 that which our senses receive ? Does any one fancy that 
 he sees a solid cube? It is easy to show that the solid- 
 ity of the figure, the relative position of its faces and 
 edges to each other, are inferences of the spectator ; no 
 more conveyed to his conviction by the eye alone, than 
 they would be if he were looking at a painted represen- 
 tation of a cube. The scene of nature is a picture with- 
 out depth of substance, no less than the scene of art ; 
 and in the one case as in the other, it is the mind which, 
 by an act of its own, discovers that colour and shape 
 denote distance and solidity. Most men are unconscious 
 of this perpetual habit of reading the language of the 
 external world, and translating as they read. The 
 draughtsman, indeed, is compelled, for his purposes, to 
 return back in thought from the solid bodies which he 
 has inferred, to the shapes of surface which he really 
 sees. He knows that there is a mask of theory over the 
 whole face of nature, if it be theory to infer more than 
 we see. But other men, unaware of this masquerade, 
 hold it to be a fact that they see cubes and spheres, spa- 
 cious apartments and winding avenues. And these things 
 are facts to them, because they are unconscious of the 
 mental operation by which they have penetrated nature's 
 disguise. 
 
 And thus, we still have an intelligible distinction of 
 Fact and Theory, if we consider Theory as a conscious, and 
 Fact as an unconscious inference, from the phenomena 
 which are presented to our senses. 
 
 But still, Theory and Fact, Inference and Perception, 
 Reasoning and Observation, are antitheses in none of 
 which can we separate the two members by any fixed 
 and definite line. 
 
 Even the simplest terms by which the antithesis is 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 43 
 
 expressed cannot be separated. Ideas and Sensations, 
 Thoughts and Things, Subject arid Object, cannot in any 
 case be applied absolutely and exclusively. Our Sen- 
 sations require Ideas to bind them together, namely, 
 Ideas of space, time, number, and the like. If not so 
 bound together, Sensations do not give us any appre- 
 hension of Things or Objects. All Things, all Objects, 
 must exist in space and in time must be one or many. 
 Now space, time, number, are not Sensations or Things. 
 They are something different from, and opposed to Sen- 
 sations and Things. We have termed them Ideas. It 
 may be said they are Relations of Things, or of Sensa- 
 tions. But granting this form of expression, still a 
 Relation is not a Thing or a Sensation ; and therefore 
 we must still have another and opposite element, along 
 with our Sensations. And yet, though we have thus 
 these two elements in every act of perception, we cannot 
 designate any portion of the act as absolutely and exclu- 
 sively belonging to one of the elements. Perception 
 involves Sensation, along with Ideas of time, space, and 
 the like ; or, if any one prefers the expression, we may 
 say, Perception involves Sensations along with the ap- 
 prehension of Relations. Perception is Sensation, along 
 with such Ideas as make Sensation into an apprehension 
 of Things or Objects. 
 
 And as Perception of Objects implies Ideas, as Ob- 
 servation implies Reasoning; so, on the other hand, 
 Ideas cannot exist where Sensation has not been ; Rea- 
 soning cannot go on when there has not been previous 
 Observation. This is evident from the necessary order 
 of developement of the human faculties. Sensation 
 necessarily exists from the first moments of our exist- 
 ence, and is constantly at work. Observation begins 
 before we can suppose the existence of any Reasoning 
 which is not involved in Observation. Hence, at what- 
 
44 OF IDEAS IN GENERAL. 
 
 ever period we consider our Ideas, we must consider 
 them as having been already engaged in connecting our 
 Sensations, and as having been modified by this employ- 
 ment. By being so employed, our Ideas are unfolded 
 and defined ; and such developement and definition can- 
 not be separated from the Ideas themselves. We cannot 
 conceive space, without boundaries or forms ; now Forms 
 involve Sensations. We cannot conceive time, without 
 events which mark the course of time ; but events involve 
 Sensations. We cannot conceive number, without con- 
 ceiving things which are numbered ; and Things imply 
 sensations. And the forms, things, events, which are 
 thus implied in our Ideas, having been the objects of 
 Sensation constantly in every part of our life, have 
 modified, unfolded, and fixed our Ideas, to an extent 
 which we cannot estimate, but which we must suppose 
 to be essential to the processes which at present go on 
 in our minds. We cannot say that Objects create Ideas ; 
 for to perceive Objects we must already have Ideas. 
 But we may say, that Objects and the constant Perception 
 of Objects have so far modified our Ideas, that we cannot, 
 even in thought, separate our Ideas from the perception 
 of Objects. 
 
 We cannot say of any Ideas, as of the Idea of space, 
 or time, or number, that they are absolutely and exclu- 
 sively Ideas. We cannot conceive what space, or time, 
 or number, would be in our minds, if we had never per- 
 ceived any Thing or Things in space or time. We can- 
 not conceive ourselves in such a condition as never to have 
 perceived any Thing or Things in space or time. But, on 
 the other hand, just as little can we conceive ourselves 
 becoming acquainted with space and time or numbers 
 as objects of Sensation. We cannot reason without 
 having the operations of our minds affected by previous 
 Sensations ; but we cannot conceive Reasoning to be 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 45 
 
 merely a series of Sensations. In order to be used in 
 Reasoning, Sensation must become Observation ; and, as 
 we have seen, Observation already involves Reasoning. 
 In order to be connected by our Ideas, Sensations must 
 be Things or Objects, and Things or Objects already in- 
 clude Ideas. And thus, none of the terms by which the 
 fundamental antithesis is expressed can be absolutely 
 and exclusively applied. 
 
 I will make a remark suggested by the views which 
 have thus been presented. Since, as we have just seen, 
 none of the terms which express the fundamental anti- 
 thesis can be applied absolutely and exclusively, the 
 absolute application of the antithesis in any particular 
 case can never be a conclusive or immoveable principle. 
 This remark is the more necessary to be borne in mind, as 
 the terms of this antithesis are often used in a vehement 
 and peremptory manner. Thus we are often told that 
 such a thing is a Fact; A FACT and not a Theory, with all 
 the emphasis which, in speaking or writing, tone or italics 
 or capitals can give. We see from what has been said, 
 that when this is urged, before we can estimate the 
 truth, or the value of the assertion, we must ask to 
 whom is it a Fact? what habits of thought, what pre- 
 vious information, what Ideas does it imply, to conceive 
 the Fact as a Fact ? Does not the apprehension of the 
 Fact imply assumptions which may with equal justice 
 be called Theory, and which are perhaps false Theory ? 
 in which case, the Fact is no Fact. Did not the an- 
 cients assert it as a Fact, that the earth stood still, 
 and the stars moved ? and can any Fact have stronger 
 apparent evidence to justify persons in asserting it em- 
 phatically than this had ? 
 
 These remarks are by no means urged in order to 
 shew that no Fact can be certainly known to be true ; 
 but only, to shew that no Fact can be certainly shown 
 
46 OF IDEAS IN GENERAL. 
 
 to be a Fact, merely by calling it a Fact, however 
 emphatically. There is by no means any ground of 
 general skepticism with regard to truth, involved in 
 the doctrine of the necessary combination of two ele- 
 ments in all our knowledge. On the contrary, Ideas 
 are requisite to the essence, and Things to the reality 
 of our knowledge in every case. The proportions of 
 Geometry and Arithmetic are examples of knowledge 
 respecting our Ideas of space and number, with regard 
 to which there is no room for doubt. The doctrines of 
 Astronomy are examples of truths not less certain 
 respecting the Facts of the external world. 
 
 SECT. 11. Successive Generalization. 
 
 IN the preceding pages we have been led to the doctrine, 
 that though, in the Antithesis of Theory and Fact, there 
 is involved an essential opposition ; namely the opposition 
 of the thoughts within us and the phenomena without 
 us ; yet that we cannot distinguish and define the mem- 
 bers of this antithesis separately. Theories become 
 Facts, by becoming certain and familiar : and thus, as 
 our knowledge becomes more sure and more extensive, 
 we are constantly transferring to the class of facts, 
 opinions which were at first regarded as theories. 
 
 Now we have further to remark, that in the progress 
 of human knowledge respecting any branch of specula- 
 tion, there may be several such steps in succession, each 
 depending upon and including the preceding. The 
 theoretical views which one generation of discoverers 
 establishes, become the facts from which the next gene- 
 ration advances to new theories. As men rise from the 
 particular to the general, so, in the same manner, they 
 rise from what is general to what is more general. Each 
 induction supplies the materials of fresh inductions ; 
 each generalization, with all that it embraces in its circle, 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 47 
 
 may be found to be but one of many circles, compre- 
 hended within the circuit of some wider generalization. 
 
 This remark has already been made, and illustrated, 
 in the History of tlie Inductive Sciences* ; and, in truth, 
 the whole of the history of science is full of suggestions 
 and exemplifications of this course of things. It may be 
 convenient, however, to select a few instances which may 
 further explain and confirm this view of the progress of 
 scientific knowledge. 
 
 The most conspicuous instance of this succession is 
 to be found in that science which has been progressive 
 from the beginning of the world to our own times, and 
 which exhibits by far the richest collection of successive 
 discoveries : I mean Astronomy. It is easy to see that 
 each of these successive discoveries depended on those 
 antecedently made, and that in each, the truths which 
 were the highest point of the knowledge of one age 
 were the fundamental basis of the efforts of the age 
 which came next. Thus we find, in the days of Greek 
 discovery, Hipparchus and Ptolemy combining and ex- 
 plaining the particular facts of the motion of the sun, 
 moon, and planets, by means of the theory of epicycles 
 and eccentrics ; a highly important step, which gave 
 an intelligible connexion and rule to the motions of each 
 of these luminaries. When these cycles and epicycles, 
 thus truly representing the apparent motions of the 
 heavenly bodies, had accumulated to an inconvenient 
 amount, by the discovery of many inequalities in the 
 observed motions, Copernicus showed that their effects 
 might all be more simply included, by making the sun 
 the center of motion of the planets, instead of the earth. 
 But in this new view, he still retained the epicycles and 
 eccentrics which governed the motion of each body. 
 Tycho Brahe's observations, and Kepler's calculations, 
 
 * Hist. Inductive Sciences, B. vn c. ii. Sect. 5. 
 
48 OF IDEAS IN GENERAL. 
 
 showed that, besides the vast number of facts which the 
 epicyclical theory could account for, there were some 
 which it would not exactly include, and Kepler was led 
 to the persuasion that the planets move in ellipses. 
 But this view of motion was at first conceived by Kepler 
 as a modification of the conception of epicycles. On one 
 occasion he blames himself for not sooner seeing that 
 such a modification was possible. " What an absurdity 
 on my part !" he cries* ; " as if libration in the diameter 
 of the epicycle might not come to the same thing as 
 motion in the ellipse." But again ; Kepler's laws of the 
 elliptical motion of the planets were established; and 
 these laws immediately became the facts on which the 
 mathematicians had to found their mechanical theories. 
 From these facts, Newton, as we have related, proved 
 that the central force of the sun retains the planets in 
 their orbits, according to the law of the inverse square 
 of the distance. The same law was shown to prevail in 
 the gravitation of the earth. It was shown, too, by in- 
 duction from the motions of Jupiter and Saturn, that 
 the planets attract each other ; by calculations from the 
 figure of the earth, that the parts of the earth attract 
 each other ; and, by considering the course of the tides, 
 that the sun and moon attract the waters of the ocean. 
 And all these curious discoveries being established as 
 facts, the subject was ready for another step of gene- 
 ralization. By an unparalleled rapidity in the progress 
 of discovery in this case, not only were all the inductions 
 which we have first mentioned made by one individual, 
 but the new advance, the higher flight, the closing vic- 
 tory, fell to the lot of the same extraordinary person. 
 
 The attraction of the sun upon the planets, of the 
 moon upon the earth, of the planets on each other, of the 
 parts of the earth on themselves, of the sun and moon 
 
 * Hut. Inductive Sciences, B. v. c. iv. Sect. 3. 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 49 
 
 upon the ocean ; all these truths, each of itself a great 
 discovery, were included by Newton in the higher gene- 
 ralization, of the universal gravitation of matter, by 
 which each particle is drawn to each other according to 
 the law of the inverse square : and thus this long ad- 
 vance from discovery to discovery, from truths to truths, 
 each justly admired when new, and then rightly used as 
 old, was closed in a worthy and consistent manner, by 
 a truth which is the most worthy admiration, because it 
 includes all the researches of preceding ages of Astro- 
 nomy. 
 
 We may take another example of a succession of this 
 kind from the history of a science, which, though it has 
 made wonderful advances, has not yet reached its goal, 
 as physical astronomy appears to have done, but seems to 
 have before it a long prospect of future progress. I now 
 refer to Chemistry, in which I shall try to point out how 
 the preceding discoveries afforded the materials of the 
 succeeding; although this subordination and connexion 
 is, in this case, less familiar to men's minds than in Astro- 
 nomy, and is, perhaps, more difficult to present in a clear 
 and definite shape. Sylvius saw, in the facts which 
 occur, when an acid and an alkali are brought together, 
 the evidence that they neutralize each other. But cases 
 of neutralization, and acidification, and many other ef- 
 fects of mixture of the ingredients of bodies, being thus 
 viewed as facts> had an aspect of unity and law given 
 them by Geoffroy and Bergman"-, who introduced the con- 
 ception of the Chemical Affinity or Elective Attraction, 
 by which certain elements select other elements, as if by 
 preference. That combustion, whether a chemical union 
 or a chemical separation of ingredients, is of the same 
 nature with acidification, was the doctrine of Beccher 
 
 * Hixf. Inductive Sciences, B. xiv. c. iii. 
 VOL. I. W. P. E 
 
50 OF IDEAS IN GENERAL. 
 
 and Stahl, and was soon established as a truth which 
 must form a part of every succeeding physical theory. 
 That the rules of affinity and chemical composition may 
 include gaseous elements, was established by Black and 
 Cavendish. And all these truths, thus brought to light 
 by chemical discoverers, affinity, the identity of acidifi- 
 cation and combustion, the importance of gaseous ele- 
 ments, along with all the facts respecting the weight 
 of ingredients and compounds which the balance dis- 
 closed, were taken up, connected, and included as 
 particulars in the oxygen theory of Lavoisier. Again, 
 the results of this theory, and the quantity of the several 
 ingredients which entered into each compound (such 
 results, for the most part, being now no longer mere 
 theoretical speculations, but recognized facts) were the 
 particulars from which Dalton derived that wide law of 
 chemical combination which we term the Atomic Theory. 
 And this law, soon generally accepted among chemists, 
 is already in its turn become one of the facts included 
 in Faraday's Theory of the identity of Chemical Affinity 
 and Electric Attraction. 
 
 It is unnecessary to give further exemplifications of 
 this constant ascent from one step to a higher; this 
 perpetual conversion of true theories into the materials 
 of other and wider theories. It will hereafter be our 
 business to exhibit, in a more full and formal manner, 
 the mode in which this principle determines the whole 
 scheme and structure of all the most exact sciences. 
 And thus, beginning with the facts of sense, we gradually 
 climb to the highest forms of human knowledge, and 
 obtain from experience and observation a vast collection 
 of the most wide and elevated truths. 
 
 There are, however, truths of a very different kind, to 
 which we must turn our attention, in order to pursue our 
 
FUNDAMENTAL ANTITHESIS OF PHILOSOPHY. 51 
 
 researches respecting the nature and grounds of our 
 knowledge. But before we do this, we must notice one 
 more feature in that progress of science which we have 
 already in part described. 
 
 CHAPTER III. 
 OF TECHNICAL TERMS. 
 
 1 . IT has already been stated that we gather knowledge 
 from the external world, when we are able to apply, to 
 the facts which we observe, some ideal conception, which 
 gives unity and connexion to multiplied and separate 
 perceptions. We have also shown that our conceptions, 
 thus verified by facts, may themselves be united and con- 
 nected by a new bond of the same nature ; and that man 
 may thus have to pursue his way from truth to truth 
 through a long progression of discoveries, each resting 
 on the preceding, and rising above it. 
 
 Each of these steps, in succession, is recorded, fixed, 
 and made available, by some peculiar form of words ; 
 and such words, thus rendered precise in their meaning, 
 and appropriated to the service of science, we may call 
 Technical Terms. It is in a great measure by inventing 
 such Terms that men not only best express the discoveries 
 they have made, but also enable their followers to become 
 so familiar with these discoveries, and to possess them 
 so thoroughly, that they can readily use them in ad- 
 vancing to ulterior generalizations. 
 
 Most of our ideal conceptions are described by exact 
 and constant words or phrases, such as those of which we 
 here speak. We have already had occasion to employ 
 many of these. Thus we have had instances of technical 
 Terms expressing geometrical conceptions, as Ellipsis, 
 
 E2 
 
52 OF IDEAS IN GENERAL. 
 
 Radius Vector, Axis, Plane, the Proportion of the In- 
 verse Square, and the like. Other Terms have described 
 mechanical conceptions, as Accelerating Force and 
 Attraction. Again, chemistry exhibits (as do all sciences) 
 a series of Terms which mark the steps of our progress. 
 The views of the first real founders of the science are 
 recorded by the Terms which are still in use, Neutral 
 Salts, Affinity, and the like. The establishment of Dai- 
 ton's theory has produced the use of the word Atom in 
 a peculiar sense, or of some other word, as Proportion, 
 in a sense equally technical. And Mr. Faraday has 
 found it necessary, in order to expound his electro-chemi- 
 cal theory, to introduce such terms as Anode and Cathode, 
 Amon and Cathwn. 
 
 2. I need not adduce any further examples, for my 
 object at present is only to point out the use and influence 
 of such language : its rules and principles I shall here- 
 after try, in some measure, to fix. But what we have 
 here to remark is, the extraordinary degree in which the 
 progress of science is facilitated, by thus investing each 
 new discovery with a compendious and steady form of 
 expression. These terms soon become part of the cur- 
 rent language of all who take an interest in speculation. 
 However strange they may sound at first, they soon grow 
 familiar in our ears, arid are used without any effort, or 
 any recollection of the difficulty they once involved. They 
 become as common as the phrases which express our 
 most frequent feelings and interests, while yet they have 
 incomparably more precision than belongs to any terms 
 which express feelings; and they carry with them, in 
 their import, the results of deep and laborious trains of 
 research. They convey the mental treasures of one 
 period to the generations that follow; and laden with 
 this, their precious freight, they sail safely across gulfs 
 of time in which empires have suffered shipwreck, and 
 
OF TECHNICAL TERMS. 53 
 
 the languages of common life have sunk into oblivion. 
 We have still in constant circulation among us the Terms 
 which belong to the geometry, the astronomy, the 
 zoology, the medicine of the Greeks, and the algebra 
 and chemistry of the Arabians. And we can in an in- 
 stant, by means of a few words, call to our own recollec- 
 tion, or convey to the apprehension of another person* 
 phenomena and relations of phenomena in optics, mine- 
 ralogy, chemistry, which are so complex and abstruse, 
 that it might seem to require the utmost subtlety of the 
 human mind to grasp them, even if that were made the 
 sole object of its efforts. By this remarkable effect of 
 Technical Language, we have the results of all the 
 labours of past times not only always accessible, but so 
 prepared that we may (provided we are careful in the 
 use of our instrument) employ what is really useful and 
 efficacious for the purpose of further success, without 
 being in any way impeded or perplexed by the length 
 and weight of the chain of past connexions which we 
 drag along with us. 
 
 By such means, by the use of the Inductive Process, 
 and by the aid of Technical Terms, man has been con- 
 stantly advancing in the path of scientific truth. In a 
 succeeding part of this work we shall endeavour to trace 
 the general rules of this advance, and to lay down the 
 maxims by which it may be most successfully guided 
 and forwarded. But in order that we may do this to 
 the best advantage, we must pursue still further the 
 analysis of knowledge into its elements ; and this will be 
 our employment in the first part of the work. 
 
54 
 
 CHAPTER IV. 
 OF NECESSARY TRUTHS. 
 
 1. EVERY advance in human knowledge consists, as 
 we have seen, in adapting new ideal conceptions to ascer- 
 tained facts, and thus in superinducing the Form upon 
 the Matter, the active upon the passive processes of our 
 minds. Every such step introduces into our knowledge 
 an additional portion of the ideal element, and of those 
 relations which flow from the nature of Ideas. It is, 
 therefore, important for our purpose to examine more 
 closely this element, and to learn what the relations are 
 which may thus come to form part of our knowledge. 
 An inquiry into those Ideas which form the foundations 
 of our sciences ; into the reality, independence, extent, 
 and principal heads of the knowledge which we thus ac- 
 quire ; is a task on which we must now enter, and 
 which will employ us for several of the succeeding Books. 
 
 In this inquiry our object will be to pass in review all 
 the most important Fundamental Ideas which our 
 sciences involve ; and to prove more distinctly in refer- 
 ence to each, what we have already asserted with regard 
 to all, that there are everywhere involved in our know- 
 ledge acts of the mind as well as impressions of sense ; 
 and that our knowledge derives, from these acts, a gene- 
 rality, certainty, and evidence which the senses could in 
 no degree have supplied. But before I proceed to do 
 this in particular cases, I will give some account of the 
 argument in its general form. 
 
 We have already considered the separation of our 
 knowledge into its two elements, Impressions of Sense 
 and Ideas, as evidently indicated by this ; that all know- 
 ledge possesses characters which neither of these ele- 
 ments alone could bestow. Without our ideas, our sen- 
 sations could have no connexion ; without external 
 
OF NECESSARY TRUTHS. 55 
 
 impressions, our ideas would have no reality ; and thus 
 both ingredients of our knowledge must exist. 
 
 2. There is another mode in which the distinction of 
 the two elements of knowledge appears, as I have already 
 said : (C. i. Sect. 2.) namely in the distinction of neces- 
 sary and contingent or experiential truths. For of these 
 two classes of truths, the difference arises from this ; 
 that the one class derives its nature from the one, and 
 the other from the other, of the two elements of know- 
 ledge. I have already stated briefly the difference of 
 these two kinds of truths : namely, that the former are 
 truths which, we see, must be true : the latter are true, 
 but so far as we can see, might be otherwise. The former 
 are true necessarily and universally : the latter are learnt 
 from experience and limited by experience. Now with 
 regard to the former kind of truths, I wish to show that 
 the universality and necessity which distinguish them 
 can by no means be derived from experience ; that these 
 characters do in reality flow from the ideas which these 
 truths involve ; and that when the necessity of the truth 
 is exhibited in the way of logical demonstration, it is 
 found to depend upon certain fundamental principles, 
 (Definitions and Axioms,) which may thus be considered 
 as expressing, in some measure, the essential characters 
 of our ideas. These fundamental principles I shall after- 
 wards proceed to discuss and to exhibit in each of the 
 principal departments of science. 
 
 I shall begin by considering Necessary Truths more 
 fully than I have yet done. As I have already said, 
 necessary truths are those in which we not only learn 
 that the proposition is true, but see that it must be true ; 
 in which the negation of the truth is not only false, but 
 impossible; in which we cannot, even by an effort of 
 imagination, or in a supposition, conceive the reverse of 
 that which is asserted. 
 
56 OF IDEAS IN GENERAL. 
 
 3. That there are such truths cannot be doubted. 
 We may take, for example, all relations of number. 
 Three and Two added together make Five. We cannot 
 conceive it to be otherwise. We cannot, by any freak 
 of thought, imagine Three and Two to make Seven. 
 
 It may be said that this assertion merely expresses 
 what we mean by our words ; that it is a matter of defi- 
 nition ; that the proposition is an identical one. 
 
 But this is by no means so. The definition of Five 
 is not Three and Two, but Four and One. How does it 
 appear that Three and Two is the same number as Four 
 and One ? It is evident that it is so ; but why is it evi- 
 dent ? not because the proposition is identical ; for if 
 that were the reason, all numerical propositions must be 
 evident for the same reason. If it be a matter of defi- 
 nition that 3 and 2 make 5, it must be a matter of defi- 
 nition that 39 and 27 make 66. But who will say that 
 the definition of 66 is 39 and 27 ? Yet the magnitude 
 of the numbers can make no difference in the ground of 
 the truth. How do we know that the product of 13 and 
 17 is 4 less than the product of 15 and 15? We see 
 that it is so, if we perform certain operations by the rules 
 of arithmetic ; but how do we know the truth of the 
 rules of arithmetic? If we divide 123375 by 987 ac- 
 cording to the process taught us at school, how are we 
 assured that the result is correct, and that the number 
 125 thus obtained is really the number of times one 
 number is contained in the other? 
 
 The correctness of the rule, it may be replied, can be 
 rigorously demonstrated. It can be shewn that the pro- 
 cess must inevitably give the true quotient. 
 
 Certainly this can be shown to be the case. And 
 precisely because it can be shown that the result must be 
 true, we have here an example of a necessary truth ; and 
 this truth, it appears, is not therefore necessary because it 
 
OF NECESSARY TRUTHS. 57 
 
 is itself evidently identical, however it may be possible to 
 prove it by reducing it to evidently identical propositions. 
 And the same is the case with all other numerical propo- 
 sitions ; for, as we have said, the nature of all of them is 
 the same. 
 
 Here, then, we have instances of truths which are 
 not only true, but demonstrably and necessarily true. 
 Now such truths are, in this respect at least, altogether 
 different from truths, which, however certain they may 
 be, are learnt to be so only by the evidence of observa- 
 tion, interpreted, as observation must be interpreted, by 
 our own mental faculties. There is no difficulty in find- 
 ing examples of these merely observed truths. We find 
 that sugar dissolves in water, and forms a transparent 
 fluid, but no one will say that we can see any reason 
 beforehand why the result must be so. We find that all 
 animals which chew the cud have also the divided hoof; 
 but could any one have predicted that this would be 
 universally the case ? or supposing the truth of the rule 
 to be known, can any one say that he cannot conceive 
 the facts as occurring otherwise ? Water expands when 
 it crystallizes, some other substances contract in the same 
 circumstances ; but can any one know that this will be 
 so otherwise than by observation ? We have here propo- 
 sitions rigorously true, (we will assume,) but can any 
 one say they are necessarily true ? These, and the great 
 mass of the doctrines established by induction, are actual, 
 but so far as we can see, accidental laws ; results deter- 
 mined by some unknown selection, not demonstrable 
 consequences of the essence of things, inevitable and 
 perceived to be inevitable. According to the phrase- 
 ology which has been frequently used by philosophical 
 writers, they are contingent, not necessary truths. 
 
 I It is requisite to insist upon this opposition, because 
 no insight can be obtained into the true nature of 
 
58 OF IDEAS IN GENERAL. 
 
 knowledge, and the mode of arriving at it, by any one 
 who does not clearly appreciate the distinction. The 
 separation of truths which are learnt by observation, and 
 truths which can be seen to be true by a pure act of 
 thought, is one of the first and most essential steps in 
 our examination of the nature of truth, and the mode of 
 its discovery. If any one does not clearly comprehend 
 this distinction of necessary and contingent truths, he 
 will not be able to go along with us in our researches 
 into the foundations of human knowledge ; nor, indeed, 
 to pursue with success any speculation on the subject. 
 But, in fact, this distinction is one that can hardly fail 
 to be at once understood. It is insisted upon by almost 
 all the best modern, as well as ancient, metaphysicians*, 
 as of primary importance. And if any person does not 
 fully apprehend, at first, the different kinds of truth thus 
 pointed out, let him study, to some extent, those sciences 
 which have necessary truth for their subject, as geometry, 
 or the properties of numbers, so as to obtain a familiar 
 acquaintance with such truth ; and he will then hardly 
 fail to see how different the evidence of the propositions 
 which occur in these sciences, is from the evidence of 
 the facts which are merely learnt from experience. 
 That the year goes through its course in 365 days, can 
 only be known by observation of the sun or stars : that 
 365 days is 52 weeks and a day, it requires no expe- 
 rience, but only a little thought to perceive. That bees 
 build their cells in the form of hexagons, we cannot 
 know without looking at them; that regular hexagons 
 may be arranged so as to fill space, may be proved with 
 the utmost rigour, even if there were not in existence 
 such a thing as a material hexagon. 
 
 4. As I have already said, one mode in which we 
 may express the difference of necessary truths and truths 
 
 * Aristotle, Dr. Whately, Dugald Stewart, &c. 
 
OF NECESSARY TRUTHS. 59 
 
 of experience, is, that necessary truths are those of which 
 we cannot distinctly conceive the contrary. We can 
 very readily conceive the contrary of experiential truths. 
 We can conceive the stars moving about the pole or 
 across the sky in any kind of curves with any velocities ; 
 we can conceive the moon always appearing during the 
 whole month as a luminous disk, as she might do if her 
 light were inherent and not borrowed. But we cannot 
 conceive one of the parallelograms on the same base and 
 between the same parallels larger than the other; for 
 we find that, if we attempt to do this, when we separate 
 the parallelograms into parts, we have to conceive one 
 triangle larger than another, both having all their parts 
 equal ; which we cannot conceive at all, if we conceive 
 the triangles distinctly. We make this impossibility 
 more clear by conceiving the triangles to be placed so 
 that two sides of the one coincide with two sides of the 
 other ; and it is then seen, that in order to conceive the 
 triangles unequal, we must conceive the two bases which 
 have the same extremities both ways, to be different 
 lines, though both straight lines. This it is impossible 
 to conceive : we assent to the impossibility as an axiom, 
 when it is expressed by saying, that two straight lines 
 cannot inclose a space; and thus we cannot distinctly 
 conceive the contrary of the proposition just mentioned 
 respecting parallelograms. 
 
 But it is necessary, in applying this distinction, to 
 bear in mind the terms of it ; that we cannot distinctly 
 conceive the contrary of a necessary truth. For in a 
 certain loose, indistinct way, persons conceive the con- 
 trary of necessary geometrical truths, when they erro- 
 neously conceive false propositions to be true. Thus, 
 Hobbes erroneously held that he had discovered a means 
 of geometrically doubling the cube, as it is called, that 
 is, finding two mean proportionals between two given 
 
60 OF IDEAS IN GENERAL. 
 
 lines ; a problem which cannot be solved by plane 
 geometry. Hobbes not only proposed a construction for 
 this purpose, but obstinately maintained that it was 
 right, when it had been proved to be wrong. But then, 
 the discussion showed how indistinct the geometrical 
 conceptions of Hobbes were ; for when his critics had 
 proved that one of the lines in his diagram would not 
 meet the other in the point which his reasoning sup- 
 posed, but in another point near to it ; he maintained, in 
 reply, that one of these points was large enough to 
 include the other, so that they might be considered as 
 the same point. Such a mode of conceiving the oppo- 
 site of a geometrical truth, forms no exception to the 
 assertion, that this opposite cannot be distinctly con- 
 ceived. 
 
 In like manner, the indistinct conceptions of children 
 and of rude savages do not invalidate the distinction of 
 necessary and experiential truths. Children and savages 
 make mistakes even with regard to numbers ; and might 
 easily happen to assert that 27 and 38 are equal to 63 
 or 64. But such mistakes cannot make arithmetical 
 truths cease to be necessary truths. When any person 
 conceives these numbers and their addition distinctly, by 
 resolving them into parts, or in any other way, he sees 
 that their sum is necessarily 65. If, on the ground of 
 the possibility of children and savages conceiving some- 
 thing different, it be held that this is not a necessary 
 truth, it must be held on the same ground, that it is not 
 a necessary truth that 7 and 4 are equal to 11; for 
 children and savages might be found so unfamiliar with 
 numbers as not to reject the assertion that 7 and 4 are 
 10, or even that 4 and 3 are 6, or 8. But I suppose 
 that no persons would on such grounds hold that these 
 arithmetical truths arc truths known only by experi- 
 ence. 
 
OF NECESSARY TRUTHS. 61 
 
 5. I have taken examples of necessary truths from 
 the properties of number and space; but such truths exist 
 no less in other subjects, although the discipline of 
 thought which is requisite to perceive them distinctly, 
 may not be so usual among men with regard to the 
 sciences of mechanics and hydrostatics, as it is with 
 regard to the sciences of geometry and arithmetic. Yet 
 every one may perceive that there are such truths in 
 mechanics. If I press the table with my hand, the 
 table presses my hand with an equal force : here is a 
 self-evident and necessary truth. In any machine, 
 constructed in whatever manner to increase the force 
 which I can exert, it is certain that what I gain in force 
 I must lose in the velocity which I communicate. This 
 is not a contingent truth, borrowed from and limited by 
 observation ; for a man of sound mechanical views applies 
 it with like confidence, however novel be the construc- 
 tion of the machine. When I come to speak of the ideas 
 which are involved in our mechanical knowledge, I 
 may, perhaps, be able to bring more clearly into view 
 the necessary truth of general propositions on such 
 subjects. That reaction is equal and opposite to action, 
 is as necessarily true as that two straight lines cannot 
 inclose a space ; it is as impossible theoretically to make 
 a perpetual motion by mere mechanism as to make the 
 diagonal of a square commensurable with the side. 
 
 6. Necessary truths must be universal truths. If any 
 property belong to a right-angled triangle necessarily, it 
 must belong to all right-angled triangles. And it shall 
 be proved in the following Chapter, that truths possess- 
 ing these two characters, of Necessity and Universality, 
 cannot possibly be the mere results of experience. 
 
62 
 
 CHAPTER V. 
 OF EXPERIENCE. 
 
 1. I HERE employ the term Experience in a more defi- 
 nite and limited sense than that which it possesses in 
 common usage ; for I restrict it to matters belonging to 
 the domain of science. In such cases, the knowledge 
 which we acquire, by means of experience, is of a clear 
 and precise nature ; and the passions and feelings and 
 interests, which make the lessons of experience in prac- 
 tical matters so difficult to read aright, no longer disturb 
 and confuse us. We may, therefore, hope, by attending 
 to such cases, to learn what efficacy experience really 
 has, in the discovery of truth. 
 
 That from experience (including intentional expe- 
 rience, or observation,} we obtain much knowledge which 
 is highly important, and which could not be procured 
 from any other source, is abundantly clear. We have 
 already taken several examples of such knowledge. 
 We know by experience that animals which ruminate 
 are cloven-hoofed ; and we know this in no other man- 
 ner. We know, in like manner, that all the planets and 
 their satellites revolve round the sun from west to east. 
 It has been found by experience that all meteoric stones 
 contain chrome. Many similar portions of our know- 
 ledge might be mentioned. 
 
 Now what we have here to remark is this ; that in 
 no case can experience prove a proposition to be neces- 
 sarily or universally true. However many instances we 
 may have observed of the truth of a proposition, yet if it be 
 known merely by observation, there is nothing to assure 
 us that the next case shall not be an exception to the rule. 
 If it be strictly true that every ruminant animal yet 
 known has cloven hoofs, we still cannot be sure that 
 
OF EXPERIENCE. 63 
 
 some creature will not hereafter be discovered which has 
 the first of these attributes without having the other. 
 When the planets and their satellites, as far as Saturn, had 
 been all found to move round the sun in one direction, 
 it was still possible that there might be other such bodies 
 not obeying this rule ; and, accordingly, when the satel- 
 lites of Uranus were detected, they appeared to offer an 
 exception of this kind. Even in the mathematical sciences, 
 we have examples of such rules suggested by experience, 
 and also of their precariousness. However far they may 
 have been tested, we cannot depend upon their correct- 
 ness, except we see some reason for the rule. For 
 instance, various rules have been given, for the purpose 
 of pointing out prime numbers; that is, those which can- 
 not be divided by any other number. We may try, as 
 an example of such a rule, this one any odd power of 
 the number two, diminished by one. Thus the third 
 power of two, diminished by one, is seven; the fifth 
 power, diminished by one, is thirty-one; the seventh 
 power so diminished is one hundred and twenty-seven. 
 All these are prime numbers : and we might be led to 
 suppose that the rule is universal. But the next ex- 
 ample shows us the fallaciousness of such a belief. The 
 ninth power of two, diminished by one, is five hundred 
 and eleven, which is not a prime, being divisible by seven. 
 Experience must always consist of a limited number 
 of observations. And, however numerous these may be, 
 they can show nothing with regard to the infinite 
 number of cases in which the experiment has not been 
 made. Experience being thus unable to prove a fact 
 to be universal, is, as will readily be seen, still more 
 incapable of proving a truth to be necessary. Expe- 
 rience cannot, indeed, offer the smallest ground for the 
 necessity of a proposition. She can observe and record 
 what has happened ; but she cannot find, in any case, or 
 
64 OF IDEAS IN GENERAL. 
 
 in any accumulation of cases, any reason for what mitxt 
 happen. She may see objects side by side ; but she 
 cannot see a reason why they must ever be side by side. 
 She finds certain events to occur in succession ; but the 
 succession supplies, in its occurrence, no reason for its 
 recurrence. She contemplates external objects ; but she 
 cannot detect any internal bond, which indissolubly 
 connects the future with the past, the possible with the 
 real. To learn a proposition by experience, and to see 
 it to be necessarily true, are two altogether different pro- 
 cesses of thought. 
 
 2. But it may be said, that we do learn by means 
 of observation and experience many universal truths; 
 indeed, all the general truths of which science consists. 
 Is not the doctrine of universal gravitation learnt by 
 experience ? Are not the laws of motion, the properties 
 of light, the general principles of chemistry, so learnt ? 
 How, with these examples before us, can we say that 
 experience teaches no universal truths? 
 
 To this we reply, that these truths can only be 
 known to be general, not universal, if they depend upon 
 experience alone. Experience cannot bestow that uni- 
 versality which she herself cannot have, and that necessity 
 of which she has no comprehension. If these doctrines 
 are universally true, this universality flows from the ideas 
 which we apply to our experience, and which are, as we 
 have seen, the real sources of necessary truth. How far 
 these ideas can communicate their universality and 
 necessity to the results of experience, it will hereafter 
 be our business to consider. It will then appear, that 
 when the mind collects from observation truths of a wide 
 and comprehensive kind, which approach to the sim- 
 plicity and universality of the truths of pure science ; 
 she gives them this character by throwing upon them 
 the light of her own Fundamental Ideas. 
 
OF EXPERIENCE. 05 
 
 But the truths which we discover by observation of 
 the external world, even when most strikingly simple 
 and universal, are not necessary truths. Is the doctrine 
 of universal gravitation necessarily true ? It was doubted 
 by Clairaut (so far as it refers to the moon), when the 
 progression of the apogee in fact appeared to be twice 
 as great as the theory admitted. It has been doubted, 
 even more recently, with respect to the planets, their 
 mutual perturbations appearing to indicate a deviation 
 from the law. It is doubted still, by some persons, with 
 respect to the double stars. But suppose all these 
 doubts to be banished, and the law to be universal ; is it 
 then proved to be necessary ? Manifestly not : the very 
 existence of these doubts proves that it is not so. For 
 the doubts were dissipated by reference to observation 
 and calculation, not by reasoning on the nature of the 
 law. Clairaut's difficulty was removed by a more exact 
 calculation of the effect of the sun's force on the motion 
 of the apogee. The suggestion of Bessel, that the in- . 
 tensity of gravitation might be different for different 
 planets, was found to be unnecessary, when Professor 
 Airy gave a more accurate determination of the mass of 
 Jupiter. And the question whether the extension of the 
 law of the inverse square to the double stars be true, 
 (one of the most remarkable questions now before the 
 scientific world,) must be answered, not by any specula- 
 tions concerning what the laws of attraction must neces- 
 sarily be, but by carefully determining the actual laws 
 of the motion of these curious objects, by means of the 
 observations such as those which Sir John Herschel has 
 collected for that purpose, by his unexampled survey of 
 both hemispheres of the sky. And since the extent of 
 this truth is thus to be determined by reference to ob- 
 served facts, it is clear that no mere accumulation of 
 VOL. i. w. P. F 
 
66 OF IDEAS IN GENERAL. 
 
 them can make its universality certain, or its necessity 
 apparent. 
 
 Thus no knowledge of the necessity of any truths 
 can result from the observation of what really happens. 
 This being clearly understood, we are led to an import- 
 ant inquiry. 
 
 The characters of universality and necessity in the 
 truths which form part of our knowledge, can never 
 be derived from experience, by which so large a part 
 of our knowledge is obtained. But since, as we have 
 seen, we really do possess a large body of truths which 
 are necessary, and because necessary, therefore universal, 
 the question still recurs, from what source these charac- 
 ters of universality and necessity are derived. 
 
 The answer to this question we will attempt to give 
 in the next chapter. 
 
 CHAPTER VI. 
 OF THE GROUNDS OF NECESSARY TRUTHS. 
 
 1 . To the question just stated, I reply, that the neces- 
 sity and universality of the truths which form a part of 
 our knowledge, are derived from the Fundamental Ideas 
 which those truths involve. These ideas entirely shape 
 and circumscribe our knowledge ; they regulate the ac- 
 tive operations of our minds, without which our passive 
 sensations do not become knowledge. They govern 
 these operations, according to rules which are not only 
 fixed and permanent, but which may be expressed in 
 plain and definite terms; and these rules, when thus 
 expressed, may be made the basis of demonstrations by 
 which the necessary relations imparted to our know- 
 ledge by our Ideas may be traced to their consequences 
 in the most remote ramifications of scientific truth. 
 
GROUNDS OF NECESSARY TRUTHS. 67 
 
 These enunciations of the necessary and evident con- 
 ditions imposed upon our knowledge by the Fundamental 
 Ideas which it involves, are termed Axioms. Thus the 
 Axioms of Geometry express the necessary conditions 
 which result from the Idea of Space; the Axioms of 
 Mechanics express the necessary conditions which flow 
 from the Ideas of Force and Motion ; and so on. 
 
 2. It will be the office of several of the succeeding 
 Books of this work to establish and illustrate in detail 
 what I have thus stated in general terms. I shall there 
 pass in review many of the most important fundamental 
 ideas on which the existing body of our science depends ; 
 and I shall endeavour to show, for each such idea in 
 succession, that knowledge involves an active as well as 
 a passive element ; that it is not possible without an act 
 of the mind, regulated by certain laws. I shall further 
 attempt to enumerate some of the principal fundamental 
 relations which each idea thus introduces into our 
 thoughts, and to express them by means of definitions 
 and axioms, and other suitable forms. 
 
 I will only add a remark or two to illustrate further 
 this view of the ideal grounds of our knowledge. 
 
 3. To persons familiar with any of the demonstrative 
 sciences, it will be apparent that if we state all the 
 Definitions and Axioms which are employed in the 
 demonstrations, we state the whole basis on which those 
 reasonings rest. For the whole process of demonstrative 
 or deductive reasoning in any science, (as in geometry, 
 for instance,) consists entirely in combining some of these 
 first principles so as to obtain the simplest propositions 
 of the science; then combining these so as to obtain 
 other propositions of greater complexity ; and so on, till 
 we advance to the most recondite demonstrable truths ; 
 these last, however, intricate and unexpected, still in- 
 volving no principles except the original definitions and 
 
68 OF IDEAS IN GENERAL. 
 
 axioms. Thus, by combining the Definition of a triangle, 
 arid the Definitions of equal lines and equal angles, 
 namely, that they are such as when applied to each 
 other, coincide, with the Axiom respecting straight lines 
 (that two such lines cannot inclose a space,) we demon- 
 strate the equality of triangles, under certain assumed 
 conditions. Again, by combining this result with the 
 Definition of parallelograms, and with the Axiom that if 
 equals be taken from equals the wholes are equal, we 
 prove the equality of parallelograms between the same 
 parallels and upon the same base. From this proposi- 
 tion, again, we prove the equality of the square on the 
 hypotenuse of a triangle to the squares on the two sides 
 containing the right angle. But in all this there is 
 nothing contained which is not rigorously the result of 
 our geometrical Definitions and Axioms. All the rest 
 of our treatises of geometry consists only of terms and 
 phrases of reasoning, the object of which is to connect 
 those first principles, and to exhibit the effects of their 
 combination in the shape of demonstration. 
 
 4. This combination of first principles takes place 
 according to the forms and rules of Logic. All the 
 steps of the demonstration may be stated in the shape in 
 which logicians are accustomed to exhibit processes of 
 reasoning in order to show their conclusiveness, that is, 
 in Syllogisms. Thus our geometrical reasonings might 
 be resolved into such steps as the following : 
 
 All straight lines drawn from the centre of a circle 
 to its circumference are equal : 
 
 But the straight lines AB, AC, are drawn from the 
 centre of a circle to its circumference : 
 
 Therefore the straignt lines AB, AC, are equal. 
 
 Each step of geometrical, and all other demonstra- 
 tive reasoning, may be resolved into three such clauses 
 as these ; and these three clauses are termed respectively, 
 
GROUNDS OF NECESSARY TRUTHS. 69 
 
 the major premiss, the minor premiss, and the conclu- 
 sion; or, more briefly, the major, the minor, and the 
 conclusion. 
 
 The principle which justifies the reasoning when 
 exhibited in this syllogistic form, is this : that a truth 
 which can be asserted as generally, or rather as univer- 
 sally true, can be asserted as true also in each particular 
 case. The minor only asserts a certain particular case 
 to be an example of such conditions as are spoken of in 
 the major; and hence the conclusion, which is true of 
 the major by supposition, is true of the minor by conse- 
 quence ; and thus we proceed from syllogism to syl- 
 logism, in each one employing some general truth in 
 some particular instance. Any proof which occurs in 
 geometry, or any other science of demonstration, may 
 thus be reduced to a series of processes, in each of 
 which we pass from some general proposition to the 
 narrower and more special propositions which it in- 
 cludes. And this process of deriving truths by the mere 
 combination of general principles, applied in particular 
 hypothetical cases, is called deduction; being opposed 
 to induction, in which, as we have seen, (Chap. i. Sect. 3.) 
 a new general principle is introduced at every step. 
 
 5. Now we have to remark that, this being so, how- 
 ever far we follow such deductive reasoning, we can 
 never have, in our conclusion any truth which is not 
 virtually included in the original principles from which 
 the reasoning started. For since at any step we merely 
 take out of a general proposition something included in 
 it, while at the preceding step we have taken this ge- 
 neral proposition out of one more general, and so on 
 perpetually, it is manifest that our last result was really 
 included in the principle or principles with which we 
 began. I say principles, because, although our logical 
 conclusion can only exhibit the legitimate issue of our 
 
70 OF IDEAS IN GENERAL. 
 
 first principles, it may, nevertheless, contain the result 
 of the combination of several such principles, and may 
 thus assume a great degree of complexity, and may ap- 
 pear so far removed from the parent truths, as to betray 
 at first sight hardly any relationship with them. Thus 
 the proposition which has already been quoted respect- 
 ing the squares on the sides of a right-angled triangle, 
 contains the results of many elementary principles ; as, 
 the definitions of parallels, triangle, and square ; the 
 axioms respecting straight lines, and respecting paral- 
 lels; and, perhaps, others. The conclusion is compli- 
 cated by containing the effects of the combination of all 
 these elements ; but it contains nothing, and can contain 
 nothing, but such elements and their combinations. 
 
 This doctrine, that logical reasoning produces no new 
 truths, but only unfolds and brings into view those truths 
 which were, in effect, contained in the first principles of 
 the reasoning, is assented to by almost all who, in 
 modern times, have attended to the science of logic. 
 Such a view is admitted both by those who defend, and 
 by those who depreciate the value of logic. " Whatever 
 is established by reasoning, must have been contained 
 and virtually asserted in the premises*." "The only 
 truth which such propositions can possess consists in 
 conformity to the original principles." 
 
 In this manner the whole substance of our geometry 
 is reduced to the Definitions and Axioms which we 
 employ in our elementary reasonings ; and in like man- 
 ner we reduce the demonstrative truths of any other 
 science to the definitions and axioms which we there 
 employ. 
 
 6. But in reference to this subject, it has sometimes; 
 been said that demonstrative sciences do in reality depend 
 upon Definitions only; and that no additional kind of 
 
 * Whateley's Logic, pp. 237, 238. 
 
GROUNDS OF NECESSARY TRUTHS. 71 
 
 principle, such as we have supposed Axioms to be, is 
 absolutely required. It has been asserted that in geo- 
 metry, for example, the source of the necessary truth of 
 our propositions is this, that they depend upon definitions 
 alone, and consequently merely state the identity of the 
 same thing under different aspects. 
 
 That in the sciences which admit of demonstration, 
 as geometry, mechanics, and the like, Axioms as well as 
 Definitions are needed, in order to express the grounds 
 of our necessary convictions, must be shown hereafter 
 by an examination of each of these sciences in particular. 
 But that the propositions of these sciences, those of geo- 
 metry for example, do not merely assert the identity of 
 the same thing, will, I think, be generally allowed, if we 
 consider the assertions which we are enabled to make. 
 When we declare that " a straight line is the shortest 
 distance between two points," is this merely an identical 
 proposition? the definition of a straight line in another 
 form ? Not so : the definition of a straight line involves 
 the notion of form only, and does not contain anything 
 about magnitude; consequently, it cannot contain any- 
 thing equivalent to " shortest." Thus the propositions 
 of geometry are not merely identical propositions; nor 
 have we in their general character anything to coun- 
 tenance the assertion, that they are the results of defi- 
 nitions alone. And when we come to examine this and 
 other sciences more closely, we shall find that axioms, 
 such as are usually in our treatises made the funda- 
 mental principles of our demonstrations, neither have 
 ever been, nor can be, dispensed with. Axioms, as well 
 as Definitions, are in all cases requisite, in order pro- 
 perly to exhibit the grounds of necessary truth. 
 
 7. Thus the real logical basis of every body of demon- 
 strated truths are the Definitions and Axioms which are 
 the first principles of the reasonings. But when we are 
 
72 OF IDEAS IN GENERAL. 
 
 arrived at this point, the question further occurs, what 
 is the ground of the truth of these Axioms ? It is not 
 the logical, but the philosophical, not the formal, but the 
 real foundation of necessary truth, which we are seeking. 
 Hence this inquiry necessarily comes before us, What 
 is the ground of the Axioms of Geometry, of Mechanics, 
 and of any other demonstrable science ? 
 
 The answer which we are led to give, by the view 
 which we have taken of the nature of knowledge, has 
 already been stated. The ground of the axioms belong- 
 ing to each science is the Idea which the axiom involves. 
 The ground of the Axioms of Geometry is the Idea of 
 Space: the ground of the Axioms of Mechanics is the 
 Idea of Force, of Action and Reaction, and the like. And 
 hence these Ideas are Fundamental Ideas ; and since they 
 are thus the foundations, not only of demonstration but 
 of truth, an examination into their real import and 
 nature is of the greatest consequence to our purpose. 
 
 8. Not only the Axioms, but the Definitions which 
 form the basis of our reasonings, depend upon our Fun- 
 damental Ideas. And the Definitions are not arbitrary 
 definitions, but are determined by a necessity no less 
 rigorous than the Axioms themselves. We could not 
 think of geometrical truths without conceiving a circle ; 
 and we could not reason concerning such truths without 
 defining a circle in some mode equivalent to that which 
 is commonly adopted. The Definitions of parallels, of 
 right angles, and the like, are quite as necessarily pre- 
 scribed by the nature of the case, as the Axioms which 
 these Definitions bring with them. Indeed we may 
 substitute one of these kinds of principles for another. 
 We cannot always put a Definition in the place of an 
 Axiom ; but we may always find an Axiom which shall 
 take the place of a Definition. If we assume a proper 
 Axiom respecting straight lines, we need no Definition 
 
GROUNDS OF NECESSARY TRUTHS. 73 
 
 of a straight line. But in whatever shape the principle 
 appear, as Definition or as Axiom, it has about it nothing 
 casual or arbitrary, but is determined to be what it is, as 
 to its import, by the most rigorous necessity, growing 
 out of the Idea of Space. 
 
 9. These principles, Definitions, and Axioms, thus 
 exhibiting the primary developements of a fundamental 
 idea, do in fact express the idea, so far as its expression 
 in words forms part of our science. They are different 
 views of the same body of truth ; and though each prin- 
 ciple, by itself, exhibits only one aspect of this body, 
 taken together they convey a sufficient conception of it 
 for our purposes. The Idea itself cannot be fixed in 
 words; but these various lines of truth proceeding from 
 it, suggest sufficiently to a fitly-prepared mind, the place 
 where the idea resides, its nature, and its efficacy. 
 
 It is true that these principles, our elementary Defi- 
 nitions and Axioms, even taken altogether, express the 
 Idea incompletely. Thus the Definitions and Axioms of 
 Geometry, as they are stated in our elementary works, 
 do not fully express the Idea of Space as it exists in our 
 minds. For, in addition to these, other Axioms, inde- 
 pendent of these, and no less evident, can be stated ; and 
 are in fact stated when we come to the Higher Geo- 
 metry. Such, for instance, is the Axiom of Archimedes 
 that a curve line which joins two points is less than a 
 broken line which joins the same points and includes the 
 curve. And thus the Idea is disclosed but not fully re- 
 vealed, imparted but not transfused, by the use we make 
 of it in science. When we have taken from the fountain 
 so much as serves our purpose, there still remains behind 
 a deep well of truth, which we have not exhausted, and 
 which we may easily believe to be inexhaustible. 
 
74 
 
 CHAPTER VII. 
 
 THE FUNDAMENTAL IDEAS ARE NOT DERIVED 
 FROM EXPERIENCE. 
 
 1. BY the course of speculation contained in the last 
 three Chapters, we are again led to the conclusion which 
 we have already stated, that our knowledge contains an 
 ideal element, and that this element is not derived from 
 experience. For we have seen that there are proposi- 
 tions which are known to be necessarily true ; and that 
 such knowledge is not, and cannot be, obtained by mere 
 observation of actual facts. It has been shown, also, 
 that these necessary truths are the results of certain fun- 
 damental ideas, such as those of space, number, and the 
 like. Hence it follows inevitably that these ideas and 
 others of the same kind are not derived from experience. 
 For these ideas possess a power of infusing into their 
 developements that very necessity which experience can 
 in no way bestow. This power they do not borrow from 
 the external world, but possess by their own nature. 
 Thus we unfold out of the Idea of Space the propositions 
 of geometry, which are plainly truths of the most rigor- 
 ous necessity and universality. But if the idea of space 
 were merely collected from observation of the external 
 world, it could never enable or entitle us to assert such 
 propositions : it could never authorize us to say that not 
 merely some lines, but all lines, not only have, but must 
 have, those properties which geometry teaches. Geo- 
 metry in every proposition speaks a language which 
 experience never dares to utter; and indeed of which 
 she but half comprehends the meaning. Experience 
 sees that the assertions are true, but she sees not how 
 profound and absolute is their truth. She unhesitatingly 
 assents to the laws which geometry delivers, but she does 
 
FUNDAMENTAL IDEAS NOT DERIVATIVE. 75 
 
 not pretend to see the origin of their obligation. She 
 is always ready to acknowledge the sway of pure scien- 
 tific principles as a matter of fact, but she does not 
 dream of offering her opinion on their authority as a 
 matter of right ; still less can she justly claim to be her- 
 self the source of that authority. 
 
 David Hume asserted*, that we are incapable of 
 seeing in any of the appearances which the world pre- 
 sents anything of necessary connexion ; and hence he 
 inferred that our knowledge cannot extend to any such 
 connexion. It will be seen from what we have said that 
 we assent to his remark as to the fact, but we differ from 
 him altogether in the consequence to be drawn from it. 
 Our inference from Hume's observation is, not the truth 
 of his conclusion, but the falsehood of his premises ; 
 not that, therefore, we can know nothing of natural con- 
 nexion, but that, therefore, we have some other source of 
 knowledge than experience : not, that we can have no 
 idea of connexion or causation, because, in his language, 
 it cannot be the copy of an impression ; but that since 
 we have such an idea, our ideas are not the copies of 
 our impressions. 
 
 Since it thus appears that our fundamental ideas are 
 not acquired from the external world by our senses, but 
 have some separate and independent origin, it is im- 
 portant for us to examine their nature and properties, as 
 they exist in themselves; and this it will be our business 
 to do through a portion of the following pages. But it 
 may be proper first to notice one or two objections 
 which may possibly occur to some readers. 
 
 2. It may be said that without the use of our senses,, 
 of sight and touch, for instance, we should never have 
 any idea of space ; that this idea, therefore, may properly 
 be said to be derived from those senses. And to this I 
 
 * Essays, Vol. n. p. 70- 
 
76 OF IDEAS IN GENERAL. 
 
 reply, by referring to a parallel instance. Without light 
 we should have no perception of visible figure ; yet the 
 power of perceiving visible figure cannot be said to be 
 derived from the light, but resides in the structure of the 
 eye. If we had never seen objects in the light, we 
 should be quite unaware that we possessed a power of 
 vision ; yet we should not possess it the less on that 
 account. If we had never exercised the senses of sight 
 and touch (if we can conceive such a state of human ex- 
 istence) we know not that we should be conscious of an 
 idea of space. But the light reveals to us at the same 
 time the existence of external objects and our own power 
 of seeing. And in a very similar manner, the exercise 
 of our senses discloses to us, at the same time, the ex- 
 ternal world, and our own ideas of space, time, and other 
 conditions, without which the external world can neither 
 be observed nor conceived. That light is necessary to 
 vision, does not, in any degree, supersede the importance 
 of a separate examination of the laws of our visual 
 powers, if we would understand the nature of our own 
 bodily faculties and the extent of the information they 
 can give us. In like manner, the fact that intercourse 
 with the external world is necessary for the conscious 
 employment of our ideas, does not make it the less es- 
 sential for us to examine those ideas in their most inti- 
 mate structure, in order that we may understand the 
 grounds and limits of our knowledge. Even before we 
 see a single object, we have a faculty of vision ; and in 
 like manner, if we can suppose a man who has never 
 contemplated an object in space or time, we must still 
 assume him to have the faculties of entertaining the ideas 
 of space and time, which faculties are called into play 
 on the very first occasion of the use of the senses. 
 
 3. In answer to such remarks as the above, it has 
 sometimes been said that to assume separate faculties in 
 
FUNDAMENTAL IDEAS NOT DERIVATIVE. 77 
 
 the mind for so many different processes of thought, is to 
 give a mere verbal explanation, since we learn nothing 
 concerning our idea of space by being told that we have 
 a faculty of forming such an idea. R has been said that 
 this course of explanation leads to an endless multipli- 
 cation of elements in man's nature, without any advan- 
 tage to our knowledge of his true constitution. We 
 may, it is said, assert man to have a faculty of walking, 
 of standing, of breathing, of speaking ; but what, it is 
 asked, is gained by such assertions? To this I reply, that 
 we undoubtedly have such faculties as those just named; 
 that it is by no means unimportant to consider them; and 
 that the main question in such cases is, whether they are 
 separate and independent faculties, or complex and deri- 
 vative ones ; and, if t-he latter be the case, what are the 
 simple and original faculties by the combination of which 
 the others are produced. In walking, standing, breath- 
 ing, for instance, a great part of the operation can be 
 reduced to one single faculty ; the voluntary exercise of 
 our muscles. But in breathing this does not appear to 
 be the whole of the process. The operation is, in part at 
 least, involuntary ; and it has been held that there is a 
 certain sympathetic action of the nerves, in addition to 
 the voluntary agency which they transmit, which is essen- 
 tial to the function. To determine whether or no this 
 sympathetic faculty is real and distinct, and if so, what 
 are its laws and limits, is certainly a highly philosophical 
 inquiry, and well deserving the attention which has been 
 bestowed upon it by eminent physiologists. And just of 
 the same nature are the inquiries with respect to man's 
 intellectual constitution, on which we propose to enter. 
 For instance, man has a faculty of apprehending time, 
 and a faculty of reckoning numbers: are these distinct, or 
 is one faculty derived from the other? To analyze the 
 various combinations of our ideas and observations into 
 
78 OF IDEAS IN GENERAL. 
 
 the original faculties which they involve ; to show that 
 these faculties are original, and not capable of further 
 analysis : to point out the characters which mark these 
 faculties and lead to the most important features of our 
 knowledge; these are the kind of researches on which 
 we have now to enter, and these, we trust, will be found 
 to be far from idle or useless parts of our plan. If we 
 succeed in such attempts, it will appear that it is by 
 no means a frivolous or superfluous step to distinguish 
 separate faculties in the mind. If we do not learn much 
 by being told that we have a faculty of forming the idea 
 of space, we at least, by such a commencement, circum- 
 scribe a certain portion of the field of our investigations, 
 which, we shall afterwards endeavour to show, requires 
 and rewards a special examination. And though we shall 
 thus have to separate the domain of our philosophy into 
 many provinces, these are, as we trust it will appear, 
 neither arbitrarily assigned, nor vague in their limits, 
 nor infinite in number. 
 
 CHAPTER VIII. 
 OF THE PHILOSOPHY OF THE SCIENCES. 
 
 WE proceed, in the ensuing Books, to the closer exami- 
 nation of a considerable number of those Fundamental 
 Ideas on which the sciences, hitherto most successfully 
 cultivated, are founded. In this task, our objects will 
 be to explain and analyze such Ideas so as to bring into 
 view the Definitions and Axioms, or other forms, in 
 which we may clothe the conditions to which our specu- 
 lative knowledge is subjected. I shall also try to prove, 
 for some of these Ideas in particular, what has been 
 already urged respecting them in general, that they are 
 
PHILOSOPHY OF SCIENCES. 79 
 
 not derived from observation, but necessarily impose 
 their conditions upon that knowledge of which observa- 
 tion supplies the materials. I shall further, in some 
 cases, endeavour to trace the history of these Ideas as 
 they have successively come into notice in the progress 
 of science; the gradual developement by which they have 
 arrived at their due purity and clearness; and, as a 
 necessary part of such a history, I shall give a view of 
 some of the principal controversies which have taken 
 place with regard to each portion of knowledge. 
 
 An exposition and discussion of the Fundamental 
 Ideas of each Science may, with great propriety, be 
 termed the PHILOSOPHY OF such SCIENCE. These ideas 
 contain in themselves the elements of those truths which 
 the science discovers and enunciates; and in the progress 
 of the sciences, both in the world at large and in the 
 mind of each individual student, the most important 
 steps consist in apprehending these ideas clearly, and in 
 bringing them into accordance with the observed facts. 
 I shall, therefore, in a series of Books, treat of the Phi- 
 losophy of the Pure Sciences, the Philosophy of the 
 Mechanical Sciences, the Philosophy of Chemistry, and 
 the like, and shall analyze and examine the ideas which 
 these sciences respectively involve. 
 
 In this undertaking, inevitably somewhat long, and 
 involving many deep and subtle discussions, I shall take, 
 as a chart of the country before me, by which my course 
 is to be guided, the scheme of the sciences which I was 
 led to form by travelling over the history of each in 
 order"'". Each of the sciences of which I then narrated 
 the progress, depends upon several of the Fundamental 
 Ideas of which I have to speak : some of these Ideas are 
 peculiar to one field of speculation, others are common 
 to more. A previous enumeration of Ideas thus collected 
 
 * History of the Inductive Sciences. 
 
80 OF IDEAS IN GENERAL. 
 
 may serve both to show the course and limits of this part 
 of our plan, and the variety of interest which it offers. 
 
 I shall, then, successively, have to speak of the Ideas 
 which are the foundation of Geometry and Arithmetic, 
 (and which also regulate all sciences depending upon 
 these, as Astronomy and Mechanics;) namely, the Ideas 
 of Space, Time, and Number : 
 
 Of the Ideas on which the Mechanical Sciences (as 
 Mechanics, Hydrostatics, Physical Astronomy) more pecu- 
 liarly rest ; the ideas of Force and Matter, or rather the 
 idea of Cause, which is the basis of these : 
 
 Of the Ideas which the Secondary Mechanical Sciences 
 (Acoustics, Optics, and Thermotics) involve ; namely, the 
 Ideas of the Externality of objects, and of the Media 
 by which we perceive their qualities : 
 
 Of the Ideas which are the basis of Mechanico-che- 
 mical and Chemical Science; Polarity, Chemical Affinity, 
 and Substance ; and the Idea of Symmetry, a necessary 
 part of the Philosophy of Crystallography : 
 
 Of the Ideas on which the Classificatory Sciences 
 proceed (Mineralogy, Botany, and Zoology) ; namely, the 
 Ideas of Resemblance, and of its gradations, and of 
 Natural Affinity: 
 
 Finally, of those Ideas on which the Physiological 
 Sciences are founded ; the Ideas of separate Vital Powers, 
 such as Assimilation and Irritability ; and the Idea of 
 Final Cause. 
 
 We have, besides these, the Palsetiological Sciences, 
 which proceed mainly on the conception of Historical 
 Causation. 
 
 It is plain that when we have proceeded so far as 
 this, we have advanced to the verge of those speculations 
 which have to do with mind as well as body. The 
 extension of our philosophy to such a field, if it can be 
 justly so extended, will be one of the most important 
 
PHILOSOPHY OF SCIENCES. 81 
 
 results of our researches; but on that very account we 
 must fully study the lessons which we learn in those 
 fields of speculation where our doctrines are most secure, 
 before we venture into a region where our principles will 
 appear to be more precarious, and where they are inevi- 
 tably less precise. 
 
 We now proceed to the examination of the above 
 Ideas, and to such essays towards the philosophy of each 
 Science as this course of investigation may suggest. 
 
 VOL. i. w. p. 
 
82 
 
 BOOK II. 
 
 THE PHILOSOPHY OF THE PURE 
 SCIENCES. 
 
 CHAPTER I. 
 OF THE PUKE SCIENCES. 
 
 1. ALL external objects and events which we can con- 
 template are viewed as having relations of Space, Time, 
 and Number ; and are subject to the general conditions 
 which these Ideas impose, as well as to the particular 
 laws which belong to each class of objects and occur- 
 rences. The special laws of nature, considered under 
 the various aspects which constitute the different sciences, 
 are obtained by a mixed reference to experience and to 
 the fundamental ideas of each science. But besides the 
 sciences thus formed by the aid of special experience, the 
 conditions which flow from those more comprehensive 
 ideas first mentioned, Space, Time, and Number, consti- 
 tute a body of science, applicable to objects and changes 
 of all kinds, and deduced without recurrence being had 
 to any observation in particular. These sciences, thus 
 unfolded out of ideas alone, unmixed with any reference 
 to the phenomena of matter, are hence termed Pure 
 Sciences. The principal sciences of this class are Geome- 
 try, Theoretical Arithmetic, and Algebra considered in its 
 most general sense, as the investigation of the relations 
 of space and number by means of general symbols. 
 
OF THE PUEE SCIENCES. 83 
 
 2. These Pure Sciences were not included in our 
 survey of the history of the sciences, because they are 
 not inductive sciences. Their progress has not consisted 
 in collecting laws from phenomena, true theories from 
 observed facts, and more general from more limited laws ; 
 but in tracing the consequences of the ideas themselves, 
 and in detecting the most general and intimate analogies 
 and connexions which prevail among such conceptions as 
 are derivable from the ideas. These sciences have no 
 principles besides definitions and axioms, and no process 
 of proof but deduction ; this process, however, assuming 
 here a most remarkable character ; and exhibiting a com- 
 bination of simplicity and complexity, of rigour and 
 generality, quite unparalleled in other subjects. 
 
 3. The universality of the truths, and the rigour of 
 the demonstrations of these pure sciences, attracted 
 attention in the earliest times ; and it was perceived that 
 they offered an exercise and a discipline of the intellec- 
 tual faculties, in a form peculiarly free from admixture 
 of extraneous elements. They were strenuously culti- 
 vated by the Greeks, both with a view to such a disci- 
 pline, and from the love of speculative truth which pre- 
 vailed among that people : and the name mathematics, by 
 which they are designated, indicates this their character 
 of disciplinal studies. 
 
 4. As has already been said, the ideas which these 
 sciences involve extend to all the objects and changes 
 which we observe in the external world ; and hence the 
 consideration of mathematical relations forms a large 
 portion of many of the sciences which treat of the phe- 
 nomena and laws of external nature, as Astronomy, 
 Optics, and Mechanics. Such sciences are hence often 
 termed Mixed Mathematics, the relations of space and 
 number being, in these branches of knowledge, combined 
 with principles collected from special observation ; 
 
 G2 
 
84 PHILOSOPHY OF THE PURE SCIENCES. 
 
 while Geometry, Algebra, and the like subjects, which 
 involve no result of experience, are called Pure Mathe- 
 matics. 
 
 5. Space, time, and number, may be conceived as 
 forms by which the knowledge derived from our sensa- 
 tions is moulded, and which are independent of the dif- 
 ferences in the matter of our knowledge, arising from the 
 sensations themselves. Hence the sciences which have 
 these ideas for their subject may be termed Formal 
 Sciences. In this point of view, they are distinguished 
 from sciences in which, besides these mere formal laws 
 by which appearances are corrected, we endeavour to 
 apply to the phenomena the idea of cause, or some of the 
 other ideas which penetrate further into the principles 
 of nature. We have thus, in the History, distinguished 
 Formal Astronomy and Formal Optics from Physical 
 Astronomy and Physical Optics. 
 
 We now proceed to our examination of the Ideas 
 which constitute the foundation of these formal or pure 
 mathematical sciences, beginning with the Idea of Space. 
 
 CHAPTER II. 
 OF THE IDEA OF SPACE. 
 
 1. BY speaking of space as an Idea, I intend to imply, 
 as has already been stated, that the apprehension of 
 objects as existing in space, and of the relations of posi- 
 tion, &c., prevailing among them, is not a consequence 
 of experience, but a result of a peculiar constitution and 
 activity of the mind, which is independent of all expe- 
 rience in its origin, though constantly combined with 
 experience in its exercise. 
 
 That the idea of space is thus independent of experi- 
 ence, has already been pointed out in speaking of ideas 
 
OF THE IDEA OF SPACE. 85 
 
 in general : but it may be useful to illustrate the doctrine 
 further in this particular case. 
 
 I assert, then, that space is not a notion obtained 
 by experience. Experience gives us information con- 
 cerning things without us : but our apprehending them 
 as without us, takes for granted their existence in space. 
 Experience acquaints us what are the form, position, 
 magnitude of particular objects : but that they have form, 
 position, magnitude, presupposes that they are in space. 
 We cannot derive from appearances, by the way of 
 observation, the habit of representing things to ourselves 
 as in space ; for no single act of observation is possible 
 any otherwise than by beginning with such a representa- 
 tion, and conceiving objects as already existing in space. 
 
 2. That our mode of representing space to ourselves 
 is not derived from experience, is clear also from this : 
 that through this mode of representation we arrive at 
 propositions which are rigorously universal and neces- 
 sary. Propositions of such a kind could not possibly be 
 obtained from experience ; for experience can only teach 
 us by a limited number of examples, and therefore can 
 never securely establish a universal proposition: and 
 again, experience can only inform us that anything is so, 
 and can never prove that it must be so. That two sides 
 of a triangle are greater than the third is a universal 
 and necessary geometrical truth: it is true of all tri- 
 angles ; it is true in such a way that the contrary cannot 
 be conceived. Experience could not prove such a propo- 
 sition. And experience has not proved it ; for perhaps 
 no man ever made the trial as a means of removing 
 doubts : and no trial could, in fact, add in the smallest 
 degree to the certainty of this truth. To seek for proof 
 of geometrical propositions by an appeal to observation 
 proves nothing in reality, except that the person who 
 has recourse to such grounds has no due apprehension 
 
86 PHILOSOPHY OF THE PURE SCIENCES. 
 
 of the nature of geometrical demonstration. We have 
 heard of persons who convinced themselves by measure- 
 ment that the geometrical rule respecting the squares 
 on the sides of a right-angled triangle was true : but 
 these were persons whose minds had been engrossed by 
 practical habits, and in whom the speculative develope- 
 ment of the idea of space had been stifled by other em- 
 ployments. The practical trial of the rule may illustrate, 
 but cannot prove it. The rule will of course be con- 
 firmed by such trial, because what is true in general is 
 true in particular: but the rule cannot be proved from any 
 number of trials, for no accumulation of particular cases 
 makes up a universal case. To all persons who can see 
 the force of any proof, the geometrical rule above referred 
 to is as evident, and its evidence as independent of ex- 
 perience, as the assertion that sixteen and nine make 
 twenty-five. At the same time, the truth of the geome- 
 trical rule is quite independent of numerical truths, and 
 results from the relations of space alone. This could 
 not be if our apprehension of the relations of space were 
 the fruit of experience : for experience has no element 
 from which such truth and such proof could arise. 
 
 3. Thus the existence of necessary truths, such as 
 those of geometry, proves that the idea of space from 
 which they flow, is not derived from experience. Such 
 truths are inconceivable on the supposition of their being 
 collected from observation ; for the impressions of sense 
 include no evidence of necessity. But we can readily 
 understand the necessary character of such truths, if we 
 conceive that there are certain necessary conditions under 
 which alone the mind receives the impressions of sense. 
 Since these conditions reside in the constitution of the 
 mind, and apply to every perception of an object to 
 which the mind can attain, we easily see that their rules 
 must include, not only all that has been, but all that can 
 
OF THE IDEA OF SPACE. 87 
 
 be, matter of experience. Our sensations can each con- 
 vey no information except about itself; each can contain 
 no trace of another additional sensation ; and thus no 
 relation and connexion between two sensations can be 
 given by the sensations themselves. But the mode in 
 which the mind perceives these impressions as objects, 
 may and will introduce necessary relations among them : 
 and thus by conceiving the idea of space to be a con- 
 dition of perception in the mind, we can conceive the 
 existence of necessary truths, which apply to all per- 
 ceived objects. 
 
 4. If we consider the impressions of sense as the 
 mere materials of our experience, such materials may 
 be accumulated in any quantity and in any order. But 
 if we suppose that this matter has a certain form given 
 it, in the act of being accepted by the mind, we can 
 understand how it is that these materials are subject to 
 inevitable rules ; how nothing can be perceived exempt 
 from the relations which belong to such a form. And 
 since there are such truths applicable to our experience, 
 and arising from the nature of space, we may thus 
 consider space as a, form which the materials given by 
 experience necessarily assume in the mind; as an ar- 
 rangement derived from the perceiving mind, and not 
 from the sensations alone. 
 
 5. Thus this phrase, that space is a, form belonging 
 to our perceptive power, may be employed to express 
 that we cannot perceive objects as in space, without an 
 operation of the mind as well-*as of the senses without 
 active as well as passive faculties. This phrase, how- 
 ever, is not necessary to the exposition of our doctrines. 
 Whether we call the conception of space a condition of 
 perception, a form of perception, or an idea, or by any 
 other term, it is something originally inherent in the 
 mind perceiving, and not in the objects perceived. And 
 
88 PHILOSOPHY OF THE PURE SCIENCES. 
 
 it is because the apprehension of all objects is thus sub- 
 jected to certain mental conditions, forms or ideas, that 
 our knowledge involves certain inviolable relations and 
 necessary truths. The principles of such truths, so far 
 as they regard space, are derived from the idea of space, 
 and we must endeavour to exhibit such principles in 
 their general form. But before we do this, we may 
 notice some of the conditions which belong, not to our 
 Ideas in general, but to this Idea of Space in parti- 
 cular. 
 
 CHAPTER III. 
 
 OF SOME PECULARITIES OF THE IDEA OF 
 
 SPACE. 
 
 1. SOME of the Ideas which we shall have to examine 
 involve conceptions of certain relations of objects, as the 
 idea of Cause and of Likeness ; and may appear to be 
 suggested by experience, enabling us to abstract this 
 general relation from particular cases. But it will be 
 seen that Space is not such a general conception of a 
 relation. For we do not speak of Spaces as we speak of 
 Causes and Likenesses, but of Space. And when we 
 speak of spaces, we understand by the expression, parts 
 of one and the same identical every where -extended 
 Space. We conceive a Universal Space ; which is not 
 made up of these partial spaces as its component parts, 
 for it would remain if these were taken away ; and these 
 cannot be conceived without presupposing absolute space. 
 Absolute Space is essentially one ; and the complication 
 which exists in it, and the conception of various spaces, 
 depends merely upon boundaries. Space must, there- 
 fore, be, as we have said, not a general conception 
 abstracted from particulars, but a universal mode of 
 representation, altogether independent of experience. 
 
PECULIARITIES OF THE IDEA OF SPACE. 89 
 
 2. Space is infinite. We represent it to ourselves as 
 an infinitely great magnitude. Such an idea as that of 
 Likeness or Cause, is, no doubt, found in an infinite 
 number of particular cases, and so far includes these 
 cases. But these ideas do riot include an infinite number 
 of cases as parts of an infinite whole. When we say 
 that all bodies and partial spaces exist in infinite space, 
 we use an expression which is not applied in the same 
 sense to any cases except those of Space and Time. 
 
 3. What is here said may appear to be a denial of 
 the real existence of space. It must be observed, how- 
 ever, that we do not deny, but distinctly assert, the 
 existence of space as a real and necessary condition of 
 all objects perceived ; and that we not only allow that 
 objects are seen external to us, but we found upon the 
 fact of their being so seen, our view of the nature of 
 space. If, however, it be said that we deny the reality 
 of space as an object or thing, this is true. Nor does it 
 appear easy to maintain that space exists as a thing, 
 when it is considered that this thing is infinite in all its 
 dimensions; and, moreover, that it is a thing, which, 
 being nothing in itself, exists only that other things may 
 exist in it. And those who maintain the real existence 
 of space, must also maintain the real existence of time in 
 the same sense. Now two infinite things, thus really 
 existing, and yet existing only as other things exist in 
 them, are notions so extravagant that we are driven to 
 some other mode of explaining the state of the matter. 
 
 4. Thus space is not an object of which we perceive 
 the properties, but a form of our perception; not a thing 
 which affects our senses, but an idea to which we con- 
 form the impressions of sense. And its peculiarities ap- 
 pear to depend upon this, that it is not only a form of 
 sensation, but of intuition ; that in reference to space, 
 we not only perceive but contemplate objects. We see 
 
90 PHILOSOPHY OF THE PURE SCIENCES. 
 
 objects in space, side by side, exterior to each other; 
 space, and objects in so far as they occupy space, have 
 parts exterior to other parts ; and have the whole thus 
 made up by the juxtaposition of parts. This mode of 
 apprehension belongs only to the ideas of space and 
 time. Space and Time are made up of parts, but Cause 
 and Likeness are not apprehended as made up of parts. 
 And the term intuition (in its rigorous sense) is appli- 
 cable only to that mode of contemplation in which we 
 thus look at objects as made up of parts, and apprehend 
 the relations of those parts at the same time and by the 
 same act by which we apprehend the objects themselves. 
 
 5. As we have said, space limited by boundaries gives 
 rise to various conceptions which we have often to con- 
 sider. Thus limited, space assumes form or figure; and 
 the variety of conceptions thus brought under our notice 
 is infinite. We have every possible form of line, straight 
 line, and curve ; and of curves an endless number ; cir- 
 cles, parabolas, hyperbolas, spirals, helices. We have 
 plane surfaces of various shapes, parallelograms, poly- 
 gons, ellipses ; and we have solid figures, cubes, cones, 
 cylinders, spheres, spheroids, and so on. All these have 
 their various properties, depending on the relations of 
 their boundaries ; and the investigation of their proper- 
 ties forms the business of the science of Geometry. 
 
 6. Space has three dimensions, or directions in which 
 it may be measured ; it cannot have more or f\ver. The 
 simplest measurement is that of a straight line, which 
 has length alone. A surface has both length and 
 breadth : and solid space has length, breadth, and thick- 
 ness or depth. The origin of such a difference of dimen- 
 sions will be seen if we reflect that each portion of space 
 has a boundary, and is extended both in the direction in 
 which its boundary extends, and also in a direct ion from 
 its boundary ; for otherwise it would not be a boundary. 
 
PECULARITIES OF THE IDEA OF SPACE. 91 
 
 A point has no dimensions. A line has but one dimen- 
 sion, the distance from its boundary, or its length. A 
 plane, bounded by a straight line, has the dimension 
 which belongs to this line, and also has another dimen- 
 sion arising from the distance of its parts from this bound- 
 ary line; and this may be called breadth. A solid, 
 bounded by a plane, has the dimensions which this plane 
 has ; and has also a third dimension, which we may call 
 height or depth, as we consider the solid extended above 
 or below the plane ; or thickness, if we omit all con- 
 sideration of up and down. And no space can have any 
 dimensions which are not resoluble into these three. 
 
 We may now proceed to consider the mode in which 
 the idea of space is employed in the formation of 
 Geometry. 
 
 CHAPTER IV. 
 
 OF THE DEFINITIONS AND AXIOMS WHICH 
 RELATE TO SPACE. 
 
 1. THE relations of space have been apprehended 
 with peculiar distinctness and clearness from the very 
 first unfolding of man's speculative powers. This was a 
 consequence of the circumstance which we have just 
 noticed, that the simplest of these relations, and those on 
 which the others depend, are seen by intuition. Hence, 
 as soon as men were led to speculate concerning the 
 relations of space, they assumed just principles, and 
 obtained true results. It is said that the science of 
 geometry had its origin in Egypt, before the dawn of the 
 Greek philosophy : but the knowledge of the early 
 Egyptians (exclusive of their mythology) appears to have 
 been purely practical; and, probably, their geometry 
 consisted only in some maxims of land-measuring, which 
 is what the term implies. The Greeks of the time of 
 
92 PHILOSOPHY OF THE PURE SCIENCES. 
 
 Plato, had, however, not only possessed themselves of 
 many of the most remarkable elementary theorems of 
 the science ; but had, in several instances, reached the 
 boundary of the science in its elementary form ; as when 
 they proposed to themselves the problems of doubling 
 the cube and squaring the circle. 
 
 But the deduction of these theorems by a systematic 
 process, and the primary exhibition of the simplest prin- 
 ciples involved in the idea of space, which such a 
 deduction requires, did not take place, so far as we are 
 aware, till a period somewhat later. The Elements of 
 Geometry of Euclid, in which this task was performed, 
 are to this day the standard work on the subject: the 
 author of this work taught mathematics with great 
 applause at Alexandria, in the reign of Ptolemy Lagus, 
 about 280 years before Christ. The principles which 
 Euclid makes the basis of his system have been very 
 little simplified since his time ; and all the essays and 
 controversies which bear upon these principles, have 
 had a reference to the form in which they are stated 
 by him. 
 
 2. Definitions. The first principles of Euclid's geo- 
 metry are, as the first principles of any system of 
 geometry must be, definitions and axioms respecting 
 the various ideal conceptions which he introduces; as 
 straight lines, parallel lines, angles, circles, and the like. 
 But it is to be observed that these definitions and 
 axioms are very far from being arbitrary hypotheses and 
 assumptions. They have their origin in the idea of 
 space, and are merely modes of exhibiting that idea in 
 such a manner as to make it afford grounds of deductive 
 reasoning. The axioms are necessary consequences of 
 the conceptions respecting which they are asserted ; and 
 the definitions are no less necessary limitations of con- 
 ceptions ; not requisite in order to arrive at this or that 
 
DEFINITIONS AND AXIOMS RELATING TO SPACE. 93 
 
 consequence; but necessary in order that it may be 
 possible to draw any consequences, and to establish any 
 general truths. 
 
 For example, if we rest the end of one straight 
 staff upon the middle of another straight staff, and move 
 the first staff into various positions, we, by so doing, 
 alter the angles which the first staff makes with the 
 other to the right hand and to the left. But if we 
 place the staff in that special position in which these 
 two angles are equal, each of them is a right angle, 
 according to Euclid ; and this is the definition of a right 
 angle, except that Euclid employs the abstract con- 
 ception of straight lines, instead of speaking, as we have 
 done, of staves. But this selection of the case in which 
 the two angles are equal is not a mere act of caprice ; 
 as it might have been if he had selected a case in which 
 these angles are unequal in any proportion. For the 
 consequences which can be drawn concerning the cases 
 of unequal angles, do not lead to general truths, without 
 some reference to that peculiar case in which the angles 
 are equal: and thus it becomes necessary to single out 
 and define that special case, marking it by a special 
 phrase. And this definition not only gives complete and 
 distinct knowledge what a right angle is, to any one 
 who can form the conception of an angle in general ; but 
 also supplies a principle from which all the properties of 
 right angles may be deduced. 
 
 3. Axioms. With regard to other conceptions also, 
 as circles, squares, and the like, it is possible to lay 
 down definitions which are a sufficient basis for our 
 reasoning, so far as such figures are concerned. But, 
 besides these definitions, it has been found necessary to 
 introduce certain axioms among the fundamental prin- 
 ciples of geometry. These are of the simplest character ; 
 for instance, that two straight lines cannot cut each 
 
94 PHILOSOPHY OF THE PURE SCIENCES. 
 
 other in more than one point, and an axiom concerning 
 parallel lines. Like the definitions, these axioms flow 
 from the Idea of Space, and present that idea under 
 various aspects. They are different from the definitions ; 
 nor can the definitions be made to take the place of the 
 axioms in the reasoning by which elementary geo- 
 metrical properties are established. For example, the 
 definition of parallel straight lines is, that they are such 
 as, however far continued, can never meet : but, in order 
 to reason concerning such lines, we must further adopt 
 some axiom respecting them : for example, we may very 
 conveniently take this axiom ; that two straight lines 
 which cut one another are not both of them parallel to 
 a third straight line""". The definition and the axiom are 
 seen to be inseparably connected by our intuition of the 
 properties of space ; but the axiom cannot be proved 
 from the definition, by any rigorous deductive demon- 
 stration. And if we were to take any other definition of 
 two parallel straight lines, (as that they are both per- 
 pendicular to a third straight line,) we should still, at 
 some point or other of our progress, fall in with the 
 same difficulty of demonstratively establishing their pro- 
 perties without some further assumption. 
 
 4. Thus the elementary properties of figures, which 
 are the basis of our geometry, are necessary results of 
 our Idea of Space ; and are connected with each other 
 by the nature of that idea, and not merely by our hypo- 
 theses and constructions. Definitions and axioms must 
 be combined, in order to express this idea so far as 
 the purposes of demonstrative reasoning require. These 
 verbal enunciations of the results of the idea cannot be 
 made to depend on each other by logical consequence ; 
 but have a mutual dependence of a more intimate kind, 
 
 * This axiom is simpler and more convenient than that of Euclid. 
 It is employed by the late Professor Playfair in his Geometry. 
 
DEFINITIONS AND AXIOMS RELATING TO SPACE. 95 
 
 which words cannot fully convey. It is not possible to 
 resolve these truths into certain hypotheses, of which all 
 the rest shall be the necessary logical consequence. The 
 necessity is not hypothetical, but intuitive. The axioms 
 require not to be granted, but to be seen. If any one 
 were to assent to them without seeing them to be true, 
 his assent would be of no avail for purposes of reason- 
 ing: for he would be also unable to see in what cases 
 they might be applied. The clear possession of the 
 Idea of Space is the first requisite for all geometrical 
 reasoning ; and this clearness of idea may be tested by 
 examining whether the axioms offer themselves to the 
 mind as evident. 
 
 5. The necessity of ideas added to sensations, in 
 order to produce knowledge, has often been overlooked 
 or denied in modern times. The ground of necessary 
 truth which ideas supply being thus lost, it was con- 
 ceived that there still remained a ground of necessity in 
 definitions; that we might have necessary truths, by 
 asserting especially what the definition implicity involved 
 in general. It was held, also, that this was the case in 
 geometry: that all the properties of a circle, for 
 instance, were implicitly contained in the definition of a 
 circle. That this alone is not the ground of the neces- 
 sity of the truths which regard the circle, that we 
 could not in this way unfold a definition into propor- 
 tions, without possessing an intuition of the relations to 
 which the definition led, has already been shown. But 
 the insufficiency of the above account of the grounds of 
 necessary geometrical truth appeared in another way 
 also. It was found impossible to lay down a system of 
 definitions out of which alone the whole of geometrical 
 
 I truth could be evolved. It was found that axioms could 
 not be superseded. No definition of a straight line 
 could be given which rendered the axiom concerning 
 
96 PHILOSOPHY OF THE PURE SCIENCES. 
 
 straight lines superfluous. And thus it appeared that 
 the source of geometrical truths was not definition 
 alone ; and we find in this result a confirmation of the 
 doctrine which we are here urging, that this source of 
 truth is to be found in the form or conditions of our 
 perception ; in the idea which we unavoidably combine 
 with the impressions of sense ; in the activity, and not 
 in the passivity of the mind*. 
 
 6. This will appear further when we come to con- 
 sider the mode in which we exercise our observation 
 upon the relations of space. But we may, in the first 
 place, make a remark which tends to show the con- 
 nexion between our conception of a straight line, and 
 the axiom which is made the foundation of our reason- 
 ings concerning space. The axiom is this ; that two 
 straight lines, which have both their ends joined, cannot 
 have the intervening parts separated so as to inclose a 
 space. The necessity of this axiom is of exactly the 
 same kind as the necessity of the definition of a right 
 angle, of which we have already spoken. For as the line 
 standing on another makes right angles when it makes 
 the angles on the two sides of it equal ; so a line is a 
 straight line when it makes the two portions of space, 
 on the two sides of it, similar. And as there is only a 
 single position of the line first mentioned, which can 
 make the angles equal, so there is only a single form of 
 a line which can make the spaces near the line similar 
 on one side and on the other : and therefore there can- 
 not be two straight lines, such as the axiom describes, 
 
 * I formerly stated views similar to these in some "Remarks" 
 appended to a work which I termed The Mechanical Euclid, pub- 
 lished in 1837- These Remarks, so far as they bear upon the question 
 here discussed, were noticed and controverted in No. 135 of the Edin- 
 burgh Review. As an examination of the reviewer's objections may 
 serve further to illustrate the subject, I shall annex to this chapter an 
 answer to the article to which I have referred. 
 
DEFINITIONS AND AXIOMS RELATING TO SPACE. 97 
 
 which, between the same limits, give two different 
 boundaries to space thus separated. And thus we see a 
 reason for the axiom. Perhaps this view may be further 
 elucidated if we take a leaf of paper, double it, and 
 crease the folded edge. We shall thus obtain a straight 
 line at the folded edge ; and this line divides the surface 
 of the paper, as it was originally spread out, into two 
 similar spaces. And that these spaces are similar so far 
 as the fold which separates them is concerned, appears 
 from this ; that these two parts coincide when the 
 paper is doubled. And thus a fold in a sheet of paper 
 at the same time illustrates the definition of a straight 
 line according to the above view, and confirms the 
 axiom that two such lines cannot enclose a space. 
 
 If the separation of the two parts of space were made 
 by any other than a straight line ; if, for instance, the 
 paper were cut by a concave line ; then, on turning one 
 of the parts over, it is easy to see that the edge of one 
 part being concave one way, and the edge of the other 
 part concave the other way, these two lines would 
 enclose a space. And each of them would divide the 
 whole space into two portions which were not similar ; 
 for one portion would have a concave edge, and the 
 other a convex edge. Between any two points, there 
 might be innumerable lines drawn, some, convex one 
 way, and some, convex the other way ; but the straight 
 line is the line which is not convex either one way or 
 the other ; it is the single medium standard from which 
 the others may deviate in opposite directions. 
 
 Such considerations as these show sufficiently that 
 the singleness of the straight line which connects any 
 two points is a result of our fundamental conceptions of 
 space. But yet the above conceptions of the similar 
 form of the two parts of space on the two sides of a line, 
 and of the form of a line which is intermediate among 
 
 VOL. i. w. P. H 
 
98 PHILOSOPHY OF THE PURE SCIENCES. 
 
 all other forms, are of so vague a nature, that they can- 
 not fitly be made the basis of our elementary geometry ; 
 and they are far more conveniently replaced, as they 
 have been in almost all treatises of geometry, by the 
 axiom, that two straight lines cannot inclose a space. 
 
 7. But we may remark that, in what precedes, we 
 have considered space only under one of its aspects : as 
 a plane. The sheet of paper which we assumed in order 
 to illustrate the nature of a straight line, was supposed 
 to be perfectly plane orflat: for otherwise, by folding it, 
 we might obtain a line not straight. Now this assump- 
 tion of a plane appears to take for granted that very 
 conception of a straight line which the sheet was em- 
 ployed to illustrate ; for the definition of a plane given 
 in the Elements of Geometry is, that it is a surface on 
 which lie all straight lines drawn from one point of the 
 surface to another. And thus the explanation above 
 given of the nature of a straight line, that it divides a 
 plane space into similar portions on each side, appears 
 to be imperfect or nugatory. 
 
 To this we reply, that the explanation must be ren- 
 dered complete and valid by deriving the conception of 
 a plane from considerations of the same kind as those 
 which we employed for a straight line. Any portion of 
 solid space may be divided into two portions by surfaces 
 passing through any given line or boundaries. And 
 these surfaces may be convex either on one side or on 
 the other, and they admit of innumerable changes from 
 being convex on one side to being convex on the other 
 in any degree. So long as the surface is convex either 
 way, the two portions of space which it separates are not 
 similar, one having a convex and the other a concave 
 boundary. But there is a certain intermediate position of 
 the surface, in which position the two portions of space 
 which it divides have their boundaries exactly similar. 
 
DEFINITIONS AND AXIOMS RELATING TO SPACE. 09 
 
 In this position, the surface is neither convex nor concave, 
 but plane. And thus a plane surface is determined by 
 this condition of its being that single surface which is 
 the intermediate form among all convex and concave 
 surfaces by which solid space can be divided, and of 
 its separating such space into two portions, of whiqh 
 the boundaries, though they are the same surface in 
 two opposite positions, are exactly similar. 
 
 Thus a plane is the simplest and most symmetrical 
 boundary by which a solid can be divided ; and a straight 
 line is the simplest and most symmetrical boundary by 
 which a plane can be separated. These conceptions are 
 obtained by considering the boundaries of an intermin- 
 able space, capable of imaginary division in every direc- 
 tion. And as a limited space may be separated into two 
 parts by a plane, and a plane again separated into two 
 parts by a straight line, so a line is divided into two por- 
 tions by a point, which is the common boundary of the 
 two portions ; the end of the one and the beginning of the 
 other portion having itself no magnitude, form, or parts. 
 
 8. The geometrical properties of planes and solids 
 are deducible from the first principles of the Elements, 
 without any new axioms ; the definition of a plane above 
 quoted, that all straight lines joining its points lie in 
 the plane, being a sufficient basis for all reasoning upon 
 these subjects. And thus, the views which we have pre- 
 sented of the nature of space being verbally expressed 
 by means of certain definitions and axioms, become the 
 groundwork of a long series of deductive reasoning, by 
 which is established a very large and curious collection 
 of truths, namely, the whole science of Elementary 
 Plane and Solid Geometry. 
 
 This science is one of indispensable use and constant 
 reference, for every student of the laws of nature; for the 
 relations of space and number are the alphabet in which 
 
 H 2 
 
100 PHILOSOPHY OF THE PURE SCIENCES. 
 
 those laws are written. But besides the interest and im- 
 portance of this kind which geometry possesses, it has a 
 great and peculiar value for all who wish to understand 
 the foundations of human knowledge, and the methods 
 by which it is acquired. For the student of geometry 
 apquires, with a degree of insight and clearness which 
 the unmathematical reader can but feebly imagine, a 
 conviction that there are necessary truths, many of them 
 of a very complex and striking character; and that a 
 few of the most simple and self-evident truths which it is 
 possible for the mind of man to apprehend, may, by 
 systematic deduction, lead to the most remote and unex- 
 pected results. 
 
 In pursuing such philosophical researches as that 
 in which we are now engaged, it is of great advantage 
 to the speculator to have cultivated to some extent the 
 study of geometry ; since by this study he may become 
 fully aware of such features in human knowledge as 
 those which \ve have mentioned. By the aid of the 
 lesson thus learned from the contemplation of geome- 
 trical truths, we have been endeavouring to establish 
 those further doctrines; that these truths are but dif- 
 ferent aspects of the same Fundamental Idea, and that 
 the grounds of the necessity which these truths possess 
 reside in the Idea from which they flow, this Idea not 
 being a derivative result of experience, but its primary 
 rule. When the reader has obtained a clear and satis- 
 factory view of these doctrines, so far as they are appli- 
 cable to our knowledge concerning space, he has, we may 
 trust, overcome the main difficulty which will occur in 
 following the course of the speculations now presented 
 to him. He is then prepared to go forwards with us ; to 
 see over how wide a field the same doctrines are appli- 
 cable: and how rich and various a harvest of knowledge 
 springs from these seemingly scanty principles. 
 
DEFINITIONS AND AXIOMS RELATING TO SPACE. 101 
 
 But before we quit the subject now under our con- 
 sideration, we shall endeavour to answer some objections 
 which have been made to the views here presented; and 
 shall attempt to illustrate further the active powers which 
 we have ascribed to the mind. 
 
 CHAPTER V. 
 
 OF SOME OBJECTIONS WHICH HAVE BEEN 
 MADE TO THE DOCTRINES STATED 
 IN THE PREVIOUS CHAPTER*. 
 
 THE Edinburgh Review, No. cxxxv., contains a cri- 
 tique on a work termed The Mechanical Euclid, in which 
 opinions were delivered to nearly the same effect as some 
 of those stated in the last chapter, and in Chapter xi. 
 of the First Book. Although I believe that there are no 
 arguments used by the reviewer to which the answers 
 will not suggest themselves in the mind of any one who 
 has read with attention what has been said in the pre- 
 ceding chapters (except, perhaps, one or two remarks 
 which have reference to mechanical ideas), it may serve to 
 
 * In order to render the present chapter more intelligible, it may 
 be proper to state briefly the arguments which gave occasion to the 
 review. After noticing Stewart's assertions, that the certainty of mathe- 
 matical reasoning arises from its depending upon definitions, and that 
 mathematical truth is hypothetical; I urged, that no one has yet 
 been able to construct a system of mathematical truths by the aid of 
 definitions alone ; that a definition would not be admissible or appli- 
 cable except it agreed with a distinct conception in the mind ; that the 
 definitions which we employ in mathematics are not arbitrary or hypo- 
 thetical, but necessary definitions; that if Stewart had taken as his 
 examples of axioms the peculiar geometrical axioms, his assertions 
 would have been obviously erroneous ; and that the real foundation of 
 the truths of mathematics is the Idea of Space, which may be expressed 
 (for purposes of demonstration) partly by definitions and partly by 
 axioms. 
 
102 PHILOSOPHY OF THE PURE SCIENCES. 
 
 illustrate the subject if I reply to the objections directly, 
 taking them as the reviewer has stated them. 
 
 1. I had dissented from Stewart's assertion that 
 mathematical truth is hypothetical, or depends upon arbi- 
 trary definitions ; since we understand by an hypothesis 
 a c supposition, not only which we may make, but may 
 abstain rc*m' 'making, or may replace by a different sup- 
 p.ositio-nv whereas- the definitions and hypotheses of geo- 
 metry " are necessarily such as they are, and cannot be 
 altered or excluded. The reviewer (p. 84), informs us 
 that he understands Stewart, when he speaks of hypo- 
 theses and definitions being the foundation of geometry, 
 to speak of the hypothesis that real objects correspond 
 to our geometrical definitions. " If a crystal be an exact 
 hexahedron, the geometrical properties of the hexahe- 
 dron may be predicated of that crystal." To this I reply, 
 that such hypotheses as this are the grounds of our 
 applications of geometrical truths to real objects, but 
 can in no way be said to be the foundation of the truths 
 themselves; that I do not think that the sense which the 
 reviewer gives was Stewart's meaning; but that if it was, 
 this view of the use of mathematics does not at all affect 
 the question which both he and I proposed to discuss, 
 which was, the ground of mathematical certainty. I may 
 add, that whether a crystal be an exact hexahedron, is 
 a matter of observation and measurement, not of defini- 
 tion. I think the reader can have no difficulty in seeing 
 how little my doctrine is affected by the connexion on 
 which the reviewer thus insists. I have asserted that the 
 proposition which affirms the square on the diagonal of 
 a rectangle to be equal to the squares on two sides, does 
 not rest upon arbitrary hypotheses; the objector answers, 
 that the proposition that the square on the diagonal of 
 this page is equal to the squares on the sides, depends 
 upon the arbitrary hypothesis that the page is a rect- 
 
ANSWER TO OBJECTIONS. 103 
 
 angle. Even if this fact were a matter of arbitrary 
 hypothesis, what could it have to do with the general 
 geometrical proposition? How could a single fact, ob- 
 served or hypothetical, affect a universal and necessary 
 truth, which would be equally true if the fact were false ? 
 If there be nothing arbitrary or hypothetical in geometry 
 till we come to such steps in its application, it is plain 
 that the truths themselves are not hypothetical ; which is 
 the question for us to decide. 
 
 2. The reviewer then (p. 85), considers the doctrine 
 that axioms as well as definitions are the foundations of 
 geometry; and here he strangely narrows and confuses 
 the discussion by making himself the advocate of Stewart, 
 instead of arguing the question itself. I had asserted 
 that some axioms are- necessary as the foundations of 
 mathematical reasoning, in addition to the definitions. 
 If Stewart did not intend to discuss this question, I had 
 no concern with what he had said about axioms. But I 
 had every reason to believe that this was the question 
 which Stewart did intend to discuss. I conceive there is 
 no doubt that he intended to give an opinion upon the 
 grounds of mathematical reasoning in general. For he 
 begins his discussions (Elements, Vol. n., p. 38) by contest- 
 ing Reid's opinion on this subject, which is stated gene- 
 rally; and he refers again to the same subject, asserting 
 in general terms, that the first principles of mathematics 
 are not axioms but definitions. If, then, afterwards, he 
 made his proof narrower than his assertion ; if having 
 declared that no axioms are necessary, he afterwards 
 limited himself to showing that seven out of twelve of 
 Euclid's axioms are barren truisms, it was no concern of 
 mine to contest this assertion, which left my thesis un- 
 touched. I had asserted that the proper geometrical 
 axioms (that two straight lines cannot inclose a spa*ce> 
 and the axiom about parallel lines) are indispensable in 
 
104 PHILOSOPHY OF THE PURE SCIENCES. 
 
 geometry. What account the reviewer gives of these 
 axioms we shall soon see; but if Stewart allowed them to 
 be axioms necessary to geometrical reasoning, he over- 
 turned his own assertion as to the foundations of such 
 reasoning ; and if he said nothing decisive about these 
 axioms, which are the points on which the battle must 
 turn, he left his assertion altogether unproved ; nor was 
 it necessary for me to pursue the war into a barren and 
 unimportant corner, when the metropolis was surrendered. 
 The reviewer's exultation that I have not contested the 
 first seven axioms is an amusing example of the self- 
 complacent zeal of advocacy. 
 
 3. But let us turn to the material point, the proper 
 geometrical axioms. What is the reviewer's account of 
 these? Which side of the alternative does he adopt? 
 Do they depend upon the definitions, and is he prepared 
 to show the dependence ? Or are they superfluous, and 
 can he erect the structure of geometry without their aid? 
 One of these two courses, it would seem, he must take. 
 For we both begin by asserting the excellence of geo- 
 metry as an example of demonstrated truth. It is 
 precisely this attribute which gives an interest to our 
 present inquiry. How, then, does the reviewer explain 
 this excellence on his views ? How does he reckon the 
 foundation courses of the edifice which we agree in con- 
 sidering as a perfect example of intellectual building ? 
 
 I presume I may take, as his answer to this question, 
 his hypothetical statement of what Stewart would have 
 said, (p. 87,) on the supposition that there had been, 
 among the foundations of geometry, self-evident indemon- 
 strable truths : although it is certainly strange that the 
 reviewer should not venture to make up his mind as to 
 the truth or falsehood of this supposition. If there were 
 such truths they would be, he says, " legitimate filiations" 
 of the definitions. They would be involved in the defi- 
 
ANSWER TO OBJECTIONS. 105 
 
 nitions. And again he speaks of the foundation of the 
 geometrical doctrine of parallels as a flaw, and as a 
 truth which requires, but has not received demonstration. 
 And yet again, he tells us that each of these supposed 
 axioms (Euclid's twelfth, for instance), is "merely an 
 indication of the point at which geometry fails to per- 
 form that which it undertakes to perform" (p. 91); and 
 that in reality her truths are not yet demonstrated. The 
 amount of this is, that the geometrical axioms are to be 
 held to be legitimate filiations of the definitions, because 
 though certainly true, they cannot be proved from the 
 definitions ; that they are involved in the definitions, 
 although they cannot be evolved out of them ; and that 
 rather than admit that they have any other origin than 
 the definitions, we are to proclaim that geometry has 
 failed to perform what she undertakes to perform. 
 
 To this I reply that I cannot understand what is 
 meant by "legitimate filiations" of principles, if the phrase 
 not mean consequences of such principles established by 
 rigorous and formal demonstrations ; that the reviewer, 
 if he claims any real signification for his phrase, must 
 substantiate the meaning of it by such a demonstration ; 
 he must establish his " legitimate filiation" by a genea- 
 logical table in a satisfactory form. When this cannot 
 be done, to assert, notwithstanding, that the propositions 
 are involved in the definitions, is a mere begging the 
 question; and to excuse this defect by saying that geo- 
 metry fails to perform what she has promised, is to calum- 
 niate the character of that science which we profess to 
 make our standard, rather than abandon an arbitrary 
 and unproved assertion respecting the real grounds of 
 her excellence. I add, further, that if the doctrine of 
 parallel lines, or any other geometrical doctrine of which 
 we see the truth, with the most perfect insight of its 
 necessity, have not hitherto received demonstration to the 
 
 
106 PHILOSOPHY OF THE PURE SCIENCES. 
 
 satisfaction of any school of reasoners, the defect must 
 arise from their erroneous views of the nature of demon- 
 strations, and the grounds of mathematical certainty. 
 
 4. I conceive, then, that the reviewer has failed alto- 
 gether to disprove the doctrine that the axioms of geo- 
 metry are necessary as a part of the foundations of the 
 science. I had asserted further that these axioms supply 
 what the definitions leave deficient ; and that they, along 
 with definitions, serve to present the idea of space under 
 such aspects that we can reason logically concerning it. 
 To this the reviewer opposes (p. 96) the common opinion 
 that a perfect definition is a complete explanation of a 
 name, and that the test of its perfection is, that we 
 may substitute the definition for the name wherever 
 it occurs. I reply, that my doctrine, that a definition 
 expresses a part, but not the whole, of the essential cha- 
 racters of an idea, is certainly at variance with an opinion 
 sometimes maintained, that a definition merely explains 
 a word, and should explain it so fully that it may always 
 replace it. The error of this common opinion may, I think, 
 be shown from considerations such as these ; that if we 
 undertake to explain one word by several, we may be 
 called upon, on the same ground, to explain each of these 
 several by others, and that in this way we can reach no 
 limit nor resting-place ; that in point of fact, it is not 
 found to lead to clearness, but to obscurity, when in the 
 discussion of general principles, we thus substitute defi- 
 nitions for single terms ; that even if this be done, we 
 cannot reason without conceiving what the terms mean ; 
 and that, in doing this, the relations of our concep- 
 tions, and not the arbitrary equivalence of two forms of 
 expression, are the foundations of our reasoning. 
 
 5. The reviewer conceives that some of the so-called 
 axioms are really definitions. The axiom, that " magni- 
 tudes which coincide with each other, that is, which fill 
 
ANSWER TO OBJECTIONS. 107 
 
 the same space, are equal," is a definition of geometrical 
 equality : the axiom, that " the whole is greater than its 
 part," is a definition of whole and part. But surely there 
 are very serious objections to this view. It would seem 
 more natural to say, if the former axiom is a definition 
 of the word equal, that the latter is a definition of the 
 word greater. And how can one short phrase define two 
 terms ? If I say, " the heat of summer is greater than 
 the heat of winter," does this assertion define anything, 
 though the proposition is perfectly intelligible and dis- 
 tinct? I think, then, that this attempt to reduce these 
 axioms to definitions is quite untenable. 
 
 6. I have stated that a definition can be of no use, 
 except we can conceive the possibility and truth of the 
 property connected with it ; and that if we do conceive 
 this, we may rightly begin our reasonings by stating the 
 property as an axiom ; which Euclid does, in the case of 
 straight lines and of parallels. The reviewer inquires, 
 (p. 92,) whether I am prepared to extend this doctrine to 
 the case of circles, for which the reasoning is usually 
 rested upon the definition ; whether I would replace this 
 definition by an axiom, asserting the possibility of such a 
 circle. To this I might reply, that it is not at all incum- 
 bent upon me to assent to such a change ; for I have all 
 along stated that it is indifferent whether the fundamen- 
 tal properties from which we reason be exhibited as defi- 
 nitions or as axioms, provided their necessity be clearly 
 seen. But I am ready to declare that I think the form 
 of our geometry would be not at all the worse, if, instead 
 of the usual definition of a circle, " that it is a figure 
 contained by one line, which is called the circumference, 
 and which is such, that all straight lines drawn from a 
 certain point within the circumference are equal to one 
 another," we were to substitute an axiom and a defini- 
 tion, as follows : > 
 
108 PHILOSOPHY OF THE PURE SCIENCES. 
 
 Axiom. If a line be drawn so as to be at every point 
 equally distant from a certain point, this line will return 
 into itself, or will be one line including a space. 
 
 Definition. The space is called a circle, the line the 
 circumference, and the point the center. 
 
 And this being done, it would be true, as the reviewer 
 remarks, that geometry cannot stir one step without 
 resting on an axiom. And I do not at all hesitate to say, 
 that the above axiom, expressed or understood, is no less 
 necessary than the definition, and is tacitly assumed in 
 every proposition into which circles enter. 
 
 7. I have, I think, now disposed of the principal 
 objections which bear upon the proper axioms of geo- 
 metry. The principles which are stated as the first seven 
 axioms of Euclid's Elements, need not, as I have said, be 
 here discussed. They are principles which refer, not to 
 Space in particular, but to Quantity in general : such ? 
 for instance, as these ; " If equals be added to equals the 
 wholes are equal ;" " If equals be taken from equals 
 the remainders are equal." But I will make an obser- 
 vation or two upon them before I proceed. 
 
 Both Locke and Stewart have spoken of these axioms 
 as barren truisms : as propositions from which it is not 
 possible to deduce a single inference : and the reviewer 
 asserts that they are not first principles, but laws of 
 thought, (p. 88.) To this last expression I am willing 
 to assent ; but I would add, that not only these, but all 
 the principles which express the fundamental conditions 
 of our knowledge, may with equal propriety be termed 
 laws of thought ; for these principles depend upon our 
 ideas, and regulate the active operations of the mind, by 
 which coherence and connexion are given to its passive 
 impressions. But the assertion that no conclusions can 
 be drawn from simple axioms, or laws of human thought, 
 which regard quantity, is by no means true. The whole. 
 
ANSWER TO OBJECTIONS. 109 
 
 of arithmetic, for instance, the rules for the multiplica- 
 tion and division of large numbers, for finding a common 
 measure, and, in short, a vast body of theory respecting 
 numbers, rests upon no other foundation than such 
 axioms as have been just noticed, that if equals be added 
 to equals the wholes will be equal. And even when 
 Locke's assertion, that from these axioms no truths can 
 be deduced, is modified by Stewart and the reviewer, 
 and limited to geometrical truths, it is hardly tenable 
 (although, in fact, it matters little to our argument 
 whether it is or no). For the greater part of the Seventh 
 Book of Euclid's Elements, (on Commensurable and In- 
 commensurable Quantities,) and the Fifth Book, (on 
 Proportion,) depend upon these axioms, with the addi- 
 tion only of the definition or axiom (for it may be stated 
 either way) which expresses the idea of proportionality 
 in numbers. So that the attempt to disprove the neces- 
 sity and use of axioms, as principles of reasoning, fails 
 even when we take those instances which the opponents 
 consider as the more manifestly favourable to their 
 doctrine. 
 
 8. But perhaps the question may have already sug- 
 gested itself to the reader's mind, of what use can it be 
 formally to state such principles as these, (for example, 
 that if equals be added to equals the wholes are equal,) 
 since, whether stated or no, they will be assumed in our 
 reasoning? And how can such principles be said to be 
 necessary, when our proof proceeds equally well without 
 any reference to them? And the answer is, that it is 
 precisely because these are the common principles of 
 reasoning, which we naturally employ without specially 
 contemplating them, that they require to be separated 
 from the other steps and formally stated, when we 
 analyze the demonstrations which we have obtained 
 In every mental process many principles are combined 
 
110 PHILOSOPHY OF THE PURE SCIENCES. 
 
 and abbreviated, and thus in some measure concealed 
 and obscured. In analyzing these processes, the combi- 
 nation must be resolved, and the abbreviation expanded, 
 and thus the appearance is presented of a pedantic and 
 superfluous formality. But that which is superfluous for 
 proof, is necessary for the analysis of proof. In order to 
 exhibit the conditions of demonstration distinctly, they 
 must be exhibited formally. In the same manner, in 
 demonstration we do not usually express every step in 
 the form of a syllogism, but we see the grounds of the 
 conclusiveness of a demonstration, by resolving it into 
 syllogisms. Neither axioms nor syllogisms are necessary 
 for conviction; but they are necessary to display the 
 conditions under which conviction becomes inevitable. 
 The application of a single one of the axioms just spoken 
 of is so minute a step in the proof, that it appears pe- 
 dantic to give it a marked place ; but the very essence 
 of demonstration consists in this, that it is composed of 
 an indissoluble succession of such minute steps. The 
 admirable circumstance is, that by the accumulation of 
 such apparently imperceptible advances, we can in the 
 end make so vast and so sure a progress. The com- 
 pleteness of the analysis of our knowledge appears in the 
 smallness of the elements into which it is thus resolved. 
 The minuteness of any of these elements of truth, of 
 axioms for instance, does not prevent their being as 
 essential as others which are more obvious. And any 
 attempt to assume one kind of element only, when the 
 course of our analysis brings before us two or more 
 kinds, is altogether unphilosophical. Axioms and defi- 
 nitions are the proximate constituent principles of our 
 demonstrations; and the intimate bond which connects 
 together a definition and an axiom on the same subject 
 is not truly expressed by asserting the latter to be de- 
 rived from the former. This bond of connexion exists 
 
OF THE PERCEPTION OF SPACE. Ill 
 
 in the mind of the reasoner, in his conception of that to 
 which both definition and axiom refer, and consequently 
 in the general Fundamental Idea of which that concep- 
 tion is a modification. 
 
 CHAPTER VI. 
 OF THE PERCEPTION OF SPACE. 
 
 1. ACCORDING to the views above explained, certain 
 of the impressions of our senses convey to us the per- 
 ception of objects as existing in space; inasmuch as by 
 the constitution of our minds we cannot receive those 
 impressions otherwise than in a certain form, involving 
 such a manner of existence. But the question deserves 
 to be asked, What are the impressions of sense by which 
 we thus become acquainted with space and its relations ? 
 And as we have seen that this idea of space implies an 
 act of the mind as well as an impression on the sense, 
 what manifestations do we find of this activity of the 
 mind, in our observation of the external world ? 
 
 It is evident that sight and touch are the senses by 
 which the relations of space are perceived, principally or 
 entirely. It does not appear that an odour, or a feeling 
 of warmth or cold, would, independently of experience, 
 suggest to us the conception of a space surrounding us. 
 But when we see objects, we see that they are extended 
 and occupy space; when we touch them, we feel that 
 they are in a space in which we also are. We have 
 before our eyes any object, for instance, a board covered 
 with geometrical diagrams; and we distinctly perceive, 
 by vision, those lines of which the relations are the 
 subjects of our mathematical reasoning. Again, we see 
 before us a solid object, a cubical box for instance ; we 
 see that it is within reach ; we stretch out the hand and 
 
112 PHILOSOPHY OE THE PURE SCIENCES. 
 
 perceive by the touch that it has sides, edges, corners, 
 which we had already perceived by vision. 
 
 2. Probably most persons do not generally appre- 
 hend that there is any material difference in these two 
 cases ; that there are any different acts of mind con- 
 cerned in perceiving by sight a mathematical diagram 
 upon paper, and a solid cube lying on a table. Yet it is 
 not difficult to show that, in the latter case at least, the 
 perception of the shape of the object is not immediate. 
 A very little attention teaches us that there is an act of 
 judgment as well as a mere impression of sense requisite, 
 in order that we may see any solid object. For there is 
 no visible appearance which is inseparably connected 
 with solidity. If a picture of a cube be rightly drawn in 
 perspective and skilfully shaded, the impression upon the 
 sense is the same as if it were a real cube. The picture 
 may be mistaken for a solid object. But it is clear that, 
 in this case, the solidity is given to the object by an act 
 of mental judgment. All that is seen is outline and 
 shade, figures and colours on a flat board. The solid 
 angles and edges, the relation of the faces of the figure 
 by which they form a cube, are matters of inference. 
 This, which is evident in the case of the pictured cube, is 
 true in all vision whatever. We see a scene before us 
 on which are various figures and colours, but the eye 
 cannot see more. It sees length and breadth, but no 
 third dimension. In order to know that there are solids, 
 we must infer as well as see. And this we do readily 
 and constantly; so familiarly, indeed, that we do not 
 perceive the operation. Yet we may detect this latent 
 process in many ways; for instance, by attending to 
 cases in which the habit of drawing such inferences mis- 
 leads us. Most persons have experienced this delusion 
 in looking at a scene in a theatre, and especially that 
 kind of scene which is called a diorama, when the 
 
OF THE PERCEPTION OF SPACE. 113 
 
 interior of a building is represented. In these cases, 
 the perspective representations of the various members 
 of the architecture and decoration impress us almost 
 irresistibly with the conviction that we have before us a 
 space of great extent and complex form, instead of a flat 
 painted canvass. Here, at least, the space is our own 
 creation, but yet here, it is manifestly created by the 
 same act of thought as if we were really in the palace or 
 the cathedral of which the halls and aisles thus seem to 
 inclose us. And the act by which we thus create space 
 of three dimensions out of visible extent of length and 
 breadth, is constantly and imperceptibly going on. We 
 are perpetually interpreting in this manner the language 
 of the visible world. From the appearances of things 
 which we directly see, we are constantly inferring that 
 which we cannot directly see, their distance from us, 
 and the position of their parts. 
 
 3. The characters which we thus interpret are 
 various. They are, for instance, the visible forms, 
 colours, and shades of the parts, understood according 
 to the maxims of perspective ; (for of perspective every 
 one has a practical knowledge, as every one has of 
 grammar ;) the effort by which we fix both our eyes on 
 the same object, and adjust each eye to distinct vision ; 
 and the like. The right interpretation of the informa- 
 tion which such circumstances give us respecting the 
 true forms and distances of things, is gradually learned ; 
 the lesson being begun in our earliest infancy, and 
 inculcated upon us every hour during which we use our 
 eyes. The completeness with which the lesson is mas- 
 tered is truly admirable; for we forget that our con- 
 clusion is obtained indirectly, and mistake a judgment 
 on evidence for an intuitive perception. We see the 
 breadth of the street, as clearly and readily as we see 
 the house on the other side of it ; and we see the house 
 VOL. i. w. P. I 
 
114 PHILOSOPHY OF THE PURE SCIENCES. 
 
 to be square, however obliquely it be presented to us. 
 This, however, by no means throws any doubt or diffi- 
 culty on the doctrine that in all these cases we do inter- 
 pret and infer. The rapidity of the process, and the 
 unconsciousness of the effort, are not more remarkable 
 in this case than they are when we understand the 
 meaning of the speech which we hear, or of the book 
 which we read. In these latter cases we merely hear 
 noises or see black marks ; but we make, out of these 
 elements, thought and feeling, without being aware of 
 the act by which we do so. And by an exactly similar 
 process we see a variously-coloured expanse, and collect 
 from it a space occupied by solid objects. In both 
 cases the act of interpretation is become so habitual 
 that we can hardly stop short at the mere impression 
 of sense. 
 
 4. But yet there are various ways in which we may 
 satisfy ourselves that these two parts of the process of 
 seeing objects are distinct. To separate these operations 
 is precisely the task which the artist has to execute in 
 making a drawing of what he sees. He has to recover 
 the consciousness of his real and genuine sensations, and 
 to discern the lines of objects as they appear. This at 
 first he finds difficult; for he is tempted to draw what 
 he knows of the forms of visible objects, and not what 
 he sees : but as he improves in his art, he learns to put 
 on paper what he sees only, separated from what he 
 infers, in order that thus the inference, and with it a 
 conception like that of the reality, may be left to the 
 spectator. And thus the natural process of vision is the 
 habit of seeing that which cannot be seen ; and the diffi- 
 culty of the art of drawing consists in learning not to 
 see more than is visible. 
 
 5. But again ; even in the simplest drawing we 
 exhibit something which we do not see. However 
 
OF THE PERCEPTION OF SPACE. 115 
 
 slight is our representation of objects, it contains some- 
 thing which we create for ourselves. For we draw an 
 outline. Now an outline has no existence in nature. 
 There are no visible lines presented to the eye by a 
 group of figures. We separate each figure from the rest, 
 and the boundary by which we do this is the outline of 
 the figure ; and the like may be said of each member of 
 every figure. A painter of our own times has made this 
 remark in a work upon his art*. "The effect which 
 natural objects produce upon our sense of vision is that 
 of a number of parts, or distinct masses of form and 
 colour, and not of lines. But when we endeavour to 
 represent by painting the objects which are before us, or 
 which invention supplies to our minds, the first and the 
 simplest means we resort to is this picture, by which we 
 separate the form of each object from those that sur- 
 round it, marking its boundary, the extreme extent of 
 its dimensions in every direction, as impressed on our 
 vision : and this is termed drawing its outline." 
 
 6. Again, there are other ways in which we see clear 
 manifestations of the act of thought by which we assign 
 to the parts of objects their relations in space, the im- 
 pressions of sense being merely subservient to this act. 
 If we look at a medal through a glass which inverts it, 
 we see the figures upon it become concave depressions 
 instead of projecting convexities; for the light which 
 illuminates the nearer side of the convexity will be trans- 
 ferred to the opposite side by the apparent inversion of 
 the medal, and will thus imply a hollow in which the 
 side nearest the light gathers the shade. Here our deci- 
 sion as to which part is nearest to us, has reference to 
 the side from which the light comes. In other cases 
 the decision is more spontaneous. If we draw black 
 outlines, such as represent the edges of a cube seen 
 
 * Phillips On Painting. 
 
 12 
 
116 PHILOSOPHY OF THE PURE SCIENCES. 
 
 in perspective, certain of the lines will cross each other ; 
 and we may make this cube appear to assume two dif- 
 ferent positions, by determining in our own mind that 
 the lines which belong to one end of the cube shall be 
 understood to be before or to be behind those which 
 they cross. Here an act of the will, operating upon the 
 same sensible image, gives us two cubes, occupying two 
 entirely different positions. Again, many persons may 
 have observed that when a windmill in motion at a dis- 
 tance from us, (so that the outline of the sails only is 
 seen,) stands obliquely to the eye, we may, by an effort 
 of thought, make the obliquity assume one or the other 
 of two positions ; and as we do this, the sails, which in 
 one instance appear to turn from right to left, in the other 
 case turn from left to right. A person a little familiar 
 with this mental effort, can invert the motion as often as 
 he pleases, so long as the conditions of form and light 
 do not offer a manifest contradiction to either position. 
 
 Thus we have these abundant and various manifesta- 
 tions of the activity of the mind, in the process by which 
 we collect from vision the relations of solid space of three 
 dimensions. But we must further make some remarks 
 on the process by which we perceive mere visible figure; 
 and also, on the mode in which we perceive the relations 
 of space by the touch ; and first, of the latter subject. 
 
 7. The opinion above illustrated, that our sight does 
 not give us a direct knowledge of the relations of solid 
 space, and that this knowledge is acquired only by an 
 inference of the mind, was first clearly taught by the 
 celebrated Bishop Berkeley"", and is a doctrine now 
 generally assented to by metaphysical speculators. 
 
 But does the sense of touch give us directly a know- 
 ledge of space ? This is a question which has attracted 
 considerable notice in recent times; and new light has 
 
 * Theory of Vision. 
 
OF THE PERCEPTION OF SPACE. 117 
 
 been thrown upon it in a degree which is very remark- 
 able, when we consider that the philosophy of perception 
 has been a prominent subject of inquiry from the earliest 
 times. Two philosophers, advancing to this inquiry from 
 different sides, the one a metaphysician, the other a phy- 
 siologist, have independently arrived at the conviction 
 that the long current opinion, according to which we 
 acquire a knowledge of space by the sense of touch, is 
 erroneous. And the doctrine which they teach instead 
 of the ancient errour, has a very important bearing upon 
 the principle which we are endeavouring to establish, 
 that our knowledge of space and its properties is derived 
 rather from the active operations than from the passive 
 impressions of the percipient mind. 
 
 Undoubtedly the persuasion that we acquire a know- 
 ledge of form by the touch is very obviously suggested 
 by our common habits. If we wish to know the form of 
 any body in the dark, or to correct the impressions con- 
 veyed by sight, when we suspect them to be false, we 
 have only, it seems to us, at least at first, to stretch forth 
 the hand and touch the object ; and we learn its shape 
 with no chance of error. In these cases, form appears 
 to be as immediate a perception of the sense of touch, 
 as colour is of the sense of sight. 
 
 8. But is this perception really the result of the 
 passive sense of touch merely ? Against such an opinion 
 Dr. Brown, the metaphysician of whom I speak, urges* 
 that the feeling of touch alone, when any object is ap- 
 plied to the hand, or any other part of the body, can no 
 more convey the conception of form or extension, than 
 the sensation of an odour or a taste can do, except we 
 have already some knowledge of the relative position of 
 the parts of our bodies; that is, except we are already in 
 possession of an idea of space, and have, in our minds, 
 * Lectures, Vol. i. p. 459, (1824). 
 
118 PHILOSOPHY OF THE PURE SCIENCES. 
 
 referred our limbs to their positions; which is to sup- 
 pose the conception of form already acquired. 
 
 9. By what faculty then do we originally acquire our 
 conceptions of the relations of position ? Brown answers 
 by the muscular sense; that is, by the conscious exer- 
 tions of the various muscles by which we move our limbs. 
 When we feel out the form and position of bodies by 
 the hand, our knowledge is acquired, not by the mere 
 touch of the body, but by perceiving the course the 
 fingers must take in order to follow the surface of the 
 body, or to pass from one body to another. We are 
 conscious of the slightest of the volitions by which we 
 thus feel out form and place ; we know whether we move 
 the finger to the right or left, up or down, to us or from 
 us, through a large or a small space ; and all these con- 
 scious acts are bound together and regulated in our 
 minds by an idea of an extended space in which they are 
 performed. That this idea of space is not borrowed from 
 the sight, and transferred to the muscular feelings by 
 habit, is evident. For a man born blind can feel out his 
 way with his staff, and has his conceptions of position 
 determined by the conditions of space, no less than one 
 who has the use of his eyes. And the muscular con- 
 sciousness which reveals to us the position of objects and 
 parts of objects, when we feel them out by means of the 
 hand, shews itself in a thousand other ways, and in all 
 our limbs: for our habits of standing, walking, and all 
 other attitudes and motions, are regulated by our feeling 
 of our position and that of surrounding objects. And 
 thus, we cannot touch any object without learning some- 
 thing respecting its position ; not that the sense of 
 touch directly conveys such knowledge ; but we have 
 already learnt, from the muscular sense, constantly 
 exercised, the position of the limb which the object thus 
 touches. 
 
OF THE PERCEPTION OF SPACE. 119 
 
 10. The justice of this distinction will, I think, be 
 assented to by all persons who attend steadily to the 
 process itself, and might be maintained by many forcible 
 reasons. Perhaps one of the most striking evidences in 
 its favour is that, as I have already intimated, it is the 
 opinion to which another distinguished philosopher, Sir 
 Charles Bell, has been led, reasoning entirely upon phy- 
 siological principles. From his researches it resulted 
 that besides the nerves which convey the impulse of the 
 will from the brain to the muscle, by which every motion 
 of our limbs is produced, there is another set of nerves 
 which carry back to the brain $ sense of the condition 
 of the muscle, and thus regulate its activity ; and give us 
 the consciousness of our position and relation to sur- 
 rounding objects. The motion of the hand and fingers, 
 or the consciousness of this motion, must be combined 
 with the sense of touch properly so called, in order to 
 make an inlet to the knowledge of such relations. This 
 consciousness of muscular exertion, which he has called a 
 sixth sense 4 '", is our guide, Sir C. Bell shows, in the com- 
 mon practical government of our motions ; and he states 
 that having given this explanation of perception as a 
 physiological doctrine, he had afterwards with satisfac- 
 tion seen it confirmed by Dr. Brown's speculations. 
 
 11. Thus it appears that our consciousness of the 
 relations of space is inseparably and fundamentally con- 
 nected with our own actions in space. We perceive only 
 while we act ; our sensations require to be interpreted by 
 our volitions. The apprehension of extension and figure 
 is far from being a process in which we are inert and 
 passive. We draw lines with our fingers ; we construct 
 surfaces by curving our hands ; we generate spaces by the 
 motion of our arms. When the geometer bids us form 
 lines, or surfaces, or solids by motion, he intends his 
 
 * Bridgewater Treatise, p. 195. Phil. Trans. 1826, Pt. n., p. 167- 
 
120 PHILOSOPHY OF THE PURE SCIENCES. 
 
 injunction to be taken as hypothetical only ; we need only 
 conceive such motions. But yet this hypothesis repre- 
 sents truly the origin of our knowledge ; we perceive 
 spaces by motion at first, as we conceive spaces by motion 
 afterwards : or if not always by actual motion, at least 
 by potential. If we perceive the length of a staif by 
 holding its two ends in our two hands without running 
 the finger along it, this is because by habitual motion we 
 have already acquired a measure of the distance of our 
 hands in any attitude of which we are conscious. Even 
 in the simplest case, our perceptions are derived not from 
 the touch, but from the sixth sense ; and this sixth sense 
 at least, whatever may be the case with the other five, 
 implies an active mind along with the passive sense. 
 
 12. Upon attentive consideration, it will be clear 
 that a large portion of the perceptions respecting space 
 which appear at first to be obtained by sight alone, are, 
 in fact, acquired by means of this sixth sense. Thus we 
 consider the visible sky as a single surface surrounding 
 us and returning into itself, and thus forming a hemi- 
 sphere. But such a mode of conceiving an object of vision 
 could never have occurred to us, if we had not been able 
 to turn our heads, to follow this surface, to pursue it till 
 we find it returning into itself. And when we have done 
 this, we necessarily present it to ourselves as a concave 
 inclosure within which we are. The sense of sight alone, 
 without the power of muscular motion, could not have 
 led us to view the sky as a vault or hemisphere. Under 
 such circumstances, we should have perceived only what 
 was presented to the eye in one position ; and if dif- 
 ferent appearances had been presented in succession, we 
 could not have connected them as parts of the same 
 picture, for want of any perception of their relative posi- 
 tion. They would have been so many detached and 
 incoherent visual sensations. The muscular sense con- 
 
OF THE PERCEPTION OF SPACE. 121 
 
 nects their parts into a whole, making them to be only 
 different portions of one universal scene *. 
 
 13. These considerations point out the fallacy of a 
 very curious representation made by Dr. Reid, of the 
 convictions to which man would be led, if he possessed 
 vision without the sense of touch. To illustrate this sub- 
 ject, Reid uses the fiction of a nation whom he terms the 
 Idomenians, who have no sense except that of sight. He 
 describes their notions of the relations of space as being 
 entirely different from ours. The axioms of their geome- 
 try are quite contradictory to our axioms. For example, 
 it is held to be self-evident among them that two straight 
 lines which intersect each other once, must intersect a 
 second time ; that the three angles of any triangle are 
 greater than two right angles; and the like. These 
 paradoxes are obtained by tracing the relations of lines 
 on the surface of a concave sphere, which surrounds the 
 spectator, and on which all visible appearances may be 
 supposed to be presented to him. But from what is said 
 above it appears that the notion of such a sphere, and 
 such a connexion of visible objects which are seen in dif- 
 ferent directions, cannot be arrived at by sight alone. 
 
 * It has been objected to this view, that we might obtain a con- 
 ception of the sky as a hemisphere, by being ourselves turned round, (as 
 on a music-stool, for instance,) and thus seeing in succession all parts of 
 the sky. But this assertion I conceive to be erroneous. By being thus 
 turned round, we should see a number of pictures which we should put 
 together as parts of a plane picture ; and when we came round to the 
 original point, we should have no possible means of deciding that it 
 was the same point : it would appear only as a repetition of the pic- 
 ture. That sight, of itself, can give us only a plane picture, the doctrine 
 of Berkeley, appears to be indisputable ; and, no less so, the doctrine 
 that it is the consciousness of our own action in space which puts toge- 
 ther these pictures so that they cover the surface of a solid body. We 
 can see length and breadth with our eyes, but we must thrust out our 
 arm towards the flat surface, in order that we may, in our thoughts, 
 combine a third dimension with the other two. 
 
122 PHILOSOPHY OF THE PURE SCIENCES. 
 
 When the spectator combines in his conception the rela- 
 tions of long-drawn lines and large figures, as he sees 
 them by turning his head to the right and to the left, 
 upwards and downwards, he ceases to be an Idomenian. 
 And thus our conceptions of the properties of space, de- 
 rived through the exercise of one mode of perception, 
 are not at variance with those obtained in another way ; 
 but all such conceptions, however produced or suggested, 
 are in harmony with each other; being, as has already 
 been said, only different aspects of the same idea. 
 
 14. If our perceptions of the position of objects 
 around us do not depend on the sense of vision alone, 
 but on the muscular feeling brought into play when we 
 turn our head, it will obviously follow that the same is 
 true when we turn the eye instead of the head. And 
 thus we may learn the form of objects, not by looking 
 at them with a fixed gaze, but by following the boundary 
 of them with the eye. While the head is held perfectly 
 still, the eye can rove along the outlines of visible ob- 
 jects, scrutinize each point in succession, and leap from 
 one point to another ; each such act being accompanied 
 by a muscular consciousness which makes us aware of 
 the direction in which the look is travelling. And we 
 may thus gather information concerning the figures and 
 places which we trace out with the visual ray, as the 
 blind man learns the forms of things which he traces out 
 with his staff, being conscious of the motions of his hand. 
 
 15. This view of the mode in which the eye per- 
 ceives position, which is thus supported by the analogy 
 of other members employed for the same purpose, is 
 further confirmed by Sir Charles Bell by physiological 
 reasons. He teaches us that* when an object is seen we 
 employ two senses: there is an impression on the retina; 
 but we receive also the idea of position or relation in 
 
 * Phil. Trans., 1823. On the Motions of the Eye. 
 
OF THE PERCEPTION OF SPACE. 123 
 
 space, which it is not the office of the retina to give, by 
 our consciousness of the efforts of the voluntary muscles 
 of the eye : and he has traced in detail the course of the 
 nerves by which these muscles convey their information. 
 The constant searching motion of the eye, as he terms 
 it*, is the means by which we become aware of the 
 position of objects about us. 
 
 16. It is not to our present purpose to follow the 
 physiology of this subject ; but we may notice that Sir 
 C. Bell has examined the special circumstances which 
 belong to this operation of the eye. We learn from him 
 that the particular point of the eye which thus traces the 
 forms of visible objects is a part of the retina which has 
 been termed the sensible spot ; being that part which is 
 most distinctly sensible to the impressions of light and 
 colour. This part, indeed, is not a spot of definite size and 
 form, for it appears that proceeding from a certain point 
 of the retina, the distinct sensibility diminishes on every 
 side by degrees. And the searching motion of the eye 
 arises from the desire which we instinctively feel of re- 
 ceiving upon the sensible spot the image of the object 
 to which the attention is directed. We are uneasy and 
 
 * Bridgewater Treatise, p. 282. I have adopted, in writing the 
 above, the views and expressions of Sir Charles Bell. The essential 
 part of the doctrine there presented is, that the eye constantly makes 
 efforts to turn, so that the image of an object to which our attention is 
 drawn, shall fall upon a certain particular point of the retina ; and that 
 when the image falls upon any other point, the eye turns away from 
 this oblique into the direct position. Other writers have maintained 
 that the eye thus turns, not because the point on which the image falls 
 in direct vision is the most sensible point, but that it is the point of 
 greatest distinctness of vision. They urge that a small star, which dis- 
 appears when the eye is turned full upon it, may often be seen by 
 looking a little away from it : and hence, they infer that the parts of 
 the retina removed from the spot of direct vision, are more sensible than 
 it is. The facts are very curious, however they be explained, but they 
 do not disturb the doctrine delivered in the text. 
 
124 PHILOSOPHY OF THE PURE SCIENCES. 
 
 impatient till the eye is turned so that this is effected. 
 And as our attention is transferred from point to point 
 of the scene before us, the eye, and this point of the eye 
 in particular, travel along with the thoughts ; and the 
 muscular sense, which tells us of these movements of 
 the organ of vision, conveys to us a knowledge of the 
 forms and places which we thus successively survey. 
 
 17. How much of activity there is in the process by 
 which we perceive the outlines of objects appears further 
 from the language by which we describe their forms. 
 We apply to them not merely adjectives of form, but 
 verbs of motion. An abrupt hill starts out of the plain ; 
 a beautiful figure has a gliding outline. We have 
 
 The windy summit, wild and high, 
 Roughly rushing on the sky. 
 
 These terms express the course of the eye as it follows 
 the lines by which such forms are bounded and marked. 
 In like manner another modern poet* says of Soracte, 
 that it 
 
 From out the plain 
 
 Heaves like a long-swept wave about to break, 
 And on the curl hangs pausing. 
 
 Thus the muscular sense, which is, inseparably con- 
 nected with an act originating in our own mind, not only 
 gives us all that portion of our perceptions of space in 
 which we use the sense of touch, but also, at least in a 
 great measure, another large portion of such perceptions, 
 in which we employ the sense of sight. As we have 
 before seen that our knowledge of solid space and its 
 properties is not conceivable in any other way than as 
 the result of a mental act, governed by conditions depend- 
 ing on its own nature ; so it now appears that our per- 
 ceptions of visible figure are not obtained without an act 
 performed under the same conditions. The sensations 
 of touch and sight are subordinated to an idea which is 
 * Byron, Ck. Har. vi., st 75. 
 
OF THE PERCEPTION OF SPACE. 125 
 
 the basis of our speculative knowledge concerning space 
 and its relations ; and this same idea is disclosed to our 
 consciousness by its practically regulating our inter- 
 course with the external world. 
 
 By considerations such as have been adduced and 
 referred to, it is proved beyond doubt, that in a great 
 number of cases our knowledge of form and position is 
 acquired from the muscular sense, and not from sight 
 directly : for instance, in all cases in which we have 
 before us objects so large and prospects so extensive 
 that we cannot see the whole of them in one position of 
 the eye*. 
 
 We now quit the consideration of the properties of 
 Space, and consider the Idea of Time. 
 
 CHAPTER VII. 
 OF THE IDEA OF TIME. 
 
 1. RESPECTING the Idea of Time, we may make 
 several of the same remarks which we made concerning 
 
 ' f The expression in the first edition was " large objects and exten- 
 sive spaces." In the text as now given, I state a definite size and 
 extent, within which the sight by itself can judge of position and figure. 
 
 The doctrine that we require the assistance of the muscular sense to 
 enable us to perceive space of three dimensions, is not at all inconsistent 
 with this other doctrine, that within the space which is seen by the 
 fixed eye, we perceive the relative positions of points directly by vision, 
 and that, consequently, we have a perception of visible t figure. 
 
 Sir Charles Bell has said, (Phil Trans. 1823, p. 181,) "It appears 
 to me that the utmost ingenuity will be at a loss to devise an explana- 
 tion of that power by which the eye becomes acquainted with the 
 position and relation of objects, if the sense of muscular activity be 
 excluded which accompanies the motion of the eyeball." But surely we 
 should have no difficulty in perceiving the relation of the sides and 
 angles of a small triangle, placed before the eye, even if the muscles of 
 the eyeball were severed. This subject is resumed B. iv. c. ii. sect. 11. 
 
126 PHILOSOPHY OF THE PURE SCIENCES. 
 
 the .idea of space, in order to shew that it is not bor- 
 rowed from experience, but is a bond of connexion 
 among the impressions of sense, derived from a peculiar 
 activity of the mind, and forming a foundation both of 
 our experience and of our speculative knowledge. 
 
 Time is not a notion obtained by experience. Expe- 
 rience, that is, the impressions of sense and our con- 
 sciousness of our thoughts, gives us various percep- 
 tions; and different successive perceptions considered 
 together exemplify the notion of change. But this very 
 connexion of different perceptions, this successiveness, 
 presupposes that the perceptions exist in time. That 
 things happen either together, or one after the other, is 
 intelligible only by assuming time as the condition under 
 which they are presented to us. 
 
 Thus time is a necessary condition in the presentation 
 of all occurrences to our minds. We cannot conceive 
 this condition to be taken away. We can conceive 
 time to go on while nothing happens in it ; but we can- 
 not conceive anything to happen while time does not 
 go on. 
 
 It is clear from this that time is not an impression 
 derived from experience, in the same manner in which 
 we derive from experience our information concerning 
 the objects which exist, and the occurrences which take 
 place in time. The objects of experience can easily be 
 conceived to be, or not to be : to be absent as well as 
 present. Time always is, and always is present, and 
 even in our thoughts we cannot form the contrary sup- 
 position. 
 
 2. Thus time is something distinct from the matter 
 or substance of our experience, and may be considered 
 as a necessary form which that matter (the experience of 
 change) must assume, in order to be an object of con- 
 templation to the mind. Time is one of the necessary 
 
OF THE IDEA OF TIME. 127 
 
 conditions under which we apprehend the information 
 which our senses and consciousness give us. By con- 
 sidering time as a form which belongs to our power of 
 apprehending occurrences and changes, and under which 
 alone all such experience can be accepted by the mind, 
 we explain the necessity, which we find to exist, of con- 
 ceiving all such changes as happening in time ; and we 
 thus see that time is not a property perceived as existing 
 in objects, or as conveyed to us by our senses ; but a con- 
 dition impressed upon our knowledge by the constitution 
 of the mind itself; involving an act of thought as well as 
 an impression of sense. 
 
 3. We showed that space is an idea of the mind, or 
 form of our perceiving power, independent of experience, 
 by pointing out that we possess necessary and universal 
 truths concerning the relations of space, which could 
 never be given by means of experience ; but of which 
 the necessity is readily conceivable, if we suppose them 
 to have for their basis the constitution of the mind. 
 There exist also respecting number, many truths abso- 
 lutely necessary, entirely independent of experience and 
 anterior to it ; and so far as the conception of number 
 depends upon the idea of time, the same argument might 
 be used to show that the idea of time is not derived from 
 experience, but is a result of the native activity of the 
 mind : but we shall defer all views of this kind till we 
 come to the consideration of Number. 
 
 4. Some persons have supposed that we obtain the 
 notion of time from the perception of motion. But it 
 is clear that the perception of motion, that is, change of 
 place, presupposes the conception of time, and is not 
 capable of being presented to the mind in any other way. 
 If we contemplate the same body as being in different 
 places at different times, and connect these observations, 
 we have the conception of motion, which thus presup- 
 
128 PHILOSOPHY OF THE PURE SCIENCES. 
 
 poses the necessary conditions that existence in time 
 implies. And thus we see that it is possible there should 
 be necessary truths concerning all motion, and conse- 
 quently, concerning those motions which are the objects 
 of experience ; but that the source of this necessity is the 
 Ideas of time and space, which, being universal conditions 
 of knowledge residing in the mind, afford a foundation 
 for necessary truths. 
 
 CHAPTER VIII. 
 OF SOME PECULIARITIES OF THE IDEA OF TIME. 
 
 1. THE Idea of Time, like the Idea of Space, offers to 
 our notice some characters which do not belong to our 
 fundamental ideas generally, but which are deserving of 
 remark. These characters are, in some respects, closely 
 similar with regard to time and to space, while, in other 
 respects, the peculiarities of these two ideas are widely 
 different. We shall point out some of these characters. 
 
 Time is not a general abstract notion collected from 
 experience; as, for example, a certain general concep- 
 tion of the relations of things. For we do not consider 
 particular times as examples of Time in general, (as we 
 consider particular causes to be examples of Cause,) but 
 we conceive all particular times to be parts of a single 
 and endless Time. This continually -flowing and endless 
 time is what offers itself to us when we contemplate any 
 series of occurrences. All actual and possible times 
 exist as Parts, in this original and general Time. And 
 since all particular times are considered as derivable 
 from time in general, it is manifest that the notion of 
 time in general cannot be derived from the notions of 
 particular times. The notion of time in general is there- 
 
SOME PECULIARITIES OF THE IDEA OF TIME. 129 
 
 fore not a general conception gathered from experi- 
 ence. 
 
 2. Time is infinite. Since all actual and possible 
 times exist in the general course of time, this general 
 time must be infinite. All limitation merely divides, 
 and does not terminate, the extent of absolute time. 
 Time has no beginning and no end; but the beginning 
 and the end of every other existence takes place in it. 
 
 3. Time, like space, is not only a form of perception, 
 but of intuition. We contemplate events as taking 
 place in time. We consider its parts as added to one 
 another, and events as filling a larger or smaller extent 
 of such parts. The time which any event takes up is 
 the sum of all such parts, and the relation of the same 
 to time is fully understood when we can clearly see what 
 portions of time it occupies, and what it does not. 
 Thus the relation of known occurrences to time is 
 perceived by intuition ; and time is a form of intuition 
 of the external world. 
 
 4. Time is conceived as a quantity of one dimension ; 
 it has great analogy with a line, but none at all with a 
 surface or solid. Time may be considered as consisting 
 of a series of instants, which are before and after one 
 another ; and they have no other relation than this, of 
 before and after. Just the same would be the case with 
 a series of points taken along a line ; each would be 
 after those on one side of it, and before those on another. 
 Indeed the analogy between time, and space of one 
 dimension, is so close, that the same terms are applied to 
 both ideas, and we hardly know to which they originally 
 belong. Times and lines are alike called long and short ; 
 we speak of the beginning and end of a line ; of a point 
 
 tf time, and of the limits of a portion of duration. 
 5. But, as has been said, there is nothing in time 
 hich corresponds to more than one dimension in space, 
 VOL. i. w. p. K 
 
130 PHILOSOPHY OF THE PURE SCIENCES. 
 
 and hence nothing which has any obvious analogy with 
 figure. Time resembles a line indefinitely extended both 
 ways ; all partial times are portions of this line ; and no 
 mode of conceiving time suggests to us a line making 
 any angle with the original line, or any other combina- 
 tion which might give rise to figures of any kind. The 
 analogy between time and space, which in many circum- 
 stances is so clear, here disappears altogether. Spaces 
 of two and of three dimensions, planes and solids, have 
 nothing to which we can compare them in the concep- 
 tions arising out of time. 
 
 6. As figure is a conception solely appropriate to 
 space, there is also a conception which peculiarly belongs 
 to time, namely, the conception of recurrence of times 
 similarly marked; or, as it may be termed, rhythm, 
 using this word in a general sense. The term rhythm 
 is most commonly 'used to designate the recurrence of 
 times marked by the syllables of a verse, or the notes of 
 a melody : but it is easy to see that the general concep- 
 tion of such a recurrence does not depend on the mode 
 in which it is impressed upon the sense. The forms of 
 such recurrence are innumerable. Thus in such a line as 
 
 Quadrupedante putrem sonitu quatit lingula camptim, 
 
 we have alternately one long or forcible syllable, and 
 two short or light ones, recurring over and over. In 
 like manner in our own language, in the line 
 
 At the close of the day when the hamlet is still, 
 
 we have two light and one strong syllable repeated four 
 times over. Such repetition is the essence of versification. 
 The same kind of rhythm is one of the main elements of 
 music, with this difference only, that in music the forcible 
 syllables are made so for the purposes of rhythm by 
 their length only or principally ; for example, if either of 
 the above lines were imitated by a melody in the most 
 
SOME PECULIARITIES OF THE IDEA OF TIME. 131 
 
 simple and obvious manner, each strong syllable would 
 occupy exactly twice as much time as two of the weaker 
 ones. Something very analogous to such rhythm may 
 be traced in other parts of poetry and art, which we need 
 not here dwell upon. But in reference to our present 
 subject, we may remark that by the introduction of such 
 rhythm, the flow of time, which appears otherwise so 
 perfectly simple and homogeneous, admits of an infinite 
 number of varied yet regular modes of progress. All 
 the kinds of versification which occur in all languages, 
 and the still more varied forms of recurrence of notes of 
 different lengths, which are heard in all the varied strains 
 of melodies, are only examples of such modifications, or 
 configurations as we may call them, of time. They in- 
 volve relations of various portions of time, as figures 
 involve relations of various portions of space. But yet 
 the analogy between rhythm and figure is by no means 
 very close ; for in rhythm we have relations of quantity 
 alone in the parts of time, whereas in figure we have re- 
 lations not only of quantity, but of a kind altogether 
 different, namely, of position. On the other hand, a 
 repetition of similar elements, which does not necessarily 
 occur in figures, is quite essential in order to impress 
 upon us that measured progress of time of which we here 
 speak. And thus the ideas of time and space have each 
 its peculiar and exclusive relations ; position and figure 
 belonging only to space, while repetition and rhythm are 
 appropriate to time. 
 
 7. One of the simplest forms of recurrence is alter- 
 nation, as when we have alternate strong and slight syl- 
 lables. For instance, 
 
 Awake, arise, or be for ever fall'ri. 
 
 Or without any subordination, as when we reckon 
 numbers, and call them in succession, odd, even, odd, 
 even. 
 
 K 2 
 
132 PHILOSOPHY OF THE PURE SCIENCES. 
 
 8. But the simplest of all forms of recurrence is that 
 which has no variety ; in which a series of units, each 
 considered as exactly similar to the rest, succeed each 
 other; as one, one, one, and so on. In this case, how- 
 ever, we are led to consider each unit with reference to 
 all that have preceded ; and thus the series one, one, one, 
 and so forth, becomes one, two, three, four, five, and so 
 on ; a series with which all are familiar, and which may 
 be continued without limit. 
 
 We thus collect from that repetition of which time 
 admits, the conception of Number. 
 
 9. The relations of position and figure are the sub- 
 ject of the science of geometry ; and are, as we have 
 already said, traced into a very remarkable and extensive 
 body of truths, which rests for its foundations on axioms 
 involved in the Idea of Space. There is, in like manner, 
 a science of great complexity and extent, which has its 
 foundation in the Idea of Time. But this science, as it 
 is usually pursued, applies only to the conception of Num- 
 ber, which is, as we have said, the simplest result of 
 repetition. This science is Theoretical Arithmetic, or 
 the speculative doctrine of the properties and relations 
 of numbers ; and we must say a few words concerning 
 the principles which it is requisite to assume as the basis 
 of this science. 
 
 CHAPTER IX. 
 OF THE AXIOMS WHICH RELATE TO NUMBER. 
 
 1. THE foundations of our speculative knowledge of 
 the relations and properties of Number, as well as of 
 Space, are contained in the mode in which we represent to 
 ourselves the magnitudes which are the subjects of our 
 reasonings. To express these foundations in axioms in the 
 
OF THE AXIOMS WHICH RELATE TO NUMBER. 133 
 
 case of number, is a matter requiring some consideration, 
 for the same reason as in the case of geometry ; that is, 
 because these axioms are principles which we assume as 
 true, without being aware that we have made any assump- 
 tion ; and we cannot, without careful scrutiny, determine 
 when we have stated, in the form of axioms, all that is 
 necessary for the formation of the science, and no more 
 than is necessary. We will, however, attempt to detect 
 the principles which really must form the basis of theo- 
 retical arithmetic. 
 
 2. Why is it that three and two are equal to four and 
 one ? Because if we look at five things of any kind, we 
 see that it is so. The five are four and one ; they, are 
 also three and two. The truth of our assertion is in- 
 volved in our being able to conceive the number five at 
 all. We perceive this truth by intuition, for we cannot 
 see, or imagine we see, five things, without perceiving 
 also that the assertion above stated is true. 
 
 But how do we state in words this fundamental prin- 
 ciple of the doctrine of numbers ? Let us consider a 
 very simple case. If we wish to show that seven and 
 two are equal to four and five, we say that seven are four 
 and three, therefore seven and two are four and three 
 and two ; and because three and two are five, this is four 
 and five. Mathematical reasoners justify the first infer- 
 ence (marked by the conjunctive word therefore], by 
 saying that "When equals are added to equals the 
 wholes are equal," and that thus, since seven is equal 
 to three and four, if we add two to both, seven and two 
 are equal to four and three and two. 
 
 3. Such axioms as this, that when equals are added 
 equals the wholes are equal, are, in fact, expressions 
 
 f the general condition of intuition, by which a whole 
 is contemplated as made up of parts, and as identical 
 with the aggregate of the parts. And a yet more gene- 
 
134 PHILOSOPHY OF THE PURE SCIENCES. 
 
 ral form in which we might more adequately express 
 this conditon of intuition would be this ; that " Two mag- 
 nitudes are equal when they can be divided into parts 
 which are equal, each to each." Thus in the above ex- 
 ample, seven and two are equal to four and five, because 
 each of the two sums can be divided into the parts, four, 
 three, and two. 
 
 4. In all these cases, a person who had never seen 
 such axioms enunciated in a verbal form would employ 
 the same reasoning as a practised mathematician, in order 
 to satisfy himself that the proposition was true. The 
 steps of the reasoning, being seen to be true by intuition, 
 would carry an entire conviction, whether or not the 
 argument were made verbally complete. Hence the 
 axioms may appear superfluous, and on this account 
 such axioms have often been spoken contemptuously of 
 as empty and barren assertions. In fact, however, al- 
 though they cannot supply the deficiency of the clear in- 
 tuition of number and space in the reasoner himself, and 
 although when he possesses such a faculty, he will reason 
 rightly if he have never heard of such axioms, they still 
 have their place properly at the beginning of our trea- 
 tises on the science of quantity ; since they express, as 
 simply as words can express, those conditions of the 
 intuition of magnitudes on which all reasoning concern- 
 ing quantity must be based ; and are necessary when we 
 want, not only to see the truth of the elementary reason- 
 ings on these subjects, but to put such reasonings in a 
 formal and logical shape. 
 
 5. We have considered the above-mentioned axioms 
 as the basis of all arithmetical operations of the nature 
 of addition. But it is easily seen that the same prin- 
 ciple may be carried into other cases ; as for instance, 
 multiplication, which is merely a repeated addition, 
 and admits of the same kind of evidence. Thus 
 
OF THE AXIOMS WHICH RELATE TO NUMBER. 135 
 
 five times three are equal to three times five ; why 
 is this ? If we arrange fifteen things in five rows of 
 three, it is seen by looking, or by imaginary looking, 
 which is intuition, that they may also be taken as three 
 rows of five. And thus the principle that those wholes 
 are equal which can be resolved into the same partial 
 magnitudes, is immediately applicable in this as in the 
 other case. 
 
 6. We may proceed to higher numbers, and may find 
 ourselves obliged to use artificial nomenclature and 
 notation in order to represent and reckon them ; but the 
 reasoning in these cases also is still the same. And the 
 usual artifice by which our reasoning in such instances 
 is assisted is, that the number which is the root of our 
 scale of notation (which is ten in our usual system), is 
 alternately separated into parts and treated as a single 
 thing. Thus 47 and 35 are 82 ; for 47 is four tens and 
 seven ; 35 is three tens and five ; whence 47 and 35 are 
 seven tens and twelve ; that is, 7 tens, 1 ten, and 2 ; 
 which is 8 tens and 2, or 82. The like reasoning is 
 applicable in other cases. And since the most remote 
 and complex properties of numbers are obtained by a 
 prolongation of a course of reasoning exactly similar to 
 that by which we thus establish the most elementary 
 propositions, we have, in the principles just noticed, the 
 foundation of the whole of Theoretical Arithmetic. 
 
 
 CHAPTER X. 
 OF THE PERCEPTION OF TIME AND NUMBER. 
 
 1. OUR perception of the passage of time involves a 
 series of acts of memory. This is easily seen and assented 
 to, when large intervals of time and a complex train of 
 occurrences are concerned. But since memory is requi- 
 
136 PHILOSOPHY OF THE PURE SCIENCES. 
 
 site in order to apprehend time in such cases, we cannot 
 doubt that the same faculty must be concerned in the 
 shortest and simplest cases of succession ; for it will 
 hardly be maintained that the process by which we con- 
 template the progress of time is different when small 
 and when large intervals are concerned. If memory be 
 absolutely requisite to connect two events which begin 
 and end a day, and to perceive a tract of time between 
 them, it must be equally indispensable to connect the 
 beginning and end of a minute, or a second ; though in 
 this case the effort may be smaller, and consequently 
 more easily overlooked. In common cases, we are un- 
 conscious of the act of thought by which we recollect 
 the preceding instant, though we perceive the effort when 
 we recollect some distant event. And this is analogous 
 to what happens in other instances. Thus, we walk 
 without being conscious of the volitions by which we 
 move our muscles ; but, in order to leap, a distinct and 
 manifest exertion of the same muscles is necessary. Yet 
 no one will doubt that we walk as well as leap by an 
 act of the will exerted through the muscles ; and in like 
 manner, our consciousness of small as well as large inter- 
 vals of time involves something of the nature of an act 
 of memory. 
 
 2. But this constant and almost imperceptible kind 
 of memory, by which we connect the beginning and end 
 of each instant as it passes, may very fitly be distinguished 
 in common cases from manifest acts of recollection, 
 although it may be difficult or impossible to separate 
 the two operations in general. This perpetual and latent 
 kind of memory may be termed a sense of successive- 
 ness ; and must be considered as an internal sense by 
 which we perceive ourselves existing in time, much in 
 the same way as by our external and muscular sense 
 we perceive ourselves existing in space. And both our 
 
PERCEPTION OF TIME AND NUMBER. 137 
 
 internal thoughts and feelings, and the events which 
 take place around us, are apprehended as objects of this 
 internal sense, and thus as taking place in time. 
 
 3. In the same manner in which our interpretation 
 of the notices of the muscular sense implies the power of 
 moving our limbs, and of touching at will this object or 
 that ; our apprehension of the relations of time by means 
 of the internal sense of successiveness implies a power of 
 recalling what has past, and of retaining what is pass- 
 ing. We are able to seize the occurrences which have 
 just taken place, and to hold them fast in our minds 
 so as mentally to measure their distance in time from 
 occurrences now present. And thus, this, sense of suc- 
 cessiveness, like the muscular sense with which we have 
 compared it, implies activity of the mind itself, and is 
 not a sense passively receiving impressions. 
 
 4. The conception of Number appears to require the 
 exercise of the same sense of succession. At first sight, 
 indeed, we seem to apprehend Number without any act 
 of memory, or any reference to time : for example, we 
 look at a horse, and see that his legs are four ; and this 
 we seem to do at once, without reckoning them. But it 
 is not difficult to see that this seeming instantaneousness 
 of the perception of small numbers is an illusion. This 
 resembles the many other cases in which we perform 
 short and easy acts so rapidly and familiarly that we are 
 unconscious of them; as in the acts of seeing, and of arti- 
 culating our words. And this is the more manifest, since 
 we begin our acquaintance with number by counting 
 even the smallest numbers. Children and very rude 
 savages must use an effort to reckon even their five 
 fingers, and find a difficulty in going further. And per- 
 sons have been known who were able by habit, or by a 
 peculiar natural aptitude, to count by dozens as rapidly 
 as common persons can by units. We may conclude, 
 
138 PHILOSOPHY OF THE PURE SCIENCES. 
 
 therefore, that when we appear to catch a small number 
 by a single glance of the eye, we do in fact count the 
 units of it in a regular, though very brief succession. To 
 count requires an act of memory. Of this we are sen- 
 sible when we count very slowly, as when we reckon the 
 strokes of a church-clock ; for in such a case we may 
 forget in the intervals of the strokes, and miscount. Now 
 it will not be doubted that the nature of the process in 
 counting is the same whether we count fast or slow. 
 There is no definite speed of reckoning at which the 
 faculties which it requires are changed; and therefore 
 memory, which is requisite in some cases, must be so 
 in all*.' 
 
 The act of counting, (one, two, three, and so on,) is 
 the foundation of all our knowledge of number. The 
 intuition of the relations of number involves this act of 
 counting; for, as we have just seen, the conception of 
 number cannot be obtained in any other way. And thus 
 the whole of theoretical arithmetic depends upon an act 
 of the mind, and upon the conditions which the exercise 
 of that act implies. These have been already explained 
 in the last chapter. 
 
 5. But if the apprehension of number be accompanied 
 by an act of the mind, the apprehension of rhythm is so 
 still more clearly. All the forms of versification and the 
 measures of melodies are the creations of man, who thus 
 realizes in words and sounds the forms of recurrence 
 which rise within his own mind. When we hear in a 
 
 * I have considered Number as involving the exercise of the sense 
 of succession, because I cannot draw any line between those cases of 
 large numbers, in which, the process of counting being performed, there 
 is a manifest apprehension of succession ; and those cases of small num- 
 bers, in which we seem to see the number at one glance. But if any 
 one holds Number to be apprehended by a direct act of intuition, as 
 Space and Time are, this view will not disturb the other doctrines 
 delivered in the text, 
 
 
PERCEPTION OF TIME AND NUMBER. 139 
 
 quiet scene any rapidly-repeated sound, as those made by 
 the hammer of the smith or the saw of the carpenter, 
 every one knows how insensibly we throw these noises 
 into a rhythmical form in our own apprehension. We 
 do this even without any suggestion from the sounds 
 themselves. For instance, if the beats of a clock or 
 watch be ever so exactly alike, we still reckon them 
 alternately tick-tack, tick-tack. That this is the case, 
 may be proved by taking a watch or clock of such a con- 
 struction that the returning swing of the pendulum is 
 silent, and in which therefore all the beats are rigorously 
 alike : we shall find ourselves still reckoning its sounds 
 as tick-tack. In this instance it is manifest that the 
 rhythm is entirely of our own making. In melodies, 
 also, and in verses in which the rhythm is complex, ob- 
 scure, and difficult, we perceive something is required 
 on our part ; for we are often incapable of contributing 
 our share, and thus lose the sense of the measure alto- 
 gether. And when we consider such cases, and attend 
 to what passes within us when we catch the measure, 
 even of the simplest and best-known air, we shall no 
 longer doubt that an act of our own thoughts is requisite 
 in such cases, as well as impressions on the sense. And 
 thus the conception of this peculiar modification of time, 
 which we have called rhythm, like all the other views 
 which we have taken of the subject, shows that we must, 
 in order to form such conceptions, supply a certain idea 
 by our own thoughts, as well as merely receive by senses, 
 whether external or internal, the impressions of appear- 
 ances and collections of appearances. 
 
 NOTE TO CHAPTER X. 
 
 I HAVE in the last ten chapters described Space, Time, and Number by 
 various expressions, all intended to point out their office as exemplifying 
 the Ideal Element of human knowledge. I have called them Fttnda- 
 
140 PHILOSOPHY OF THE PURE SCIENCES. 
 
 mental Ideas ; Forms of Perception ; Forms of Intuition ; and per- 
 haps other names. I might add yet other phrases. I might say that 
 the properties of Space, Time, and Number are Laws of the Mind's 
 Activity in apprehending what is. For the mind cannot apprehend any 
 thing or event except conformably to the properties of space, time, and 
 number. It is not only that it does not, but it can not : and this 
 impossibility shows that the law is a law of the mind, and not of 
 objects extraneous to the mind. 
 
 It is usual for some of those who reject the doctrines here presented 
 to say that the axioms of geometry, and of other sciences, are obtained 
 by Induction from facts constantly presented by experience. But I do 
 not see how Induction can prove that a proposition must be true. The 
 only intelligible usage of the word Induction appears to me to be, that in 
 which it is applied to a proposition which, being separable from the 
 facts in our apprehension, and being compared with them, is seen to 
 agree with them. But in the cases now spoken of, the proposition is 
 not separable from the facts. We cannot infer by induction that two 
 straight lines cannot inclose a space, because we cannot contemplate 
 special cases of two lines inclosing a space, in which it remains to be 
 determined whether or not the proposition, that both are straight, 
 is true. 
 
 I do not deny that the activity of the mind by which it perceives 
 objects and events as related according to the laws of space, time, and 
 number, is awakened and developed by being constantly exercised; and 
 that we cannot imagine a stage of human existence in which the powers 
 have not been awakened and developed by such exercise. In this way, 
 experience and observation are necessary conditions and prerequisites of 
 our apprehension of geometrical (and other) axioms. We cannot see 
 the truth of these axioms without some experience, because we cannot 
 see any thing, or be human beings, without some experience. This 
 might be expressed by saying that such truths are acquired necessarily 
 in the course of all experience ; but I think it is very undesirable to 
 apply, to such a case, the word Induction, of which it is so important 
 to us to keep the scientific meaning free from confusion. Induction 
 cannot give demonstrative proofs, as I have already stated in Book i. 
 C. ii. sect. 3, and therefore cannot be the ground of necessary truths. 
 
 Another expression which may be used to describe the Funda- 
 mental Ideas here spoken of is suggested by the language of a very 
 profound and acute Review of the former edition. The Reviewer holds 
 that we pass from special experiences to universal truths in virtue of 
 " the inductive propensity the irresistible impulse of the mind to 
 generalize ad injinitum." I have already given reasons why I cannot 
 adopt the former expression ; but I do not see why space, time, number, 
 
PERCEPTION OF TIME AND NUMBER. 
 
 141 
 
 cause, and the rest, may not be termed different forms of the impulse of 
 the mind to generalize. If we put together all the Fundamental Ideas 
 as results of the Generalizing Impulse, we must still separate them as 
 different modes of action of that Impulse, showing themselves in various 
 characteristic ways in the axioms and modes of reasoning which belong 
 to different sciences. The Generalizing Impulse in one case proceeds 
 according to the Idea of Space ; in another, according to the Idea of 
 Mechanical Cause ; and so in other subjects. 
 
 CHAPTER XL 
 OF MATHEMATICAL REASONING. 
 
 1. Discursive Reasoning. WE have thus seen that 
 our notions of space, time, and their modifications, neces- 
 sarily involve a certain activity of the mind; and that 
 the conditions of this activity form the foundations of 
 those sciences which have the relations of space, time, 
 and number, for their object. Upon the fundamental 
 principles thus established, the various sciences which 
 are included in the term Pure Mathematics, (Geometry, 
 Algebra, Trigonometry, Conic Sections, and the rest of 
 the Higher Geometry, the Differential Calculus, and the 
 like,) are built up by a series of reasonings. These rea- 
 sonings are subject to the rules of Logic, as we have 
 already remarked ; nor is it necessary here to dwell long- 
 on the nature and rules of such processes. But we may 
 here notice that such processes are termed discursive, 
 in opposition to the operations by which we acquire our 
 fundamental principles, which are, as we have seen, intui- 
 tive. This opposition was formerly very familiar to our 
 writers ; as Milton, 
 
 Thus the soul reason receives, 
 Discursive or intuitive. Paradise Lost, v. 438. 
 
 For in such reasonings we obtain our conclusions, not 
 by looking at our conceptions steadily in one view, which 
 
142 PHILOSOPPIY OF THE PURE SCIENCES. 
 
 is intuition, but by passing from one view to another, like 
 those who run from place to place (discursus). Thus a 
 straight line may be at the same time a side of a triangle 
 and a radius of a circle : and in the first proposition of 
 Euclid a line is considered, first in one of these relations, 
 and then in the other, and thus the sides of a certain 
 triangle are proved to be equal. And by this " discourse 
 of reason," as by our older writers it was termed, we set 
 forth from those axioms which we perceive by intuition, 
 travel securely over a vast and varied region, and become 
 possessed of a copious store of mathematical truths. 
 
 2. Technical Terms of Reasoning. The reasoning of 
 mathematics, thus proceeding from a few simple princi- 
 ples to many truths, is conducted according to the rules 
 of Logic. If it be necessary, mathematical proofs may be 
 reduced to logical forms, and expressed in Syllogisms, 
 consisting of major, minor, and conclusion. But in most 
 cases the syllogism is of that kind which is called by 
 logical writers an Enthymeme; a word which implies 
 something existing in the thoughts only, and which desig- 
 nates a syllogism in which one of the premises is under- 
 stood, and not expressed. Thus we say in a mathematical 
 proof, " because the point c is the center of the circle AB, 
 AC is equal to BC ;" not stating the major, that all lines 
 drawn from the center of a circle to the circumference 
 are equal; or introducing it only by a transient reference 
 to the definition of a circle. But the enthymeme is so 
 constantly used in all habitual forms of reasoning, that 
 it does not occur to us as being anything peculiar in 
 mathematical works. 
 
 The propositions which are proved to be generally 
 true are termed Theorems: but when anything is required 
 to be done, as to draw a line or a circle under given 
 conditions, this proposition is a Problem. A theorem re- 
 quires demonstration ; a problem, solution. And for both 
 
OF MATHEMATICAL REASONING. 143 
 
 purposes the mathematician usually makes a Construc- 
 tion. He directs us to draw certain lines, circles, or other 
 curves, on which is to be founded his demonstration that 
 his theorem is true, or that his problem is solved. Some- 
 times, too, he establishes some Lemma, or preparatory 
 proposition, before he proceeds to his main task ; and 
 often he deduces from his demonstration some conclusion 
 in addition to that which was the professed object of his 
 proposition ; and this is termed a Corollary. 
 
 These technical terms are noted here, not as being 
 very important, but in order that they may not sound 
 strange and unintelligible if we should have occasion to 
 use some of them. There is, however, one technical dis- 
 tinction more peculiar, and more important. 
 
 3. Geometrical Analysis and Synthesis. In geome- 
 trical reasoning such as we have described, we introduce 
 at every step some new consideration ; and it is by com- 
 bining all these considerations, that we arrive at the 
 conclusion, that is, the demonstration of the proposition. 
 Each step tends to the final result, by exhibiting some 
 part of the figure under a new relation. To what we 
 have already proved, is added something more; and hence 
 this process is called Synthesis, or putting together. The 
 proof flows on, receiving at every turn new contribu- 
 tions from different quarters ; like a river fed and aug- 
 mented by many tributary streams. And each of these 
 tributaries flows from some definition or axiom as its 
 fountain, or is itself formed by the union of smaller rivulets 
 which have sources of this kind. In descending along its 
 course, the synthetical proof gathers all these accessions 
 into one common trunk, the proposition finally proved. 
 
 But we may proceed in a different manner. We 
 may begin from the formed river, and ascend to its 
 sources. We may take the proposition of which we 
 require a proof, and may examine what the supposition 
 
144 PHILOSOPHY OF THE PURE SCIENCES. 
 
 of its truth implies. If this be true, then something else 
 may be seen to be true ; and from this, something else, 
 and so on. We may often, in this way, discover of what 
 simpler propositions our theorem or solution is com- 
 pounded, and may resolve these in succession, till we 
 come to some proposition which is obvious. This is geo- 
 metrical Analysis. Having succeeded in this analytical 
 process, we may invert it ; and may descend again from 
 the simple and known propositions, to the proof of a 
 theorem, or the solution of a problem, which was our 
 starting-place. 
 
 This process resembles, as we have said, tracing a 
 river to its sources. As we ascend the stream, we per- 
 petually meet with bifurcations; and some sagacity is 
 needed to enable us to see which, in each case, is the 
 main stream : but if we proceed in our research, we 
 exhaust the unexplored valleys, and finally obtain a clear 
 knowledge of the place whence the waters flow. Analy- 
 tical is sometimes confounded with symbolical reasoning, 
 on which subject we shall make a remark in the next 
 chapter. The object of that chapter is to notice certain 
 other fundamental principles and ideas, not included in 
 those hitherto spoken of, which we find thrown in our 
 way as we proceed in our mathematical speculations. 
 It would detain us too long, and involve us in subtle and 
 technical disquisitions, to examine fully the grounds of 
 these principles ; but the Mathematics hold so important 
 a place in relation to the inductive sciences, that I shall 
 briefly notice the leading ideas which the ulterior pro- 
 gress of the subject involves. 
 

 145 
 
 CHAPTER XII. 
 
 OF THE FOUNDATIONS OF THE HIGHER 
 MATHEMATICS. 
 
 1 . The Idea of a Limit. THE general truths concern- 
 ing relations of spa.ce which depend upon the axioms 
 and definitions contained in Euclid's Elements, and which 
 involve only properties of straight lines and circles, are 
 termed Elementary Geometry : all beyond this belongs to 
 the Higher Geometry. To this latter province appertain, 
 for example, all propositions respecting the lengths of any 
 portions of curve lines ; for these cannot be obtained by 
 means of the principles of the Elements alone. Here 
 then we must ask to what other principles the geometer 
 has recourse, and from what source these are drawn, Is 
 there any origin of geometrical truth which we have not 
 yet explored ? 
 
 The Idea of a Limit supplies a new mode of establish- 
 ing mathematical truths. Thus with regard to the length 
 of any portion of a curve, a problem which we have just 
 mentioned ; a curve is not made up of straight lines, and 
 therefore we cannot by means of any of the doctrines of 
 elementary geometry measure the length of any curve. 
 But we may make up a figure nearly resembling any 
 curve by putting together many short straight lines, just 
 as a polygonal building of very many sides may nearly 
 resemble a circular room. And in order to approach 
 nearer and nearer to the curve, we may make the sides 
 more and more small, more and more numerous. We 
 may then possibly find some mode of measurement, some 
 relation of these small lines to other lines, which is not 
 disturbed by the multiplication of the sides, however far 
 it be carried. And thus, we may do what is equivalent to 
 
 VOL. i. w. r. L 
 
146 PHILOSOPHY OF THE PURE SCIENCES. 
 
 measuring the curve itself; for by multiplying the sides 
 we may approach more and more closely to the curve till 
 no appreciable difference remains. The curve line is the 
 Limit of the polygon ; and in this process we proceed on 
 the Axiom, that "What is true up to the limit is true at 
 the limit." 
 
 This mode of conceiving mathematical magnitudes is 
 of wide extent and use ; for every curve may be con- 
 sidered as the limit of some polygon; every varied 
 magnitude, as the limit of some aggregate of simpler 
 forms ; and thus the relations of the elementary figures 
 enable us to advance to the properties of the most com- 
 plex cases. 
 
 A Limit is a peculiar and fundamental conception, the 
 use of which in proving the propositions of the Higher 
 Geometry cannot be superseded by any combination of 
 other hypotheses and definitions*. The axiom just no- 
 ticed, that what is true up to the limit is true at the limit, 
 is involved in the very conception of a limit : and this 
 principle, with its consequences, leads to all the results 
 which form the subject of the higher mathematics, whe- 
 
 * This assertion cannot be fully proved and illustrated without a 
 reference to mathematical reasonings which would not be generally 
 intelligible. I have shown the truth of the assertion in my Thoughts 
 on the Study of Mathematics, annexed to the Principles of English 
 University Education. The proof is of this kind: The ultimate 
 equality of an arc of a curve and the corresponding periphery of a 
 polygon, when the sides of the polygon are indefinitely increased in 
 number, is evident. But this truth cannot be proved from any other 
 axiom. For if we take the supposed axiom, that a curve is always 
 less than the including broken line, this is not true, except with a con- 
 dition ; and in tracing the import of this condition, we find its neces- 
 sity becomes evident only when we introduce a reference to a Limit. 
 And the same is the case if we attempt to supersede the notion of a 
 Limit in proving any other simple and evident proposition in which 
 that notion is involved. Therefore these evident truths are *e//levident, 
 in virtue of the Idea of a Limit, 
 
THE FOUNDATIONS OF THE HIGHER MATHEMATICS. 147 
 
 ther proved by the consideration of evanescent triangles, 
 by the processes of the Differential Calculus, or in any 
 other way. 
 
 The ancients did not expressly introduce this con- 
 ception of a Limit into their mathematical reasonings ; 
 although in the application of what is termed the 
 Method of Exhaustions, (in which they show how to 
 exhaust the difference between a polygon and a curve, or 
 the like,) they were in fact proceeding upon an obscure 
 apprehension of principles equivalent to those of the 
 Method of Limits. Yet the necessary fundamental prin- 
 ciple not having, in their time, been clearly developed, 
 their reasonings were both needlessly intricate and im^ 
 perfectly satisfactory. Moreover they were led to put in 
 the place of axioms, assumptions which were by no means 
 self-evident ; as when Archimedes assumed, for the basis 
 of his measure of the circumference of the circle, the 
 proposition that a circular arch is necessarily less than 
 two lines which inclose it, joining its extremities. The 
 reasonings of the older mathematicians, which professed 
 to proceed upon such assumptions, led to true results 
 in reality, only because they were guided by a latent 
 reference to the limiting case of such assumptions. And 
 this latent employment of the conception of a Limit, 
 reappeared in various forms during the early period of 
 modern mathematics ; as for example, in the Method of 
 Indivisibles of Cavalleri, and the Characteristic Triangle 
 of Barrow ; till at last, Newton distinctly referred such 
 reasonings to the conception of a Limit, and established 
 the fundamental principles and processes which that 
 conception introduces, with a distinctness and exactness 
 which required little improvement to make it as unim- 
 peachable as the demonstrations of geometry. And when 
 such processes as Newton thus deduced from the con- 
 ception of a Limit are represented by means of general 
 
 L2 
 
148 PHILOSOPHY OF THE PURE SCIENCES. 
 
 algebraical symbols instead of geometrical diagrams, we 
 have then before us the Method of Fluocions, or the 
 Differential Calculus; a mode of treating mathematical 
 problems justly considered as the principal weapon by 
 which the splendid triumphs of modern mathematics 
 have been achieved. 
 
 2. The Use of General Symbols. The employment 
 of algebraical symbols, of which we have just spoken, 
 has been another of the main instruments to which the 
 successes of modern mathematics are owing. And here 
 again the processes by which we obtain our results de- 
 pend for their evidence upon a fundamental conception, 
 the conception of arbitrary symbols as the Signs of 
 quantity and its relations; and upon a corresponding 
 axiom, that " The interpretation of such symbols must 
 be perfectly general." In this case, as in the last, it was 
 only by degrees that mathematicians were led to a just 
 apprehension of the grounds of their reasoning. For 
 symbols were at first used only to represent numbers 
 considered with regard to their numerical properties; 
 and thus the science of Algebra was formed. But it was 
 found, even in cases belonging to common algebra, that 
 the symbols often admitted of an interpretation which 
 went beyond the limits of the problem, and which yet was 
 not unmeaning, since it pointed out a question closely 
 analogous to the question proposed. This was the case, 
 for example, when the answer was a negative quantity ; 
 for when Descartes had introduced the mode of repre- 
 senting curves by means of algebraical relations among 
 the symbols of the co-ordinates, or distances of each of 
 their points from fixed lines, it was found that negative 
 quantities must be dealt with as not less truly significant 
 than positive ones. And as the researches of mathema- 
 ticians proceeded, other cases also were found, in which 
 the symbols, although destitute of meaning according to 
 
THE FOUNDATIONS OF THE HIGHER MATHEMATICS. 140 
 
 the original conventions of their institution, still pointed 
 out truths which could be verified in other ways ; as in 
 the cases in which what are called impossible quantities 
 occur. Such processes may usually be confirmed upon 
 other principles, and the truth in question may be esta- 
 blished by means of a demonstration in which no such 
 seeeming fallacies defeat the reasoning. But it has also 
 been shown in many such cases, that the process in which 
 some of the steps appear to be without real meaning, 
 does in fact involve a valid proof of the proposition. 
 And what we have here to remark is, that this is not 
 true accidentally or partially only, but that the results 
 of systematic symbolical reasoning must always express 
 general truths, by their nature, and do not, for their 
 justification, require each of the steps of the process to 
 represent some definite operation upon quantity. The 
 absolute universality of the interpretation of symbols is 
 the fundamental principle of their use. This has been 
 shown very ably by Dr. Peacock in his Algebra. He 
 has there illustrated, in a variety of ways, this prin- 
 ciple : that " If general symbols express an identity 
 when they are supposed to be of any special nature, 
 they must also express an identity when they are gene- 
 ral in their nature." And thus, this universality of sym- 
 bols is a principle in addition to those we have already 
 noticed; and is a principle of the greatest importance 
 in the formation of mathematical science, according to 
 the wide generality which such science has in modern 
 times assumed. 
 
 3. Connexion of Symbols and Analysis. Since in 
 our symbolical reasoning our symbols thus reason for us, 
 we do not necessarily here, as in geometrical reasoning, 
 go on adding carefully one known truth to another, till 
 we reach the desired result. On the contrary, if we have 
 a theorem to prove or a problem to solve which can be 
 
150 PHILOSOPHY OF THE PURE SCIENCES. 
 
 brought under the domain of our symbols, we may at 
 once state the given but unproved truth, or the given 
 combination of unknown quantities, in its symbolical 
 form. After this first process, we may then proceed to 
 trace, by means of our symbols, what other truth is 
 involved in the one thus stated, or what the unknown 
 symbols must signify; resolving step by step the sym- 
 bolical assertion with which we began, into others more 
 fitted for our purpose. The former process is a kind of 
 synthesis, the latter is termed analysis. And although 
 symbolical reasoning does not necessarily imply such 
 analysis; yet the connexion is so familiar, that the 
 term analysis is frequently used to designate symbolical 
 reasoning. 
 
 CHAPTER XIII. 
 THE DOCTRINE OF MOTION. 
 
 1. Pure Mechanism,. THE doctrine of Motion, of 
 which we have here to speak, is that in which motion is 
 considered quite independently of its cause, force ; for 
 all consideration of force belongs to a class of ideas 
 entirely different from those with which we are here 
 concerned. In this view it may be termed the pure 
 doctrine of motion, since it has to do solely with space 
 and time, which are the subjects of pure mathematics. 
 (See C. I. of this Book.) Although the doctrine of 
 motion in connexion with force, which is the subject 
 of mechanics, is by far the most important form in 
 which the consideration of motion enters into the form- 
 ation of our sciences, the Pure Doctrine of Motion, 
 which treats of space, time, and velocity, might be fol- 
 lowed out so as to give rise to a very considerable and 
 curious body of science. Such a science is the science 
 
THE DOCTRINE OF MOTION. 151 
 
 of Mechanism, independent of force, and considered as 
 the solution of a problem which may be thus enunciated: 
 " To communicate any given motion from a first mover 
 to a given body." The science which should have for its 
 object to solve all the various cases into which this pro- 
 blem would ramify, might be termed Pure Mechanism, 
 in contradistinction to Mechanics Proper, or Machinery, 
 in which Force is taken into consideration. The greater 
 part of the machines which have been constructed for 
 use in manufactures have been practical solutions of some 
 of the cases of this problem. We have also important 
 contributions to such a science in the works of mathe- 
 maticians; for example, the various investigations and 
 demonstrations which have been published respecting 
 the form of the Teeth of Wheels, and Mr. Babbage's 
 memoir * on the Language of Machinery. There are 
 also several works which contain collections of the 
 mechanical contrivances which have been invented for 
 the purpose of transmitting and modifying motion, and 
 these works may be considered as treatises on the science 
 of Pure Mechanism. But this science has not yet been 
 reduced to the systematic simplicity which is desirable, 
 nor indeed generally recognized as a separate science. It 
 has been confounded, under the common name of Me- 
 chanics, with the other science, Mechanics Proper, or 
 Machinery, which considers the effect of force transmitted 
 by mechanism from one part of a material combination 
 to another. For example, the Mechanical Powers, as 
 they are usually termed, (the Lever, the Wheel and 
 Axle, the Inclined Plane, the Wedge, and the Screw,) 
 have almost always been treated with reference to the 
 relation between the Power and the Weight, and not 
 primarily as a mode of changing the velocity and kind 
 
 * On a Method of expressing by Signs Ike Action of Machinery. 
 Phil. Trans., 1826, p. 250. 
 
152 PHILOSOPHY OF THE PURE SCIENCES. 
 
 of the motion. The science of pure motion has not 
 generally been separated from the science of motion 
 viewed with reference to its causes. 
 
 Recently, indeed, the necessity of such a separation 
 has been seen by those who have taken a philosophical 
 view of science. Thus this necessity has been urged by 
 M. Ampere, in his Essai sur la Philosophic des Sciences 
 (1834): "Long," he says, (p. 50), "before I employed 
 myself upon the present work, I had remarked that it is 
 usual to omit, in the beginning of all books treating of 
 sciences which regard motion and force, certain consi- 
 derations which, duly developed, must constitute a special 
 science : of which science certain parts have been treated 
 of, either in memoirs or in special works ; such, for ex- 
 ample, as that of Carnot upon Motion considered geome- 
 trically, and the essay of Lanz and Betancourt upon the 
 Composition of Machines." He then proceeds to describe 
 this science nearly as we have done, and proposes to 
 term it Kinematics (Cinematique), from Kivqiua, motion. 
 
 2. Formal Astronomy. I shall not attempt here 
 further to develop the form which such a science must 
 assume. But I may notice one very large province which 
 belongs to it. When men had ascertained the apparent 
 motions of the sun, moon, and stars, to a moderate 
 degree of regularity and accuracy, they tried to conceive 
 in their minds some mechanism by which these motions 
 might be produced; and thus they in fact proposed to 
 themselves a very extensive problem in Kinematics. 
 This, indeed, was the view originally entertained of the 
 nature of the science of astronomy. Thus Plato in the 
 seventh Book of his Republic*, speaks of astronomy as 
 the doctrine of the motion of solids, meaning thereby, 
 spheres. And the same was a proper description of the 
 science till the time of Kepler, and even later : for 
 
 * P. 528. 
 
THE DOCTRINE OF MOTION. 153 
 
 Kepler endeavoured in vain to conjoin with the know- 
 ledge of the motions of the heavenly bodies, those true 
 mechanical conceptions which converted formal into 
 physical astronomy 5 '". 
 
 The astronomy of the ancients admitted none but 
 uniform circular motions, and could therefore be com- 
 pletely cultivated by the aid of their elementary geo- 
 metry. But the pure science of motion might be 
 extended to all motions, however varied as to the speed 
 or the path of the moving body. In this form it must 
 depend upon the doctrine of limits ; and the funda- 
 mental principle of its reasonings would be this : That 
 velocity is measured by the Limit of the space described, 
 considered with reference to the time in which it is 
 described. I shall hot further pursue this subject ; and 
 in order to complete what I have to say respecting the 
 Pure Sciences, I have only a few words to add respect- 
 ing their bearing on Inductive Science in general. 
 
 CHAPTER XIV. 
 
 OF THE APPLICATION OF MATHEMATICS TO 
 THE INDUCTIVE SCENCES. 
 
 1. ALL objects in the world which can be made the 
 subjects of our contemplation are subordinate to the 
 conditions of Space, Time, and Number; and on this 
 account, the doctrines of pure mathematics have most 
 numerous and extensive applications in every depart- 
 ment of our investigations of nature. And there is a 
 peculiarity in these Ideas, which has caused the mathe- 
 matical sciences to be, in all cases, the first successful 
 efforts of the awakening speculative powers of nations at 
 * Hist. Ind. Sc., n. 130. 
 
154 PHILOSOPHY OF THE PURE SCIENCES. 
 
 the commencement of their intellectual progress. Con- 
 ceptions derived from these Ideas are, from the very 
 first, perfectly precise and clear, so as to be fit elements 
 of scientific truths. This is not the case with the other 
 conceptions which form the subjects of scientific in- 
 quiries. The conception of statical force, for instance, 
 was never presented in a distinct form till the works of 
 Archimedes appeared : the conception of accelerating 
 force was confused, in the mind of Kepler and his con- 
 temporaries, and only became clear enough for purposes 
 of sound scientific reasoning in the succeeding century : 
 the just conception of chemical composition of elements 
 gradually, in modern times, emerged from the erroneous 
 and vague notions of the ancients. If we take works 
 published on such subjects before the epoch when the 
 foundations of the true science were laid, we find the 
 knowledge not only small, but worthless. The writers 
 did not see any evidence in what we now consider as the 
 axioms of the science ; nor any inconsistency where we 
 now see self-contradiction. But this was never the case 
 with speculations concerning space and number. From 
 their first rise, these were true as far as they went. 
 The Geometry and Arithmetic of the Greeks and Indians, 
 even in their first and most scanty form, contained none 
 but true propositions. Men's intuitions upon these sub- 
 jects never allowed them to slide into error and confu- 
 sion ; and the truths to which they were led by the first 
 efforts of their faculties, so employed, form part of the 
 present stock of our mathematical knowledge. 
 
 2. But we are here not so much concerned with 
 mathematics in their pure form, as with their applica- 
 tion to the phenomena and laws of nature. And here 
 also the very earliest history of civilization presents to 
 us some of the most remarkable examples of man's suc- 
 cess in his attempts to attain to science. Space and 
 
INDUCTIVE APPLICATION OF MATHEMATICS. 155 
 
 time, position and motion, govern all visible objects ; 
 but by far the most conspicuous examples of the rela- 
 tions which arise out of such elements, are displayed by 
 the ever-moving luminaries of the sky, which measure 
 days, and months, and years, by their motions, and 
 man's place on the earth by their position. Hence the 
 sciences of space and number were from the first culti- 
 vated with peculiar reference to Astronomy. I have 
 elsewhere* quoted Plato's remark, that it is absurd 
 to call the science of the relations of space geometry, 
 the measure of the earth, since its most important office 
 is to be found in its application to the heavens. And 
 on other occasions also it appears how strongly he, who 
 may be considered as the representative of the scientific 
 and speculative tendencies of his time and country, had 
 been impressed with the conviction, that the formation 
 of a science of the celestial motions must depend entirely 
 upon the progress of mathematics. In the Epilogue to 
 the Dialogue on the Laws\, he declares mathematical 
 knowledge to be the first and main requisite for the 
 astronomer, and describes the portions of it which he 
 holds necessary for astronomical speculators to culti- 
 vate. These seem to be, Plane Geometry, Theoretical 
 Arithmetic, the Application of Arithmetic to planes 
 and to solids, and finally the doctrine of Harmonics. 
 Indeed the bias of Plato appears to be rather to con- 
 sider mathematics as the essence of the science of 
 astronomy, than as its instrument; and he seems dis- 
 posed, in this as in other things, to disparage observa- 
 tion, and to aspire after a science founded upon demon- 
 stration alone. " An astronomer," he says in the same 
 place, "must not be like Hesiod and persons of that 
 kind, whose astronomy consists in noting the settings 
 and risings of the stars ; but he must be one who 
 * Hist. Ind. Sc., B. in. c. ii. t Epinomis, p. 990. 
 
156 PHILOSOPHY OF THE PURE SCIENCES. 
 
 understands the revolutions of the celestial spheres, each 
 performing its proper cycle." 
 
 A large portion of the mathematics of the Greeks, 
 so long as their scientific activity continued, was directed 
 towards astronomy. Besides many curious propositions 
 of plane and solid Geometry, to which their astronomers 
 were led, their Arithmetic, though very inconvenient in 
 its fundamental assumptions, was cultivated to a great 
 extent ; and the science of Trigonometry, in which pro- 
 blems concerning the relations of space were resolved by 
 means of tables of numerical results previously obtained, 
 was created. Menelaus of Alexandria wrote six Books 
 on Chords, probably containing methods of calculating 
 Tables of these quantities ; such Tables were familiarly 
 used by the later Greek astronomers. The same author 
 also wrote three Books on Spherical Trigonometry, 
 which are still extant. 
 
 3. The Greeks, however, in the first vigour of their 
 pursuit of mathematical truth, at the time of Plato and 
 soon after, had by no means confined themselves to 
 those propositions which had a visible bearing on the 
 phenomena of nature ; but had followed out many beau- 
 tiful trains of research, concerning various kinds of 
 figures, for the sake of their beauty alone ; as for in- 
 stance in their doctrine of Conic Sections, of which 
 curves they had discovered all the principal properties. 
 But it is curious to remark, that these investigations, 
 thus pursued at first as mere matters of curiosity and 
 intellectual gratification, were destined, two thousand 
 years later, to play a very important part in establishing 
 that system of the celestial motions which succeeded the 
 Platonic scheme of cycles and epicycles. If the proper- 
 ties of the conic sections had not been demonstrated by 
 the Greeks, and thus rendered familiar to the mathe- 
 maticians of succeeding ages, Kepler would probably 
 
INDUCTIVE APPLICATION OF MATHEMATICS. 157 
 
 not have been able to discover those laws respecting the 
 orbits and motions of the planets which were the occa- 
 sion of the greatest revolution that ever happened in 
 the history of science. 
 
 4. The Arabians, who, as I have elsewhere said, 
 added little of their own to the stores of science which 
 they received from the Greeks, did however make some 
 very important contributions in those portions of pure 
 mathematics which are subservient to astronomy. Their 
 adoption of the Indian mode of computation by means 
 of the Ten Digits, 1, 2, 3, 4, 5, 6, 7, 8, 9, 0, and by the 
 method of Local Values, instead of the cumbrous sexa- 
 gesimal arithmetic of the Greeks, was an improvement 
 by which the convenience and facility of numerical cal- 
 culations were immeasurably augmented. The Arabians 
 also rendered several of the processes of trigonometry 
 much more commodious, by using the Sine of an arc 
 instead of the Chord ; an improvement which Albateg- 
 nius appears to claim for himself'""; and by employing 
 also the Tangents of arcs, or, as they called themf, 
 upright shadows. 
 
 5. The constant application of mathematical know- 
 ledge to the researches of Astronomy, and the mutual 
 influence of each science on the progress of the other, 
 has been still more conspicuous in modern times. New- 
 ton's Method of Prime and Ultimate Ratios, which we 
 have already noticed as the first correct exposition of 
 the doctrine of a Limit, is stated in a series of Lemmas, 
 or preparatory theorems, prefixed to his Treatise on the 
 System of the World. Both the properties of curve 
 lines and the doctrines concerning force and motion, 
 which he had to establish, required that the common 
 mathematical methods should be methodized and ex- 
 tended. If Newton had not been a most expert and in- 
 
 * Delambre, Ask, M. A., p. 12. t Ibid., p. 17. 
 
158 PHILOSOPHY OF THE PURE SCIENCES. 
 
 ventive mathematician, as well as a profound and philo- 
 sophical thinker, he could never have made any one of 
 those vast strides in discovery of which the rapid succes- 
 sion in his work strikes us with wonder"". And if we 
 see that the great task begun by him, goes on more 
 slowly in the hands of his immediate successors, and 
 lingers a little before its full completion, we perceive 
 that this arises, in a great measure, from the defect of 
 the mathematical methods then used. Newton's syn- 
 thetical modes of investigation, as we have elsewhere 
 observed, were an instrument f, powerful indeed in his 
 mighty hand, but too ponderous for other persons to 
 employ with effect. The countrymen of Newton clung 
 to it the longest, out of veneration for their master ; and 
 English cultivators of physical astronomy were, on that 
 very account, left behind the progress of mathematical 
 science in France and Germany, by a wide interval, 
 which they have only recently recovered. On the Conti- 
 nent, the advantages offered by a familiar use of symbols, 
 and by attention to their symmetry and other relations, 
 were accepted without reserve. In this manner the 
 Differential Calculus of Leibnitz, which was in its origin 
 and signification identical with the Method of Fluxions 
 of Newton, soon surpassed its rival in the extent and 
 generality of its application to problems. This Calculus 
 was applied to the science of mechanics, to which it, 
 along with the symmetrical use of co-ordinates, gave a 
 new form ; for it was soon seen that the most difficult 
 problems might in general be reduced to finding inte- 
 grals, which is the reciprocal process of that by which 
 differentials are found ; so that all difficulties of physical 
 astronomy were reduced to difficulties of symbolical cal- 
 culation, these, indeed, being often sufficiently stubborn. 
 Clairaut, Euler, and D'Alembert employed the increased 
 
 * Hist. Ind. Sc., B. vir. c. ii. t 76., p. 175. 
 
INDUCTIVE APPLICATION OF MATHEMATICS. 159 
 
 resources of mathematical science upon the Theory of 
 the Moon, and other questions relative to the system of 
 the world ; and thus began to pursue such inquiries in 
 the course in which mathematicians are still labouring 
 up to the present day. This course was not without its 
 checks and perplexities. We have elsewhere quoted* 
 Clairaut's expression when he had obtained the very 
 complex differential equations which contain the solu- 
 tion of the problem of the moon's motion : " Now inte- 
 grate them who can !" But in no very long time they 
 were integrated, at least approximately ; and the methods 
 of approximation have since then been improved; so 
 that now, with a due expenditure of labour, they may be 
 carried to any extent which is thought desirable. If 
 the methods of astronomical observation should here- 
 after reach a higher degree of exactness than they now 
 profess, so that irregularities in the motions of the sun, 
 moon, and planets, shall be detected which at present 
 escape us, the mathematical part of the theory of univer- 
 sal gravitation is in such a condition that it can soon be 
 brought into comparison with the newly-observed facts. 
 Indeed at present the mathematical theory is in advance 
 of such observations. It can venture to suggest what 
 may afterwards be detected, as well as to explain what 
 has already been observed. This has happened recently; 
 for Professor Airy has calculated the law and amount 
 of an inequality depending upon the mutual attraction of 
 the Earth and Venus ; of which inequality (so small is 
 it,) it remains to be determined whether its effect can be 
 traced in the series of astronomical observations. 
 
 6. As the influence of mathematics upon the progress 
 of astronomy is thus seen in the cases in which theory 
 and observation confirm each other, so this influence ap- 
 pears in another way, in the very few cases in which the 
 
 * Hist. Ind. Sc., B. vi. c. vi. sect. 7- 
 
160 PHILOSOPHY OF THE PURE SCIENCES. 
 
 facts have not been fully reduced to an agreement with 
 theory. The most conspicuous case of this kind is the 
 state of our knowledge of the Tides. This is a portion 
 of astronomy : for the Newtonian theory asserts these 
 curious phenomena to be the result of the attraction of 
 the sun and moon. Nor can there be any doubt that 
 this is true, as a general statement ; yet the subject is 
 up to the present time a blot on the perfection of the 
 theory of universal gravitation ; for we are very far from 
 being able in this, as in the other parts of astronomy, to 
 show that theory will exactly account for the time, and 
 magnitude, and all other circumstances of the pheno- 
 menon at every place on the earth's surface. And what 
 is the portion of our mathematics which is connected 
 with this solitary signal defect in astronomy ? It is the 
 mathematics of the Motion of Fluids ; a portion in which 
 extremely little progress has been made, and in which all 
 the more general problems of the subject have hitherto 
 remained entirely insoluble. The attempts of the greatest 
 mathematicians, Newton, Maclaurin, Bernoulli, Clairaut, 
 Laplace, to master such questions, all involve some gra- 
 tuitous assumption, which is introduced because the 
 problem cannot otherwise be mathematically dealt with : 
 these assumptions confessedly render the result defective, 
 and how defective, it is hard to say. And it was pro- 
 bably precisely the absence of a theory which could be 
 reasonably expected to agree with the observations, which 
 made Observations of this very curious phenomenon, the 
 Tides, to be so much neglected as till very recently they 
 were. Of late years such observations have been pur- 
 sued, and their results have been resolved into empirical 
 laws, so that the rules of the phenomena have been 
 ascertained, although the dependence of these rules upon 
 the lunar and 'solar forces has not been shown. Here 
 then we have a portion of our knowledge relating to 
 
INDUCTIVE APPLICATION OF MATHEMATICS. 161 
 
 facts undoubtedly dependent upon universal gravitation, 
 in which Observation has outstripped Theory in her pro- 
 gress, and is compelled to wait till her usual companion 
 overtakes her. This is a position of which Mathematical 
 Theory has usually been very impatient, and we may 
 expect that she will be no less so in the present instance. 
 
 7. It would be easy to show from the history of 
 other sciences, for example, Mechanics and Optics, how 
 essential the cultivation of pure mathematics has been to 
 their progress. The parabola was already familiar among 
 mathematicians when Galileo discovered that it was the 
 theoretical path of a Projectile ; and the extension and 
 generalization of the Laws of Motion could never have 
 been effected, unless the Differential and Integral Cal- 
 culus had been at hand, ready to trace the results of every 
 hypothesis which could be made. D'Alembert's mode of 
 expressing the Third Law of Motion in its most general 
 form'*, if it did not prove the law, at least reduced the 
 application of it to analytical processes which could be 
 performed in most of those cases in which they were 
 needed. In many instances the demands of mechanical 
 science suggested the extension of the methods of pure 
 analysis. The problem of Vibrating Strings gave rise to 
 the Calculus of Partial Differences, which was still fur- 
 ther stimulated by its application to the motions of fluids 
 and other mechanical problems. And we have in the 
 writings of Lagrange and Laplace other instances equally 
 remarkable of new analytical methods, to which mecha- 
 nical problems, and especially cosmical problems, have 
 given occasion. 
 
 8. The progress of Optics as a science has, in like 
 manner, been throughout dependent upon the progress 
 of pure mathematics. The first rise of geometry was fol- 
 
 * Hist. Ind. Sci., B. vi. e. vi. sect. 7- 
 VOL. I. W. P. M 
 
162 PHILOSOPHY OE THE PURE SCIENCES. 
 
 lowed by some advances, slight ones no doubt, in the 
 doctrine of Reflection and in Perspective. The law of 
 Refraction was traced to its consequences by means of 
 Trigonometry, which indeed was requisite to express the 
 law in a simple form. The steps made in Optical science 
 by Descartes, Newton, Euler, and Huyghens, required 
 the geometrical skill which those philosophers possessed. 
 And if Young and Fresnel had not been, each in his 
 peculiar way, persons of eminent mathematical endow- 
 ments, they would not have been able to bring the 
 Theory of Undulations and Interferences into a condi- 
 tion in which it could be tested by experiments. We 
 may see how unexpectedly recondite parts of pure mathe- 
 matics may bear upon physical science, by calling to 
 mind a circumstance already noticed in the History of 
 Science* ; that Fresnel obtained one of the most curious 
 confirmations of the theory (the laws of Circular Polar- 
 ization by reflection) through an interpretation of an 
 algebraical expression, which, according to the original 
 conventional meaning of the symbols, involved an im- 
 possible quantity. We have already remarked, that in 
 virtue of the principle of the generality of symbolical 
 language, such an interpretation may often point out 
 some real and important analogy. 
 
 9. From this rapid sketch it may be seen how 
 important an office in promoting the progress of the 
 physical sciences belongs to mathematics. Indeed in 
 the progress of many sciences, every step has been so 
 intimately connected with some advance in mathematics, 
 that we can hardly be surprized if some persons have 
 considered mathematical reasoning to be the most essen- 
 tial part of such sciences ; and have overlooked the other 
 elements which enter into their formation. How erro- 
 * Hist. Ind. Sci.. B. ix. c. xiii. sect. 2. 
 
INDUCTIVE APPLICATION OF MATHEMATICS. 163 
 
 neous this view is we shall best see by turning our 
 attention to the other Ideas besides those of space, num- 
 ber, and motion, which enter into some of the most 
 conspicuous and admired portions of what is termed 
 exact science ; and by showing that the clear and distinct 
 developement of such Ideas is quite as necessary to the 
 progress of exact and real knowledge as an acquaintance 
 with arithmetic and geometry. 
 
164 
 
 BOOK III. 
 
 THE PHILOSOPHY OF THE MECHANICAL 
 SCIENCES. 
 
 CHAPTER I. 
 OF THE MECHANICAL SCIENCES. 
 
 IN the History of the Sciences, that class of which we 
 here speak occupies a conspicuous and important place ; 
 coming into notice immediately after those parts of astro- 
 nomy which require for their cultivation merely the 
 ideas of space, time, motion, and number. It appears 
 from our History, that certain truths concerning the equi- 
 librium of bodies were established by Archimedes ; that, 
 after a long interval of inactivity, his principles were 
 extended and pursued further in modern times : and 
 that to these doctrines concerning equilibrium and the 
 forces which produce it, (which constitute the science 
 Statics,) were added many other doctrines concerning 
 the motions of bodies, considered also as produced by 
 forces, and thus the science of Dynamics was produced. 
 The assemblage of these sciences composes the province 
 of Mechanics. Moreover, philosophers have laboured to 
 make out the laws of the equilibrium of fluid as well as 
 solid bodies ; and hence has arisen the science of Hydro- 
 statics. And the doctrines of Mechanics have been found 
 to have a most remarkable bearing upon the motions 
 of the heavenly bodies ; with reference to which, indeed, 
 they were at first principally studied. The explanation 
 
OF THE MECHANICAL SCIENCES. 165 
 
 of those cosmical facts by means of mechanical principles 
 and their consequences, forms the science of Physical 
 Astronomy. These are the principal examples of mecha- 
 nical science ; although some other portions of Physics, 
 as Magnetism and Electrodynamics, introduce mecha- 
 nical doctrines very largely into their speculations. 
 
 Now in all these sciences we have to consider Forces. 
 In all mechanical reasonings forces enter, either as pro- 
 ducing motion, or as prevented from doing so by other 
 forces. Thus force, in its most general sense, is the cause 
 of motion, or of tendency to motion ; and in order to 
 discover the principles on which the mechanical sciences 
 truly rest, we must examine the nature and origin of 
 our knowledge of Causes. 
 
 In these sciences, however, we have not to deal with 
 Cause in its more general acceptation, in which it applies 
 to all kinds of agency, material or immaterial ; to the 
 influence of thought and will, as well as of bodily pres- 
 sure and attractive force. Our business at present is 
 only with such causes as immediately operate upon 
 matter. We shall nevertheless, in the first place, con- 
 sider the nature of Cause in its most general form ; and 
 afterwards narrow our speculations so as to direct them 
 specially to the mechanical sciences. 
 
 CHAPTER II. 
 OF THE IDEA OF CAUSE. 
 
 1. WE see in the world around us a constant suc- 
 cession of causes and effects connected with each other. 
 The laws of this connexion we learn in a great measure 
 from experience, by observation of the occurrences which 
 present themselves to our notice, succeeding one another. 
 
166 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 But in doing this, and in attending to this succession of 
 appearances, of which we are aware by means of our 
 senses, we supply from our own minds the Idea of Cause. 
 This Idea, as we have already shown with respect to 
 other Ideas, is not derived from experience, but has its 
 origin in the mind itself; is introduced into our expe- 
 rience by the active, and not by the passive part of our 
 nature. 
 
 By Cause we mean some quality, power, or efficacy, 
 by which a state of things produces a succeeding state. 
 Thus the motion of bodies from rest is produced by a 
 cause which we call Force: and in the particular case 
 in which bodies fall to the earth, this force is termed 
 Gravity. In these cases, the Conceptions of Force and 
 Gravity receive their meaning from the Idea of Cause 
 which they involve : for Force is conceived as the Cause 
 of Motion. That this Idea of Cause is not derived from 
 experience, we prove (as in former cases) by this con- 
 sideration : that we can make assertions, involving this 
 idea, which are rigorously necessary and universal ; 
 whereas knowledge derived from experience can only be 
 true as far as experience goes, and can never contain in 
 itself any evidence whatever of its necessity. We assert 
 that " Every event must have a cause :" and this proposi- 
 tion we know to be true, not only probably, and gene- 
 rally, and as far as we can see : but we cannot suppose 
 it to be false in any single instance. We are as certain 
 of it as of the truths of arithmetic or geometry. We 
 cannot doubt that it must apply to all events past and 
 future, in every part of the universe, just as truly as 
 to those occurrences which we have ourselves observed. 
 What causes produce what effects; what is the cause 
 of any particular event ; what will be the effect of any 
 peculiar process ; these are points on which experience 
 may enlighten us. Observation and experience may be 
 
OF THE IDEA OF CAUSE. 167 
 
 requisite, to enable us to judge respecting such matters. 
 But that every event has some cause, Experience cannot 
 prove any more than she can disprove. She can add 
 nothing to the evidence of the truth, however often she 
 may exemplify it. This doctrine, then, cannot have been 
 acquired by her teaching ; and the Idea of Cause, which 
 the doctrine involves, and on which it depends, cannot 
 have come into our minds from the region of observa- 
 tion. 
 
 2. That we do, in fact, apply the Idea of Cause in a 
 more extensive manner than could be justified, if it were 
 derived from experience only, is easily shown. For from 
 the principle that everything must have a cause, we not 
 only reason concerning the succession of the events which 
 occur in the progress of the world, and which form the 
 course of experience ; but we infer that the world itself 
 must have a cause ; that the chain of events connected 
 by common causation, must have a First Cause of a 
 nature different from the events themselves. This we 
 are entitled to do, if our Idea of Cause be independent of, 
 and superior to, experience : but if we have no Idea of 
 Cause except such as we gather from experience, this 
 reasoning is altogether baseless and unmeaning. 
 
 3. Again ; by the use of our powers of observation, 
 we are aware of a succession of appearances and events. 
 But none of our senses or powers of external observa- 
 tion can detect in these appearances the power or quality 
 which we call Cause. Cause is that which connects one 
 event with another ; but no sense or perception discloses 
 to us, or can disclose, any connexion among the events 
 which we observe. We see that one occurrence follows 
 another, but we can never see anything which shows that 
 one occurrence must follow another. We have already 
 noticed""", that this truth has been urged by metaphy- 
 
 Book i., chap. xiii. 
 
168 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 sicians in modern times, and generally assented to by 
 those who examine carefully the connexion of their own 
 thoughts. The arguments are, indeed, obvious enough. 
 One ball strikes another and causes it to move forwards. 
 But by what compulsion ? Where is the necessity ? If 
 the mind can see any circumstance in this case which 
 makes the result inevitable, let this circumstance be 
 pointed out. But, in fact, there is no such discoverable 
 necessity; for we can conceive this event not to take 
 place at all. The struck ball may stand still, for aught 
 we can see. " But the laws of motion will not allow it 
 to do so." Doubtless they will not. But the laws of 
 motion are learnt from experience, and therefore can 
 prove no necessity. Why should not the laws of motion 
 be other than they are? Are they necessarily true? 
 That they are necessarily such as do actually regulate the 
 impact of bodies, is at least no obvious truth ; and there- 
 fore this necessity cannot be, in common minds, the 
 ground of connecting the impact of one ball with the 
 motion of another. And assuredly, if this fail, no other 
 ground of such necessary connexion can be shown. In 
 this case, then, the events are not seen to be necessarily 
 connected. But if this case, where one ball moves another 
 by impulse, be not an instance of events exhibiting a 
 necessary connexion, we shall look in vain for any ex- 
 ample of such a connexion. There is, then, no case in 
 which events can be observed to be necessarily con- 
 nected : our idea of causation, which implies that the 
 event is necessarily connected with the cause, cannot be 
 derived from observation. 
 
 4. But it may be said, we have not any such Idea of 
 Cause, implying necessary connexion with effect, and a 
 quality by which this connexion is produced. We see 
 nothing but the succession of events ; and by cause we 
 mean nothing but a certain succession of events; name- 
 
OF THE IDEA OF CAUSE. 169 
 
 ly, a constant, unvarying succession. Cause and effect 
 are only two events of which the second invariably 
 follows the first. We delude ourselves when we ima- 
 gine that our idea of causation involves anything more 
 than this. 
 
 To this I reply by asking, what then is the meaning 
 of the maxim above quoted, and allowed by all to be 
 universally and necessarily true, that every event must 
 have a cause ? Let us put this maxim into the language 
 of the explanation just noticed ; and it becomes this : 
 "Every event must have a certain other event invariably 
 preceding it." But why must it? Where is the neces- 
 sity ? Why must like events always be preceded by like, 
 except so far as other events interfere? That there is 
 such a necessity, no one can doubt. All will allow that 
 if a stone ascend because it is thrown upwards in one 
 case, a stone which ascends in another case has also 
 been thrown upwards, or has undergone some equi- 
 valent operation. All will allow that in this sense, 
 every kind of event must have some other specific kind 
 of event preceding it. But this turn of men's thoughts 
 shows that they see in events a connexion which is not 
 mere succession. They see in cause and effect, not 
 merely what does, often or always, precede and follow, 
 but what must precede and follow. The events are not 
 only conjoined, they are connected. The cause is more 
 than the prelude, the effect is more than the sequel, of 
 the fact. The cause is conceived not as a mere occa- 
 sion ; it is a power, an efficacy, which has a real ope- 
 ration. 
 
 5. Thus we have drawn from the maxim, that Every 
 Effect must have a Cause, arguments to show that we 
 have an Idea of Cause which is not borrowed from expe- 
 rience, and which involves more than mere succession. 
 Similar arguments might be derived from any other 
 
170 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 maxims of universal and necessary validity, which we 
 can obtain concerning Cause : as, for example, the max- 
 ims that Causes are measured by their Effects, and that 
 Reaction is equal and opposite to Action. These maxims 
 we shall soon have to examine ; but we may observe here, 
 that the necessary truth which belongs to them, shows 
 that they, and the Ideas which they involve, are not the 
 mere fruits of observation; while their meaning, including, 
 as it does, something quite different from the mere con- 
 ception of succession of events, proves that such a con- 
 ception is far from containing the whole import and 
 signification of our Idea of Cause. 
 
 The progress of the opinions of philosophers on the 
 points discussed in this chapter, has been one of the 
 most remarkable parts of the history of Metaphysics in 
 modern times : and I shall therefore briefly notice some 
 of its features. 
 
 CHAPTER III. 
 
 MODERN OPINIONS RESPECTING THE IDEA 
 OF CAUSE. 
 
 1. TOWARDS the end of the seventeenth century there 
 existed in the minds of many of the most vigorous and 
 active speculators of the European literary world, a strong 
 tendency to ascribe the whole of our Knowledge to the 
 teaching of Experience. This tendency, with its conse- 
 quences, including among them the reaction which was 
 produced when the tenet had been pushed to a length 
 manifestly absurd, has exercised a very powerful in- 
 fluence upon the progress of metaphysical doctrines up 
 to the present time. I proceed to notice some of the 
 most prominent of the opinions which have thus ob- 
 
OPINIONS RESPECTING THE IDEA OF CAUSE. 171 
 
 tained prevalence among philosophers, so far as the Idea 
 of Cause is concerned. 
 
 Locke was one of the metaphysicians who produced 
 the greatest effect in diffusing this opinion, of the exclu- 
 sive dependence of our knowledge upon experience. 
 Agreeably to this general system, he taught""" that our 
 ideas of Cause and Effect are got from observation of 
 the things about us. Yet notwithstanding this tenet of 
 his, he endeavoured still to employ these ideas in rea- 
 soning on subjects which are far beyond all limits of 
 experience : for he professed to prove, from our idea of 
 Causation, the existence of the Deity f. 
 
 Hume noticed this obvious inconsistency; but declared 
 himself unable to discover any remedy for a defect so 
 fatal to the most important parts of our knowledge. He 
 could see, in our belief of the succession of cause and 
 effect, nothing but the habit of associating in our minds 
 what had often been associated in our experience. He 
 therefore maintained that we could not, with logical 
 propriety, extend our belief of such a succession to cases 
 entirely distinct from all those of which our experience 
 consisted. We see, he said, an actual conjunction of two 
 events ; but we can in no way detect a necessary con- 
 nexion ; and therefore we , have no means of inferring 
 cause from effect, or effect from cause \. The only way 
 in which we recognize Cause and Effect in the field of 
 our experience, is as an unfailing Sequence : we look in 
 vain for anything which can assure us of an infallible 
 Consequence. And since experience is the only source 
 of our knowledge, we cannot with any justice assert 
 that the world in which we live must necessarily have 
 had a cause. 
 
 2. This doctrine, taken in conjunction with the known 
 
 * Essay on the Human Understanding, B. n. c xxvi. t B. iv. c. x. 
 { Humes Phil, of the Human Mind, Vol. i. p. 94. 
 
172 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 skepticism of its author on religious points, produced a 
 considerable fermentation in the speculative world. The 
 solution of the difficulty thus thrown before philosophers, 
 was by no means obvious. It was vain to endeavour to 
 find in experience any other property of a Cause, than a 
 constant sequence of the effect. Yet it was equally vain 
 to try to persuade men that they had no idea of Cause ; 
 or even to shake their belief in the cogency of the fami- 
 liar arguments concerning the necessity of an original 
 cause of all that is and happens. Accordingly these 
 hostile and apparently irreconcilable doctrines, the in- 
 dispensable necessity of a cause of every event, and the 
 impossibility of our knowing such a necessity, were at 
 last allowed to encamp side by side. Reid, Beattie, and 
 others, formed one party, who showed how widely and 
 constantly the idea of a cause pervades all the processes 
 of the human mind : while another sect, including Brown, 
 and apparently Stewart, maintained that this idea is 
 always capable of being resolved into a constant se- 
 quence ; and these latter reasoners tried to obviate the 
 dangerous and shocking inferences which some persons 
 might try to draw from their opinion, by declaring the 
 maxim that " Every event must have a cause," to be an 
 instinctive law of belief, or a fundamental principle of 
 the human mind*. 
 
 3. While this series of discussions was going on in 
 Britain, a great metaphysical genius in Germany was 
 unravelling the perplexity in another way. Kant's spe- 
 culations originated, as he informs us, in the trains of 
 thought to which Hume's writings gave rise ; and the 
 Kritik der Reinen Vernunft, or Examination of the 
 Pure Reason, was published in 1787, with the view of 
 showing the true nature of our knowledge. 
 
 * Stewart's Active Powers, Vol. i. p. 347- Brown's Lectures, 
 Vol. i. p. 115. 
 
OPINIONS RESPECTING THE IDEA OF CAUSE. 173 
 
 Kant's solution of the difficulties just mentioned 
 differs materially from that above stated. According to 
 Brown"-, succession observed and cause inferred, the 
 memory of past conjunctions of events and the belief of 
 similar future conjunctions, are facts, independent, so 
 far as we can discover, but inseparably combined by a 
 law of our mental nature. According to Kant, causality 
 is an inseparable condition of our experience : a con- 
 nexion in events is requisite to our apprehending them as 
 events. Future occurrences must be connected by causa- 
 tion as the past have been, because we cannot think of 
 past, present, and future, without such connexion. We 
 cannot fix the mind upon occurrences, without including 
 these occurrences in a series of causes and effects. The 
 relation of Causation is a condition under which we 
 think of events, as the relations of space are a condition 
 under which we see objects. 
 
 4. On a subject so abstruse, it is not easy to make 
 our distinctions very clear. Some of Brown's illustrations 
 appear to approach very near to the doctrine of Kant. 
 Thus he saysf, "The form of bodies is the relation of 
 their elements to each other in space, the power of 
 bodies is their relation to each other in time." Yet not- 
 withstanding such approximations in expression, the 
 Kantian doctrine appears to be different from the views 
 of Stewart and Brown, as commonly understood. Ac- 
 cording to the Scotch philosophers, the cause and the 
 effect are two things, connected in our minds by a law 
 of our nature. But this view requires us to suppose that 
 we can conceive the law to be absent, and the course of 
 events to be unconnected. If we can understand what is 
 the special force of this law, we must be able to imagine 
 what the case would be if the law were non-existing. We 
 must be able to conceive a mind which does not connect 
 * Lect.. Vol. i. p. 114. t Led., i. p. 127. 
 
174 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 effectp with causes. The Kantian doctrine, on the other 
 hand, teaches that we cannot imagine events liberated 
 from the connexion of cause and effect : this connexion is 
 a condition of our conceiving any real occurrences : we 
 cannot think of a real sequence of things, except as in- 
 volving the operation of causes. In the Scotch system, 
 the past and the future are in their nature independent, 
 but bound together by a rule ; in the German system, 
 they share in a common nature and mutual relation, by 
 the act of thought which makes them past and future. 
 In the former doctrine cause is a tie which binds ; in the 
 latter it is a character which pervades and shapes events. 
 The Scotch metaphysicians only assert the universality 
 of the relation ; the German attempts further to explain 
 its necessity. 
 
 This being the state of the case, such illustrations as 
 that of Dr. Brown quoted above, in which he represents 
 cause as a relation of the same kind with form, do not 
 appear exactly to fit his opinions. Can the relations of 
 figure be properly said to be connected with each other 
 by a law of our nature, or a tendency of our mental con- 
 stitution ? Can we ascribe it to a law of our thoughts, 
 that we believe the three angles of a triangle to be equal 
 to two right angles? If so, we must give the same 
 reason for our belief that two straight lines cannot 
 inclose a space ; or that three and two are five. But 
 will any one refer us to an ultimate law of our consti- 
 tution for the belief that three and two are five? Do 
 we not see that they are so, as plainly as we see that 
 they are three and two ? Can we imagine laws of our 
 constitution abolished, so that three and two shall make 
 something different from five ; so that an inclosed space 
 shall lie between two straight lines ; so that the three 
 angles of a plane triangle shall be greater than two 
 right angles? We cannot conceive this. If the num- 
 
OPINIONS RESPECTING THE IDEA OF CAUSE. 175 
 
 bers are three and two ; if the lines are straight ; if the 
 triangle is a rectilinear triangle, the consequences are 
 inevitable. We cannot even imagine the contrary. We 
 do not want a law to direct that things should be what 
 they are. The relation, then, of cause and effect, being 
 of the same kind as the necessary relations of figure and 
 number, is not properly spoken of as established in our 
 minds by a special law of our constitution : for we reject 
 that loose and inappropriate phraseology which speaks 
 of the relations of figure and number as " determined by 
 laws of belief." 
 
 5. In the present work, we accept and adopt,-as the 
 basis of our inquiry concerning our knowledge, the exist- 
 ence of necessary truths concerning causes, as there exist 
 necessary truths concerning figure and number. We 
 find such truths universally established and assented to 
 among the cultivators of science, and among speculative 
 men in general. All mechanicians agree that reaction 
 is equal and opposite to action, both when one body 
 presses another, and when one body communicates mo- 
 tion to another. All reasoners join in the assertion, not 
 only that every observed change of motion has had a 
 cause, but that every change of motion must have a 
 cause. Here we have certain portions of substantial 
 and undoubted knowledge. Now the essential point in 
 the view which we must take of the idea of cause is 
 this, that our view must be such as to form a solid 
 basis for our knowledge. We have, in the Mechanical 
 Sciences, certain universal and necessary truths on the 
 subject of causes. Now any view which refers our be- 
 lief in causation to mere experience or habit, cannot 
 explain the possibility of such necessary truths, since 
 experience and habit can never lead to a perception of 
 necessary connexion. But a view which teaches us to 
 acknowledge axioms concerning cause, as we acknow- 
 
176 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 ledge axioms concerning space, will lead us to look upon 
 the science of mechanics as equally certain and univer- 
 sal with the science of geometry ; and will thus mate- 
 rially affect our judgment concerning the nature and 
 claims of our scientific knowledge. 
 
 Axioms concerning Cause, or concerning Force, 
 which as we shall see, is a modification of Cause, will 
 flow from an Idea of Cause, just as axioms concerning 
 space and number flow from the ideas of space and num- 
 ber or time. And thus the propositions which con- 
 stitute the science of Mechanics prove that we possess 
 an idea of cause, in the same sense in which the propo- 
 sitions of geometry and arithmetic prove our possession 
 of the ideas of space and of time or number. 
 
 6. The idea of cause, like the ideas of space and 
 time, is a part of the active powers of the mind. The 
 relation of cause and effect is a relation or condition 
 under which events are apprehended, which relation is 
 not given by observation, but supplied by the mind itself. 
 According to the views which explain our apprehension 
 of cause by reference to habit, or to a supposed law of 
 our mental nature, causal connexion is a consequence of 
 agencies which the mind passively obeys ; but according 
 to the view to which we are led, this connexion is a 
 result of faculties which the mind actively exercises. 
 And thus the relation of cause and effect is a condition 
 of our apprehending successive events, a part of the 
 mind's constant and universal activity, a source of neces- 
 sary truths ; or, to sum all this in one phrase, a Funda- 
 mental Idea. 
 
177 
 
 CHAPTER IV. 
 
 OF THE AXIOMS WHICH RELATE TO THE IDEA 
 
 OF CAUSE. 
 
 1. Causes are abstract Conceptions. WE have now 
 to express, as well as we can, the fundamental character 
 of that Idea of Cause, of which we have just proved the 
 existence. This may be done, at least for purposes of 
 reasoning, in this as in former instances, by means of 
 axioms. I shall state the principal axioms which belong 
 to this subject, referring the reader to his own thoughts 
 for the axiomatic evidence which belongs to them. 
 
 But I must first observe, that in order to express 
 general and abstract truths concerning cause and effect, 
 these terms, cause and effect, must be understood in a 
 general and abstract manner. When one event gives rise 
 to another, the first event is, in common language, often 
 called the cause, and the second the effect. Thus the 
 meeting of two billiard balls may be said to be the 
 cause of one of them turning aside out of the path in 
 which it was moving. For our present purposes, how- 
 ever, we must not apply the term cause to such occur- 
 rences as this meeting and turning, but to a certain 
 conception, force, abstracted from all such special events, 
 and considered as a quality or property by which one 
 body affects the motion of the other. And in like man- 
 ner in other cases, cause is to be conceived as some 
 abstract quality, power, or efficacy, by which change is 
 produced ; a quality not identical with the events, but 
 disclosed by means of them. Not only is this abstract 
 mode of conceiving force and cause useful in expressing 
 the fundamental principles of science ; but it supplies us 
 with the only mode by which such principles can be 
 VOL. i. w. P. N 
 
178 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 stated in a general manner, and made to lead to sub- 
 stantial truth and real knowledge. 
 
 Understanding cause, therefore, in this sense, we 
 proceed to our Axioms. 
 
 2. First Axiom. Nothing can take place without a 
 Cause. 
 
 Every event, of whatever kind, must have a Cause in 
 the sense of the term which we have just indicated; and 
 that it must, is a universal and necessary proposition to 
 which we irresistibly assent as soon as it is understood. 
 We believe each appearance to come into existence, 
 we conceive every change to take place, not only with 
 something preceding it, but something by which it is made 
 to be what it is. An effect without a cause ; an event 
 without a preceding condition involving the efficacy by 
 which the event is produced; are suppositions which we 
 cannot for a moment admit. That the connexion of effect 
 with cause is universal and necessary, is a universal and 
 constant conviction of mankind. It persists in the minds 
 of all men, undisturbed by all the assaults of sophistry 
 and skepticism; and, as we have seen in the last chapter, 
 remains unshaken, even when its foundations seem to be 
 ruined. This axiom expresses, to a certain extent, our 
 Idea of Cause ; and when that idea is clearly appre- 
 hended, the axiom requires no proof, and indeed admits 
 of none which makes it more evident. That notwith- 
 standing its simplicity, it is of use in our speculations, we 
 shall hereafter see ; but in the first place, we must con- 
 sider the other axioms belonging to this subject. 
 
 3. Second Axiom. Effects are proportional to their 
 Causes, and Causes are measured by their Effects. 
 
 We have already said that cause is that quality or 
 power, in the circumstances of each case, by which the 
 effect is produced ; and this power, an abstract property 
 of the condition of things to which it belongs, can in 
 
AXIOMS WHICH RELATE TO THE IDEA OF CAUSE. 179 
 
 no way fall directly under the cognizance of the senses. 
 Cause, of whatever kind, is not apprehended as including 
 objects and events which share its nature by being co-ex- 
 tensive with certain portions of it, as space and time are. 
 It cannot therefore, like them, be measured by repeti- 
 tion of its own parts, as space is measured by repetition 
 of inches, and time by repetition of minutes. Causes may 
 be greater or less ; as, for instance, the force of a man is 
 greater than the force of a child. But how much is the 
 one greater than the other ? How are we to compare 
 the abstract conception, force, in such cases as these ? 
 
 To this, the obvious and only answer is, that we must 
 compare causes by means of their effects ; that we must 
 compare force by something which force can do. The 
 child can lift one fagot ; the man can lift ten such fagots : 
 we have here a means of comparison. And whether or 
 not the rule is to be applied in this manner, that is, by 
 the number of the things operated on, (a question which 
 we shall have to consider hereafter,) it is clear that this 
 form of rule, namely, a reference to some effect or other 
 as our measure, is the right, because the only possible 
 form. The cause determines the effect. The cause being 
 the same, the effect must be the same. The connexion 
 of the two is governed by a fixed and inviolable rule. 
 It admits of no ambiguity. Every degree of intensity 
 in the cause has some peculiar modification of the effect 
 corresponding to it. Hence the effect is an unfailing 
 index of the amount of the cause ; and if it be a mea- 
 surable effect, gives a measure of the cause. We can 
 have no other measure ; but we need no other, for this 
 is exact, sufficient, and complete. 
 
 It may be said, that various effects are produced by 
 the same cause. The sun's heat melts wax and expands 
 quicksilver. The force of gravity causes bodies to move 
 downwards if they are free, and to press down upon their 
 
 N2 
 
180 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 supports if they are supported. Which of the effects is to 
 be taken as the measure of heat, or of gravity, in these 
 cases ? To this we reply, that if we had merely different 
 states of the same cause to compare, any of the effects 
 might be taken. The sun's heat on different days might 
 be measured by the expansion of quicksilver, or by the 
 quantity of wax melted. The force of gravity, if it were 
 different at different places, might be measured by the 
 spaces through which a given weight would bend an 
 elastic support, or by the spaces through which a body 
 would fall in a given time. All these measures are con- 
 sistent with the general character of our idea of cause. 
 
 4. Limitation of the Second Axiom. But there may 
 be circumstances in the nature of the case which may 
 further determine the kind of effect which we must take 
 for the measure of the cause. For example, if causes 
 are conceived to be of such a nature as to be capable of 
 addition, the effects taken as their measure must conform 
 to this condition. This is the case with mechanical 
 causes. The weights of two bodies are the causes of the 
 pressure which they exert downwards ; and these weights 
 are capable of addition. The weight of the two is the 
 sum of the weight of each. We are therefore not at 
 liberty to say that weights shall be measured by the 
 spaces through which they bend a certain elastic support, 
 except we have first ascertained that the whole weight 
 bends it through a space equal to the sum of the inflec- 
 tions produced by the separate weights. Without this 
 precaution, we might obtain inconsistent results. Two 
 weights, each of the magnitude 3 as measured by their 
 effects, might, if we took the inflections of a spring for 
 the effects, be together equal to 5 or to 7 by the same 
 kind of measurement. For the inflection produced by 
 two weights of 3 might, for aught we can see before- 
 hand, be more or less than twice as great as the inflection 
 
AXIOMS WHICH RELATE TO THE IDEA OF CAUSE. 181 
 
 produced by one weight of 3. That forces are capable of 
 addition, is a condition which limits, and, as we shall see, 
 in some cases rigorously fixes, the kind of effects which 
 are to be taken as their measures. 
 
 Causes which are thus capable of addition are to be 
 measured by the repeated addition of equal quantities. 
 Two such causes are equal to each other when they pro- 
 duce exactly the same eifect. So far our axiom is applied 
 directly. But these two causes can be added together ; 
 and being thus added, they are double of one of them ; 
 and the cause composed by addition of three such, is 
 three times as great as the first ; and so on for any mea- 
 sure whatever. By this means, and by this means only, 
 we have a complete and consistent measure of those 
 causes which are so conceived as to be subject to this 
 condition of being added and multiplied. 
 
 Causes are, in the present chapter, to be understood 
 in the widest sense of the term ; and the axiom now 
 under our consideration applies to them, whenever they 
 are of such a nature as to admit of any measure at all. 
 But the cases which we have more particularly in view 
 are mechanical causes, the causes of the motion and of 
 the equilibrium of bodies. In these cases, forces are con- 
 ceived as capable of addition ; and what has been said of 
 the measure of causes in such cases, applies peculiarly to 
 mechanical forces. Two weights, placed together, may 
 be considered as a single weight, equal to the sum of the 
 two. Two pressures, pushing a body in the same direc- 
 tion at the same point, are identical in all respects with 
 some single pressure, their sum, pushing in like manner; 
 and this is true whether or not they put the body in 
 motion. In the cases of mechanical forces, therefore, we 
 take some certain effect, velocity generated or weight 
 supported, which may fix the unit of force ; and we then 
 measure all other forces by the successive repetition of 
 
182 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 this unit, as we measure all spaces by the successive 
 repetition of our unit of lineal measure. 
 
 But these steps in the formation of the science of 
 Mechanics will be further explained, when we come to 
 follow our axioms concerning cause into their application 
 in that science. At present we have, perhaps, suffi- 
 ciently explained the axiom that causes are measured 
 by their effects, and we now proceed to a third axiom, 
 also of great importance. 
 
 5. Third Axiom. Reaction is equal and opposite to 
 Action. 
 
 In the case of mechanical forces, the action of a 
 cause often takes place by an operation of one body 
 upon another ; and in this case, the action is always and 
 inevitably accompanied by an opposite action. If I press 
 a stone with my hand, the stone presses my hand in 
 return. If one ball strike another and put it in motion, 
 the second ball diminishes the motion of the first. In 
 these cases the operation is mutual; the Action is ac- 
 companied by a Reaction. And in all such cases the 
 Reaction is a force of exactly the same nature as the 
 Action, exerted in an opposite direction. A pressure 
 exerted upon a body at rest is resisted and balanced by 
 another pressure ; when the pressure of one body puts 
 another in motion, the body, though it yields to the force, 
 nevertheless exerts upon the pressing body a force like 
 that which it suffers. 
 
 Now the axiom asserts further, that this Reaction 
 is equal, as well as opposite, to the Action. For the 
 Reaction is an effect of the Action, and is determined by 
 it. And since the two, Action and Reaction, are forces 
 of the same nature, each may be considered as cause 
 and as effect ; and they must, therefore, determine each 
 other by a common rule. But this consideration leads 
 necessarily to their equality : for since the rule is mutual, 
 
AXIOMS WHICH RELATE TO THE IDEA OF CAUSE. 183 
 
 if we could for an instant suppose the Reaction to be 
 less than the Action, we must, by the same rule, sup- 
 pose the Action to be less than the Reaction. And thus 
 Action and Reaction, in every such case, are rigorously 
 equal to each other. 
 
 It is easily seen that this axiom is not a proposition 
 which is, or can be, proved by experience ; but that its 
 truth is anterior to special observation, and depends on 
 our conception of Action and Reaction. Like our other 
 axioms, this has its source in an Idea ; namely, the Idea 
 of Cause, under that particular condition in which cause 
 and effect are mutual. The necessary and universal 
 truth which we cannot help ascribing to the axiom, shows 
 that it is not derived from the stores of experience, 
 which can never contain truths of this character. Ac- 
 cordingly, it was asserted with equal confidence and 
 generality by those who did not refer to experience for 
 their principles, and by those who did. Leonicus Tomseus, 
 a commentator of Aristotle, whose work was published 
 in 1552, and therefore at a period when no right opinions 
 concerning mechanical reaction were current, at least 
 in his school, says, in his remarks on the Author's Ques- 
 tions concerning the communication of motion, that 
 " Reaction is equal and contrary to Action." The same 
 principle was taken for granted by all parties, in all the 
 controversies concerning the proper measure of force, of 
 which we shall have to speak : and would be rigorously 
 true, as a law of motion, whichever of the rival inter- 
 pretations of the measure of the term li Action" we were 
 to take. 
 
 6. Extent of the Third Axiom. It may naturally be 
 asked whether this third Axiom respecting causation 
 extends to any other cases than those of mechanical 
 action, since the notion of Cause in general has certainly 
 a much wider extent. For instance, when a hot body 
 
184 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 heats a cold one, is there necessarily an equal reaction 
 of the second body upon the first ? Does the snowball 
 cool the boy's hand exactly as much as the hand heats 
 the snow ? To this we reply, that, in every case in which 
 one body acts upon another by its physical qualities, there 
 must be some reaction. No body can affect another 
 without being itself also affected. But in any physical 
 change the action exerted is an abstract term which may 
 be variously understood. The hot hand may melt a 
 cold body, or may warm it : which kind of effect is to 
 be taken as action ? This remains to be determined by 
 other considerations. 
 
 In all cases of physical change produced by one body 
 in another, it is generally possible to assume such a 
 meaning of action, that the reaction shall be of the same 
 nature as the action ; and when this is done, the third 
 axiom of causation, that reaction is equal to action, is 
 universally true. Thus if a hot body heat a cold one, 
 the change may be conceived as the transfer of a certain 
 substance, heat or caloric, from the first body to the 
 second. On this supposition, the first body loses just as 
 much heat as the other gains ; action and reaction are 
 equal. But if the reaction be of a different kind to the 
 action we can no longer apply the axiom. If a hot body 
 melt a cold one, the latter cools the former : here, then, is 
 reaction ; but so long as the action and reaction are stated 
 in this form, we cannot assert any equality between them. 
 
 In treating of the secondary mechanical sciences, we 
 shall see further in what way we may conceive the 
 physical action of one body upon another, so that the 
 same axioms which are the basis of the science of 
 Mechanics shall apply to changes not at first sight mani- 
 festly mechanical. 
 
 The three axioms of causation which we have now 
 stated are the fundamental maxims of all reasoning con- 
 
AXIOMS WHICH RELATE TO THE IDEA OF CAUSE. 185 
 
 cerning causes as to their quantities; and it will be 
 shown in the sequel that these axioms form the basis of 
 the science of Mechanics, determining its form, extent, 
 and certainty. We must, however, in the first place, 
 consider how we acquire those conceptions upon which 
 the axioms now established are to be employed. 
 
 CHAPTER V. 
 
 OF THE ORIGIN OF OUR CONCEPTIONS OF 
 FORCE AND MATTER. 
 
 1. Force. WHEN the faculties of observation and 
 thought are developed in man, the idea of causation is 
 applied to those changes which we see and feel in the 
 state of rest and motion of bodies around us. And 
 when our abstract conceptions are thus formed and 
 named, we adopt the term Force, and use it to 
 denote that property which is the cause of motion pro- 
 duced, changed, or prevented. This conception is, it 
 would seem, mainly and primarily suggested by our 
 consciousness of the exertions by which we put bodies 
 in motion. The Latin and Greek words for Force, Vis, 
 Ftv, were probably, like all abstract terms, derived at 
 first from some sensible object. The original meaning 
 of the Greek word was a muscle or tendon. Its first 
 application as an abstract term is accordingly to muscu- 
 lar force. 
 
 Aeureoos aur' A'/as TroXu pe'i^ova \actv deipa*; 
 IJK' 67nji/)7<ra?, eTreoetcre Se FIN ctTreXcdpov. 
 
 Then Ajax a far heavier stone upheaved, 
 He whirled it, and impressing Force intense 
 Upon the mass, dismist it. 
 
 The property by which bodies affect each other's 
 motions, was naturally likened to that energy which we 
 
186 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 exert upon them with similar effect : and thus the labour- 
 ing horse, the rushing torrent, the descending weight, the 
 elastic bow, were said to exert force. Homer* speaks 
 of the force of the river, Fi? Trorajuolo; and Hesiodf of 
 the force of the north wind, F/s dve^ov fiopeao. 
 
 Thus man's general notion of force was probabl} first 
 suggested by his muscular exertions, that is, by an act 
 depending upon that muscular sense, to which, as we 
 have already seen, the perception of space is mainly due. 
 And this being the case, it will be easily understood that 
 the Direction of the force thus exerted is perceived by 
 the muscular sense, at the same time that the force itself 
 is perceived ; and that the direction of any other force is 
 understood by comparison with force which man must 
 exert to produce the same effect, in the same manner as 
 force itself is so understood. 
 
 This abstract notion of Force long remained in a very 
 vague and obscure condition, as may be seen by referring 
 to the History for the failures of attempts at a science of 
 force and motion, made by the ancients and their com- 
 mentators in the middle ages. By degrees, in modern 
 times, we see the scientific faculty revive. The concep- 
 tion of Force becomes so far distinct and precise that it 
 can be reasoned upon in a consistent manner, with de- 
 monstrated consequences ; and a genuine science of Me- 
 chanics comes into existence. The foundations of this 
 science are to be found in the Axioms concerning causa- 
 tion which we have already stated ; these axioms being 
 interpreted and fixed in their application by a constant 
 reference to observed facts, as we shall show. But we 
 must, in the first place, consider further those primary 
 processes of observation by which we acquire the first 
 materials of thought on such subjects. 
 
 2. Matter. The conception of Force, as we have said, 
 
 * //. xxi. t Op. et D. 
 
ORIGIN OF CONCEPTIONS OF FORCE AND MATTER. 187 
 
 arises with our consciousness of our own muscular exer- 
 tions. But we cannot imagine such exertions without 
 also imagining some bodily substance against which they 
 are exercised. If we press, we press something : if we 
 thrust or throw, there must be something to resist the 
 thrust or to receive the impulse. Without body, mus- 
 cular force cannot be exerted and force in general is not 
 conceivable. 
 
 Thus Force cannot exist without Body on which it 
 acts. The two conceptions, Force and Matter, are co- 
 existent and correlative. Force implies resistance ; and 
 the force is effective only when the resistance is called 
 into play. If we grasp a stone, we have no hold of it 
 till the closing of the hand is resisted by the solid tex- 
 ture of the stone. If we push open a gate, we must 
 surmount the opposition which it exerts while turning 
 on its hinges. However slight the resistance be, there 
 must be some resistance, or there would be no force. 
 If we imagine a state of things in which objects do not 
 resist our touch, they must also cease to be influenced 
 by our strength. Such a state of things we sometimes 
 imagine in our dreams; and such are the poetical pic- 
 tures of the regions inhabited by disembodied spirits. In 
 these, the figures which appear are conspicuous to the 
 eye, but impalpable like shadow or smoke ; and as they 
 do not resist the corporeal impressions, so neither do 
 they obey them. The spectator tries in vain to strike 
 or to grasp them. 
 
 Et ni cana vates tenues sine corpore vitas 
 Admoneat volitare cava sub imagine formas, 
 Irruat ac frustra ferro diverberet umbras. 
 
 The Sibyl warns him that there round him fly 
 Bodiless things, but substance to the eye; 
 Else had he pierced those shapes with life-like face, 
 And smitten, fierce, the unresisting space. 
 
188 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 Neque ilium 
 
 Prensantem nequicquam umbras et multa volentem 
 Dicere, preterea vidit. 
 He grasps her form, and clutches but the shade. 
 
 Such may be the circumstances of the unreal world of 
 dreams, or of poetical fancies approaching to dreams : 
 for in these worlds our imaginary perceptions are bound 
 by no rigid conditions of force and reaction. In such 
 cases, the mind casts off the empire of the idea of cause, 
 as it casts off even the still more familiar sway of the 
 ideas of space and time. But the character of the 
 material world in which we live when awake is, that we 
 have at every instant and at every place, force operating 
 on matter and matter resisting force. 
 
 3. Solidity. From our consciousness of muscular 
 exertion, we derive, as we have seen, the conception of 
 force, and with that also the conception of matter. We 
 have already shown, in a former chapter, that the same 
 part of our frame, the muscular system, is the organ by 
 which we perceive extension and the relations of space. 
 Thus the same organ gives us the perception of body as 
 resisting force, and as occupying space ; and by combin- 
 ing these conditions we have the conception of solid 
 extended bodies. In reality, this resistance is inevitably 
 presented to our notice in the very facts from which we 
 collect the notion of extension. For the action of the 
 hand and arm by which we follow the forms of objects, 
 implies that we apply our fingers to their surface ; and 
 we are stopped there by the resistance which the body 
 offers. This resistance is precisely that which is requisite 
 in order to make us conscious of our muscular effort*. 
 Neither touch, nor any other mere passive sensation, 
 could produce the perception of extent, as we have 
 already urged : nor could the muscular sense lead to such 
 * Brown's Lectures, i. 466. 
 
ORIGIN OF CONCEPTIONS OF FORCE AND MATTER. 189 
 
 a perception, except the extension of the muscles were 
 felt to be resisted. And thus the perception of resistance 
 enters the mind along with the perception of extended 
 bodies. All the objects with which we have to do are 
 not only extended but solid. 
 
 This sense of the term solidity, (the general property 
 of all matter,) is different to that in which we oppose 
 solidity to fluidity. We may avoid ambiguity by op- 
 posing rigid to fluid bodies. By solid bodies, as we now 
 speak of them, we mean only such as resist the pressure 
 which we exert, so long as their parts continue in their 
 places. By fluid bodies, we mean those whose parts are, 
 by a slight pressure, removed out of their places. A drop 
 of water ceases to prevent the contact of our two hands, 
 not by ceasing to have solidity in this sense, but by being 
 thrust out of the way. If it could remain in its place, 
 it could not cease to exercise its resistance to our pres- 
 sure, except by ceasing to be matter altogether. 
 
 The perception of solidity, like the perception of 
 extension, implies an act of the mind, as well as an 
 impression of the senses : as the perception of extension 
 implies the idea of space, so the perception of solidity 
 implies the idea of action and reaction. That an Idea 
 is involved in our knowledge on this subject appears, as 
 in other instances, from this consideration, that the con- 
 victions of persons, even of those who allow of no ground 
 of knowledge but experience, do in fact go far beyond the 
 possible limits of experience. Thus Locke says*, that 
 " the bodies which we daily handle hinder by an insur- 
 mountable force the approach of the parts of our hands 
 that press them." Now it is manifest that our observa- 
 tion can never go to this length. By our senses we can 
 only perceive that bodies resist the greatest actual forces 
 that we exert upon them. But our conception of force 
 
 * Essay, B. n. c. 4. 
 
190 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 carries us further : and since, so long as the body is 
 there to receive the action of the force, it must suffer 
 the whole of that action, and must react as much as 
 it suffers : it is therefore true, that so long as the body 
 remains there, the force which is exerted upon it can 
 never surmount the resistance which the body exercises. 
 And thus this doctrine, that bodies resist the intrusion 
 of other bodies by an insurmountable force, is, in fact, 
 a consequence of the axiom that the reaction is always 
 equal to the action. 
 
 4. Inertia. But this principle of the equality of 
 action and reaction appears also in another way. Not 
 only when we exert force upon bodies at rest, but when, 
 by our exertions, we put them in motion, they react. If 
 we set a large stone in motion, the stone resists ; for the 
 operation requires an effort. By increasing the effort, we 
 can increase the effect, that is, the motion produced ; but 
 the resistance still remains. And the greater the stone 
 moved, the greater is the effort requisite to move it. 
 There is, in every case, a resistance to motion, which shows 
 itself, not in preventing the motion, but in a reciprocal 
 force, exerted backwards upon the agent by which the 
 motion is produced. And this resistance resides in 
 each portion of matter, for it is increased as we add 
 one portion of matter to another. We can push a light 
 boat rapidly through the water ; but we may go on 
 increasing its freight, till we are barely able to stir it. 
 This property of matter, then, by which it resists the 
 reception of motion, or rather by which it reacts and 
 requires an adequate force in order that any motion may 
 result, is called its inertness, or inertia. That matter has 
 such a property, is a conviction flowing from that idea of 
 a reaction equal and opposite to the action, which the 
 conception of all force involves. By what laws this 
 inertia depends on the magnitude, form, and material of 
 
ORIGIN OF CONCEPTIONS OF FORCE AND MATTER. 191 
 
 the body, must be the subject of our consideration here- 
 after. But that matter has this inertia, in virtue of 
 which, as the matter is greater, the velocity which the 
 same effort can communicate to it is less, is a principle 
 inseparable from the notion of matter itself. 
 
 Hermann says that Kepler first introduced this " most 
 significant word" inertia. Whether it is to be found in 
 earlier writers I know not ; Kepler certainly does use it 
 familiarly in those attempts to assign physical reasons 
 for the motions of the planets which were among the 
 main occasions of the discovery of the true laws of me- 
 chanics. He assumes the slowness of the motions of the 
 planets to increase, (other causes remaining the same,) 
 as the inertia increases ; and though, even in this as- 
 sumption, there is ah errour involved, (if we adopt that 
 interpretation of the term inertia to which subsequent 
 researches led,) the introduction of such a word was one 
 step in determining and expressing those laws, of motion 
 which depend on the fundamental principle of the equality 
 of action and reaction. 
 
 5. We have thus seen, I trust in a satisfactory 
 manner, the origin of our conceptions of Force, Matter, 
 Solidity, and Inertness. It has appeared that the organ 
 by which we obtain such conceptions is that very mus- 
 cular frame, which is the main instrument of our percep- 
 tions of space ; but that, besides bodily sensations, these 
 ideal conceptions, like all the others which we have 
 hitherto considered, involve also an habitual activity of 
 the mind, giving to our sensations a meaning which they 
 could not otherwise possess. And among the ideas thus 
 brought into play, is an idea of action with an equal and 
 opposite reaction, which forms a foundation for univer- 
 sal truths to be hereafter established respecting the 
 conceptions thus obtained. 
 
 We must now endeavour to trace in what manner 
 
192 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 these fundamental principles and conceptions are un- 
 folded by means of observation and reasoning, till they 
 become an extensive yet indisputable science. 
 
 CHAPTER VI. 
 
 OF THE ESTABLISHMENT OF THE PRINCIPLES 
 OF STATICS. 
 
 1. Object of the Chapter. IN the present and the 
 succeeding chapters we have to show how the general 
 axioms of Causation enable us to construct the science 
 of Mechanics. We have to consider these axioms as 
 moulding themselves, in the first place, into certain fun- 
 damental mechanical principles, which are of evident 
 and necessary truth in virtue of their dependence upon 
 the general axioms of Causation ; and thus as forming a 
 foundation for the whole structure of the science ; a 
 system of truths no less necessary than the fundamen- 
 tal principles, because derived from these by rigorous 
 demonstration. 
 
 This account of the construction of the science of 
 Mechanics, however generally treated, cannot be other- 
 wise than technical in its details, and will probably be 
 imperfectly understood by any one not acquainted with 
 Mechanics as a mathematical science. 
 
 I cannot omit this portion of my survey without 
 rendering my work incomplete ; but I may remark that 
 the main purpose of it is to prove, in a more particular 
 manner, what I have already declared in general, that 
 there are, in Mechanics no less than in Geometry, funda- 
 mental principles of axiomatic evidence and necessity; 
 that these principles derive their axiomatic character 
 from the Idea which they involve, namely the Idea of 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 193 
 
 Cause ; and that through the combination of principles 
 of this kind, the whole science of Mechanics, including 
 its most complex and remote results, exists as a body of 
 solid and universal truths. 
 
 2. Statics and Dynamics. We must first turn our 
 attention to a technical distinction of Mechanics into 
 two portions, according as the forces about which we 
 reason produce rest, or motion; the former portion is 
 termed Statics, the latter Dynamics. If a stone fall, 
 or a weight put a machine in motion, the problem 
 belongs to Dynamics ; but if the stone rest upon the 
 ground, or a weight be merely supported by a machine, 
 without being raised higher, the question is one of 
 Statics. 
 
 3. Equilibrium. In Statics, forces balance each 
 other, or keep each other in equilibrium. And forces 
 which directly balance each other, or keep each other in 
 equilibrium, are necessarily and manifestly equal. If 
 we see two boys pull at two ends of a rope so that 
 neither of them in the smallest degree prevails over the 
 other, we have a case in which two forces are in equili- 
 brium. The two forces are evidently equal, and are a 
 statical exemplification of action and reaction, such as are 
 spoken of in the third axiom concerning causes. Now 
 the same exemplification occurs in every case of equili- 
 brium. No point or body can be kept at rest except in 
 virtue of opposing forces acting upon it ; and these forces 
 must always be equal in their opposite effect. When a 
 stone lies on the floor, the weight of the stone down- 
 wards is opposed and balanced by an equal pressure of 
 the floor upwards. If the stone rests on a slope, its 
 tendency to slide is counteracted by some equal and 
 opposite force, arising, it may be, from the resistance 
 which the sloping ground opposes to any motion along 
 its surface. Every case of rest is a case of equilibrium : 
 
 VOL. i. w. P. 
 
194 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 every case of equilibrium is a case of equal and opposite 
 forces. 
 
 The most complex frame-work on which weights are 
 supported, as the roof of a building, or the cordage of a 
 machine, are still examples of equilibrium. In such 
 cases we may have many forces all combining to balance 
 each other ; and the equilibrium will depend on various 
 conditions of direction and magnitude among the forces. 
 And in order to understand what are these conditions, 
 we must ask, in the first place, what we understand by 
 the magnitude of such forces ; what is the measure of 
 statical forces. 
 
 4. Measure of Statical Forces. At first we might 
 expect, perhaps, that since statical forces come under the 
 general notion of Cause, the mode of measuring them 
 would be derived from the second axiom of Causation, 
 that causes are measured by their effects. But we find 
 that the application of this axiom is controlled by the 
 limitation which we noticed, after stating that axiom ; 
 namely, the condition that the causes shall be capable of 
 addition. Further, as we have seen, a statical force pro- 
 duces no other effect than this, that it balances some 
 other statical force ; and hence the measure of statical 
 forces is necessarily dependent upon their balancing, 
 that is, upon the equality of action and reaction. 
 
 That statical forces are capable of addition is involved 
 in our conception of such forces. When two men pull 
 at a rope in the same direction, the forces which they 
 exert are added together. When two heavy bodies are 
 put into a basket suspended by a string, their weights 
 are added, and the sum is supported by the string. 
 
 Combining these considerations, it will appear that 
 the measure of statical forces is necessarily given at once 
 by the fundamental principle of the equality of action 
 and reaction. Since two opposite forces which balance 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 195 
 
 each other are equal, each force is measured by that 
 which it balances ; and since forces are capable of addi- 
 tion, a force of any magnitude is measured by adding to- 
 gether a proper number of such equal forces. Thus a 
 heavy body which, appended to some certain elastic 
 branch of a tree, would bend it down through one inch, 
 may be taken as a unit of weight. Then if we remove 
 this first body, and find a second heavy body which will 
 also bend the branch through the same space, this is also 
 a unit of weight ; and in like manner we might go on to 
 a third and a fourth equal body; and adding together 
 the two, or the three, or the four heavy bodies, we have 
 a force twice, or three times, or four times the unit of 
 weight. And with such a collection of heavy bodies, or 
 weights, we can readily measure all other forces ; for the 
 same principle of the equality of action and reaction 
 leads at once to this maxim, that any statical force is 
 measured by the weight which it would support. 
 
 As has been said, it might at first have been sup- 
 posed that we should have to apply, in this case, the 
 axiom that causes are measured by their effects in an- 
 other manner; that thus, if that body were a unit of 
 weight which bent the bough of a tree through one inch, 
 that body would be two units which bent it through two 
 inches, and so on. But, as we have already stated, the 
 measures of weight must be subject to this condition, 
 that they are susceptible of being added : and therefore 
 we cannot take the deflexion of the bough for our mea- 
 sure, till we have ascertained, that which experience 
 alone can teach us, that under the burden of two equal 
 weights, the deflexion will be twice as great as it is with 
 one weight, which is not true, or at least is neither ob- 
 viously nor necessarily true. In this, as in all other cases, 
 although causes must be measured by their effects, we 
 learn from experience only how the effects are to be 
 
 o 2 
 
196 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 interpreted, so as to give a true and consistent mea- 
 sure. 
 
 With regard, however, to the measure of statical 
 force, and of weight, no difficulty really occurred to phi- 
 losophers from the time when they first began to specu- 
 late on such subjects ; for it was easily seen that if we 
 take any uniform material, as wood, or stone, or iron, 
 portions of this which are geometrically equal, must also 
 be equal in statical effect ; since this was implied in the 
 very hypothesis of a uniform material. And a body ten 
 times as large as another of the same substance, will be 
 of ten times the weight. But before men could esta- 
 blish by reasoning the conditions under which weights 
 would be in equilibrium, some other principles were 
 needed in addition to the mere measure of forces. The 
 principles introduced for this purpose still resulted from 
 the conception of equal action and reaction ; but it re- 
 quired no small clearness of thought to select them 
 rightly, and to employ them successfully. This, however, 
 was done, to a certain extent, by the Greeks; and the 
 treatise of Archimedes On the Center of Gravity, is 
 founded on principles which may still be considered as 
 the genuine basis of statical reasoning. I shall make a 
 few remarks on the most important principle among 
 those which Archimedes thus employs. 
 
 5. The Center of Gravity. The most important of 
 the principles which enter into the demonstration of 
 Archimedes is this : that " Every body has a center of 
 gravity ;" meaning by the center of gravity, a point at 
 which the whole matter of the body may be supposed to 
 be collected, to all intents and purposes of statical 
 reasoning. This principle has been put in various forms 
 by succeeding writers : for instance, it has been thought 
 sufficient to assume a case much simpler than the general 
 one; and to assert that two equal bodies have their 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 107 
 
 center of gravity in the point midway between them. It 
 is to be observed, that this assertion not only implies 
 that the two bodies will balance upon a support placed 
 at that midway point, but also, that they will exercise, 
 upon such a support, a pressure equal to their sum ; 
 for this point being the center of gravity, the whole 
 matter of the two bodies may be conceived to be col- 
 lected there, and therefore the whole weight will press 
 there. And thus the principle in question amounts to 
 this, that when two equal heavy bodies are supported on 
 the middle point between them, the pressure upon the 
 support is equal to the sum of the weights of the bodies. 
 
 A clear understanding of the nature and grounds of 
 this principle is of great consequence : for in it we have 
 the foundation of a large portion of the science of 
 Mechanics. And if this principle can be shown to be 
 necessarily true, in virtue of our Fundamental Ideas, we 
 can hardly doubt that there exist many other truths of 
 the same kind, and that no sound view of the evidence 
 and extent of human knowledge can be obtained, so long- 
 as we mistake the nature of these, its first principles. 
 
 The above principle, that the pressure on the support 
 is equal to the sum of the bodies supported, is often 
 stated as an axiom in the outset of books on Mechanics. 
 And this appears to be the true place and character of 
 this principle, in accordance with the reasonings which 
 we have already urged. The axiom depends upon our 
 conception of action and reaction. That the two weights 
 are supported, implies that the supporting force must be 
 equal to the force or weight supported. 
 
 In order further to show the foundation of this 
 principle, we may ask the question : If it be not an 
 axiom, deriving its truth from the fundamental concep- 
 tion of equal action and reaction, which equilibrium 
 always implies, what is the origin of its certainty ? The 
 
198 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 principle is never for an instant denied or questioned: it is 
 taken for granted, even before it is stated. No one will 
 doubt that it is not only true, but true with the same 
 rigour and universality as the axioms of Geometry. Will 
 it be said, that it is borrowed from experience ? Expe- 
 rience could never prove a principle to be universally 
 and rigorously true. Moreover, when from experience 
 we prove a proposition to possess great exactness and 
 generality, we approach by degrees to this proof: the 
 conviction becomes stronger, the truth more secure, as 
 we accumulate trials. But nothing of this kind is the 
 case in the instance before us. There is no gradation 
 from less to greater certainty; no hesitation which 
 precedes confidence. From the first, we know that the 
 axiom is exactly and certainly true. In order to be 
 convinced of it, we do not require many trials, but 
 merely a clear understanding of the assertion itself. 
 
 But in fact, not only are trials not necessary to the 
 proof, but they do not strengthen it. Probably no 
 one ever made a trial for the purpose of showing that 
 the pressure upon the support is equal to the sum of the 
 two weights. Certainly no person with clear mechanical 
 conceptions ever wanted such a trial to convince him of 
 the truth ; or thought the truth clearer after the trial 
 had been made. If to such a person, an experiment 
 were shown which seemed to contradict the principle, his 
 conclusion would be, not that the principle was doubtful, 
 but that the apparatus was out of order. Nothing can 
 be less like collecting truth from experience than this. 
 
 We maintain, then, that this equality of mechanical 
 action and reaction, is one of the principles which do 
 not flow from, but regulate our experience. To this 
 principle, the facts which we observe must conform ; 
 and we cannot help interpreting them in such a manner 
 that they shall be exemplifications of the principle. A 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 199 
 
 mechanical pressure not accompanied by an equal and 
 opposite pressure, can no more be given by experience, 
 than two unequal right angles. With the supposition of 
 such inequalities, space ceases to be space, force ceases to 
 be force, matter ceases to be matter. And this equality 
 of action and reaction, considered in the case in which 
 two bodies are connected so as to act on a single support, 
 leads to the axiom which we have stated above, and 
 which is one of the main foundations of the science of 
 Mechanics. 
 
 6. Oblique Forces. By the aid of this axiom and 
 a few others, the Greeks made some progress in the 
 science of Statics. But after a short advance, they 
 arrived at another difficulty, that of Oblique Forces, 
 which they never overcame; and which no mathematician 
 mastered till modern times. The unpublished manuscripts 
 of Leonardo da Vinci, written in the fifteenth century, 
 and the works of Stevinus and Galileo, in the sixteenth, 
 are the places in which we find the first solid grounds of 
 reasoning on the subject of forces acting obliquely to 
 each other. And mathematicians, having thus become 
 possessed of all the mechanical principles which are 
 requisite in problems respecting equilibrium, soon framed 
 a complete science of Statics. Succeeding writers pre- 
 sented this science in forms variously modified; for it 
 was found, in Mechanics as in Geometry, that various 
 propositions might be taken as the starting points ; and 
 that the collection of truths which it was the mecha- 
 nician's business to include in his course, might thus be 
 traversed by various routes, each path offering a series 
 of satisfactory demonstrations. The fundamental con- 
 ceptions of force and resistance, like those of space and 
 number, could be contemplated under different aspects, 
 each of which might be made the basis of axioms, 
 or of principles employed as axioms. Hence the 
 
200 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 grounds of the truth of Statics may be stated in various 
 ways ; and it would be a task of some length to examine 
 all these completely, and to trace them to their Funda- 
 mental Ideas. This I shall not undertake here to do ; 
 but the philosophical importance of the subject makes 
 it proper to offer a few remarks on some of the main 
 principles involved in the different modes of presenting 
 Statics as a rigorously demonstrated science. 
 
 7. A Force may be supposed to act at any Point of its 
 Direction. It has been stated in the history of Mecha- 
 nics*, that Leonardo da Vinci and Galileo obtained the 
 true measure of the effect of oblique forces, by reason- 
 ings which were, in substance, the same. The principle 
 of these reasonings is that expressed at the head of this 
 paragraph ; and when we have a little accustomed our- 
 selves to contemplate our conceptions of force, and its 
 action on matter, in an abstract manner, we shall have 
 no difficulty in assenting to the principle in this general 
 form. But it may, perhaps, be more obvious at first in 
 a special case. 
 
 If we suppose a wheel, moveable about its axis, and 
 carrying with it in its motion a weight, (as, for example, 
 one of the wheels by means of which the large bells of a 
 church are rung,) this weight may be supported by means 
 of a rope (not passing along the circumference of the 
 wheel, as is usual in the case of bells,) but fastened to 
 one of the spokes of the wheel. Now the principle which 
 is enunciated above asserts, that if the rope pass in a 
 straight line across several of the spokes of the wheel, it 
 makes no difference in the mechanical effect of the force 
 applied, for the purpose of putting the bell in motion, to 
 which of these spokes the rope \& fastened. In each case, 
 the fastening of the rope to the wheel merely serves to 
 enable the force to produce motion about the centre ; 
 
 * Hist. Ind. Set., B. vi. c. i. sect. 2. and Note (A). 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 201 
 
 and so long as the force acts in the same line, the effect 
 is the same, at whatever point of the rope the line of 
 action finishes. 
 
 This axiom very readily aids us in estimating the 
 effect of oblique forces. For when a force acts on one of 
 the arms of a lever at any oblique angle, we suppose 
 another arm projecting from the centre of motion, like 
 another spoke of the same wheel, so situated that it is 
 perpendicular to the force. This arm we may, with 
 Leonardo, call the virtual lever ; for, by the axiom, we 
 may suppose the force to act where the line of its direc- 
 tion meets this arm; and thus we reduce the case to 
 that in which the force acts perpendicularly on the arm. 
 
 The ground of this axiom is, that matter, in Statics, 
 is necessarily conceived as transmitting force. That force 
 can be transmitted from one place to another, by means 
 of matter ; that we can push with a rod, pull with a 
 rope, are suppositions implied in our conceptions of 
 force and matter. Matter is, as we have said, that which 
 receives the impression of force, and the modes just 
 mentioned, are the simplest ways in which that impres- 
 sion operates. And since, in any of these cases, the force 
 might be resisted by a reaction equal to the force itself, 
 the reaction in each case would be equal, and, therefore, 
 the action in each case is necessarily equal ; and thus the 
 forces must be transmitted, from one point to another, 
 without increase or diminution. 
 
 This property of matter, of transmitting the action of 
 force, is of various kinds. We have the coherence of a 
 rope which enables us to pull, and the rigidity of a staff, 
 which enables us to push with it in the direction of its 
 length ; and again, the same staff has a rigidity of another 
 kind, in virtue of which we can use it as a lever ; that is, a 
 rigidity to resist flexure, and to transmit the force which 
 turns a body round a fulcrum. There is, further, the 
 
202 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 rigidity by which a solid body resists twisting. Of these 
 kinds of rigidity, the first is that to which our axiom 
 refers ; but in order to complete the list of the ele- 
 mentary principles of Statics, we ought also to lay down 
 axioms respecting the other kinds of rigidity*. These, 
 however, I shall not here state, as they do not involve 
 any new principle. Like the one just considered, they 
 form part of our fundamental conception of matter ; they 
 are not the results of any experience, but are the hypo- 
 theses to which we are irresistibly led, when we would 
 liberate our reasonings concerning force and matter from 
 a dependence on the special results of experience. We 
 cannot even conceive (that is, if we have any clear 
 mechanical conceptions at all) the force exerted by the 
 point of a staff and resisting the force which we steadily 
 impress on the head of it, to be different from the 
 impressed force. 
 
 8. Forces may have equivalent Forces substituted for 
 them. The Parallelogram of Forces. It has already been 
 observed, that in order to prove the doctrines of Statics, 
 we may take various principles as our starting points, 
 and may still find a course of demonstration by which 
 the leading propositions belonging to the subject may 
 be established. Thus, instead of beginning our reason- 
 ings, as in the last section we supposed them to 
 commence, with the case in which forces act upon 
 different points of the same body in the same line of 
 force, and counteract each other in virtue of the inter- 
 vening matter by which the effect of force is transferred 
 from one point to another, we may suppose different 
 forces to act at the same point, and may thus commence 
 our reasonings with a case in which we have to con- 
 template force, without having to take into our account 
 
 * Such axioms are given in a little work (The Mechanical Euclid} 
 which I published on the Elements of Mechanics. 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 203 
 
 the resistance or rigidity of matter. Two statical forces, 
 thus acting at a mathematical point, are equivalent, in 
 all respects, to some single force acting at the same point; 
 and would be kept in equilibrium by a force equal and 
 opposite to that single force. And the rule by which 
 the single force is derived from the two, is commonly 
 termed the parallelogram of forces; the proposition being 
 this, That if the two forces be represented in magnitude 
 and direction by the two sides of a parallelogram, the 
 resulting force will be represented in the same manner 
 by the diagonal of the parallelogram. This proposition 
 has very frequently been made, by modern writers, the 
 commencement of the science of Mechanics : a position 
 for which, by its simplicity, it is well suited; although, 
 in order to deduce from it the other elementary proposi- 
 tions of the science, as, for instance, those respecting the 
 lever, we require the axiom stated in the last section. 
 
 9. The Parallelogram of Forces is a necessary Truth. 
 In the series of discussions in which we are here 
 engaged, our main business is to ascertain the nature and 
 grounds of the certainty of scientific truths. We have, 
 therefore, to ask whether this proposition, the parallelo- 
 gram of forces, be a necessary truth ; and if so, on what 
 grounds its necessity ultimately rests. We shall find 
 that this, like the other fundamental doctrines of Statics, 
 justly claims a demonstrative certainty. Daniel Ber- 
 noulli, in 1726, gave the first proof of this important 
 proposition on pure statical principles; and thus, as he 
 says*, "proved that statical theorems are not less 
 necessarily true than geometrical are." If we examine 
 this proof of Bernoulli, in order to discover what are 
 the principles on which it rests, we shall find that the 
 reasoning employs in its progress such axioms as this ; 
 That if from forces which are in equilibrium at a point 
 
 * Comm. Pctrop. Vol. i. 
 
204 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 be taken away other forces which are in equilibrium at 
 the same point, the remainder will be in equilibrium; 
 and generally ; That if forces can be resolved into other 
 equivalent forces, these may be separated, grouped, and 
 recombined, in any new manner, and the result will still 
 be identical with what it was at first. Thus in Ber- 
 noulli's proof, the two forces to be compounded are repre- 
 sented by P and Q ; p is resolved into two other forces, x 
 and u ; and Q into two others, Y and v, under certain 
 conditions. It is then assumed that these forces may be 
 grouped into the pairs x, Y, and u, v : and when it has 
 been shown that x and Y are in equilibrium, they may, by 
 what has been said, be removed, and the forces, P, Q, are 
 equivalent to u, v; which, being in the same direction 
 by the course of the construction, have a result equal to 
 their sum. 
 
 It is clear that the principles here assumed are 
 genuine axioms, depending upon our conception of the 
 nature of equivalence of forces, and upon their being 
 capable of addition and composition. If the forces P, Q, 
 be equivalent to forces x, u, Y, v, they are equivalent to 
 these forces added and compounded in any order ; just 
 as a geometrical figure is, by our conception of space, 
 equivalent to its parts added together in any order. The 
 apprehension of forces as having magnitude, as made 
 up of parts, as capable of composition, leads to such 
 axioms in Statics, in the same manner as the like 
 apprehension of space leads to the axioms of Geometry. 
 And thus the truths of Statics, resting upon such founda- 
 tions, are independent of experience in the same manner 
 in which geometrical truths are so. 
 
 The proof of the parallelogram of forces thus given 
 by Daniel Bernoulli, as it was the first, is also one of 
 the most simple proofs of that .proposition which have 
 been devised up to the present day. Many other demon- 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 205 
 
 strations, however, have been given of the same proposi- 
 tion. Jacobi, a German mathematician, has collected 
 and examined eighteen of these"''". They all depend 
 either upon such principles as have just been stated ; 
 That forces may in every way be replaced by those which 
 are equivalent to them ; or else upon those previously 
 stated, the doctrine of the lever, and the transfer of a 
 force from one point to another of its direction. In 
 either case, they are necessary results of our statical con-, 
 ceptions, independent of any observed laws of motion, 
 and indeed, of the conception of actual motion altogether. 
 There is another class of alleged proofs of the paral- 
 lelogram of forces, which involve the consideration of 
 the motion produced by the forces. But such reasonings 
 are, in fact, altogether irrelevant to the subject of Statics. 
 In that science, forces are not measured by the motion 
 which they produce, but by the forces which they will 
 balance, as we have already seen. The combination of 
 two forces employed in producing motion in the same 
 body, either simultaneously or successively, belongs to 
 that part of Mechanics which has motion for its subject, 
 and is to be considered in treating of the laws of motion. 
 The composition of motion, (as when a man moves in a 
 ship while the ship moves through the water,) has con- 
 stantly been confounded with the composition of force. 
 But though it has been done by very eminent mathe- 
 maticians, it is quite necessary for us to keep the two 
 subjects distinct, in order to see the real nature of the 
 evidence of truth in either case. The conditions of equi- 
 librium of two forces on a lever, or of three forces at 
 
 * These are by the following mathematicians; D. Bernoulli 
 (1726); Lambert (1771); Scarella (1756); Yenini (1764); Araldi 
 (1806); Wachter (1815); Ksestiier ; Marini; Eytelwein ; Salimbeni ; 
 Duchayla; two different proofs by Foncenex (1760); three by 
 D'Alembert; and those of Laplace and M. Poisson. 
 
206 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 a point, can be established without any reference what- 
 ever to any motions which the forces might, under other 
 circumstances, produce. And because this can be done, 
 to do so is the only scientific procedure. To prove such 
 propositions by any other course, would be to support 
 truth by extraneous and inconclusive reasons; which 
 would be foreign to our purpose, since we seek not only 
 knowledge, but the grounds of our knowledge. 
 
 10. The Center of gravity seeks the lowest place. 
 The principles which we have already mentioned afford 
 a sufficient basis for the science of Statics in its most 
 extensive and varied applications ; and the conditions of 
 equilibrium of the most complex combinations of ma- 
 chinery may be deduced from these principles with a 
 rigour not inferior to that of geometry. But in some of 
 the more complex cases, the results of long trains of 
 reasoning may be foreseen, in virtue of certain maxims 
 which appear to us self-evident, although it may not be 
 easy to trace the exact dependence of these maxims upon 
 our fundamental conceptions of force and matter. Of 
 this nature is the maxim now stated ; That in any com- 
 bination of matter any how supported, the Center of 
 Gravity will descend into the lowest position which the 
 connexion of the parts allows it to assume by descend- 
 ing. It is easily seem that this maxim carries to a much 
 greater extent the principle which the Greek mathe- 
 maticians assumed, that every body has a Center of 
 Gravity, that is, a point in which, if the whole matter of 
 the body be collected, the effect will remain unchanged. 
 For the Greeks asserted this of a single rigid mass only ; 
 whereas, in the maxim now under our notice, it is asserted 
 of any masses, connected by strings, rods, joints, or in 
 any manner. We have already seen that more modern 
 writers on mechanics, desirous of assuming as funda- 
 mental no wider principles than are absolutely necessary, 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 207 
 
 have not adopted the Greek axiom in all its generality, 
 but have only asserted that two equal weights have a 
 center of gravity midway between them. Yet the prin- 
 ciple that every body, however irregular, has a center of 
 gravity, and will be supported if that center is supported, 
 and not otherwise, is so far evident, that it might be 
 employed as a fundamental truth, if we could not resolve 
 it into any simpler truths : and, historically speaking, it 
 was assumed as evident by the Greeks. In like manner 
 the still wider principle, that a collection of bodies, as, 
 for instance, a flexible chain hanging upon one or more 
 supports, has a center of gravity ; and that this point 
 will descend to the lowest possible situation, as a single 
 body would do, has been adopted at various periods in 
 the history of mechanics ; and especially at conjunctures 
 when mathematical philosophers have had new and dif- 
 ficult problems to contend with. For in almost every 
 instance it has only been by repeated struggles that phi- 
 losophers have reduced the solution of such problems to 
 a clear dependence upon the most simple axioms. 
 
 11. Stevinuss Proof for Oblique Forces. We have 
 an example of this mode of dealing with problems, in 
 Stevinus's mode of reasoning concerning the Inclined 
 Plane ; which, as we have stated in the History of Me- 
 chanics, was the first correct published solution of that 
 problem. Stevinus supposes a loop of chain, or a loop 
 of string loaded with a series of equal balls at equal dis- 
 tances, to hang over the Inclined Plane ; and his reason- 
 ing proceeds upon this assumption, That such a loop 
 so hanging will find a certain position in which it will 
 rest : for otherwise, says he*, its motion must go on for 
 ever, which is absurd. It may be asked how this absurd- 
 ity of a perpetual motion appears ; and it will perhaps 
 be added, that although the impossibility of a machine 
 * Stevin. Statique, Livre i., prop. 19. 
 
208 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 with such a condition may be proved as a remote result 
 of mechanical principles, this impossibility can hardly 
 be itself recognized as a self-evident truth. But to this 
 we may reply, that the impossibility is really evident in 
 the case contemplated by Stevinus ; for we cannot con- 
 ceive a loop of chain to go on through all eternity, slid- 
 ing round and round upon its support, by the effect of 
 its own weight. And the ground of our conviction that 
 this cannot be, seems to be this consideration; that when 
 the chain moves by the effect of its weight, we consider 
 its motion as the result of an effort to reach some certain 
 position, in which it can rest ; just as a single ball in 
 a bowl moves till it comes to rest at the lowest point 
 of the bowl. Such an effect of weight in the chain, we 
 may represent to ourselves by conceiving all the matter 
 of the chain to be collected in one single point, and this 
 single heavy point to hang from the support in some way 
 or other, so as fitly to represent the mode of support of 
 the chain. In whatever manner this heavy point (the 
 center of gravity of the chain) be supported and con- 
 trolled in its movements, there will still be some position 
 of rest which it will seek and find. And thus there will 
 be some corresponding position of rest for the chain ; and 
 the interminable shifting from one position to another, 
 with no disposition to rest in any position, cannot exist. 
 
 Thus the demonstration of the property of the 
 Inclined Plane by Stevinus, depends upon a principle 
 which, though far from being the simplest of those to 
 which the case can be reduced, is still both true and 
 evident : and the evidence of this principle, depending 
 upon the assumption of a center of gravity, is of the 
 same nature as the evidence of the Greek statical demon- 
 strations, the earliest real advances in the science. 
 
 12. Principle of Virtual Velocities. We have 
 referred above to an assertion often made, that we 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS, 209 
 
 may, from the simple principles of Mechanics, demon- 
 strate the impossibility of a perpetual motion. In reality, 
 however, the simplest proof of that impossibility, in 
 a machine acted upon by weight only, arises from the 
 very maxim above stated, that the center of gravity seeks 
 and finds the lowest place ; or from some similar propo- 
 sition. For if, as is done by many writers, we profess 
 to prove the impossibility of a perpetual motion by means 
 of that proposition which includes the conditions of equi- 
 librium, and is called the Principle of Virtual Velocities*, 
 we are under the necessity of first proving in a general 
 manner that principle. And if this be done by a mere 
 enumeration of cases, (as by taking those five cases which 
 are called the Mechanical Powers,} there may remain 
 some doubts whether the enumeration of possible mecha- 
 nical combinations be complete. Accordingly, some writers 
 have attempted independent and general proofs of the 
 Principle of Virtual Velocities; and these proofs rest 
 upon assumptions of the same nature as that now under 
 notice. This is, for example, the case with Lagrange's 
 proof, which depends upon what he calls the Principle 
 of Pulleys. For this principle is, That a weight any 
 how supported, as by a string passing round any number 
 of pulleys any how placed, will be at rest then only, 
 when it cannot get lower by any small motion of the 
 pulleys. And thus the maxim that a weight will descend 
 if it can, is assumed as the basis of this proof. 
 
 There is, as we have said, no need to assume such 
 principles as these for the foundation of our mechanical 
 science. But it is, on various accounts, useful to direct 
 our attention to those cases in which truths, apprehended 
 at first in a complex and derivative form, have after- 
 wards been reduced to their simpler elements ; in which, 
 also, sagacious and inventive men have fixed upon those 
 
 * See Hist. Ind. Sci., B. vi. c. ii. sect. 4. 
 VOL. I. W. P. P 
 
210 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 truths as self-evident, which now appear to us only cer- 
 tain in virtue of demonstration. In these cases we can 
 hardly doubt that such men were led to assert the 
 doctrines which they discovered, not by any capricious 
 conjecture or arbitrary selection, but by having a keener 
 and deeper insight than other persons into the relations 
 which were the object of their contemplation; and in the 
 science now spoken of, they were led to their assump- 
 tions by possessing clearly and distinctly the conceptions 
 of mechanical cause and effect, action and reaction. 
 force, and the nature of its operation. 
 
 13. Fluids press Equally in all Directions. The 
 doctrines which concern the equilibrium of fluids depend 
 on principles no less certain and simple than those which 
 refer to the equilibrium of solid bodies ; and the Greeks, 
 who, as we have seen, obtained a clear view of some of 
 the principles of Statics, also made a beginning in the 
 kindred subject of Hydrostatics. We still possess a trea- 
 tise of Archimedes On Floating Bodies, which contains 
 correct solutions of several problems belonging to this 
 subject, and of some which are by no means easy. In 
 this treatise, the fundamental assumption is of this kind : 
 "Let it be assumed that the nature of a fluid is such, 
 that the parts which are less pressed yield to those which 
 are more pressed." In this assumption or axiom it is 
 implied that a pressure exerted upon a fluid in one direc- 
 tion produces a pressure in another direction ; thus, the 
 weight of the fluid which arises from a downward force 
 produces a lateral pressure against the sides of the con- 
 taining vessel. Not only does the pressure thus diverge 
 from its original direction into all other directions, but the 
 pressure, is in all directions exactly equal, an equal extent 
 of the fluid being taken. This principle, which was in- 
 volved in the reasoning of Archimedes, is still to the 
 present day the basis of all hydrostatical treatises, and is 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 211 
 
 expressed, as above, by saying that fluids press equally 
 in all directions. 
 
 Concerning this, as concerning previously-noticed 
 principles, we have to ask whether it can rightly be said 
 to be derived from experience. And to this the answer 
 must still be, as in the former cases, that the proposition 
 is not one borrowed from experience in any usual or 
 exact sense of the phrase. I will endeavour to illustrate 
 this. There are many elementary propositions in phy- 
 sics, our knowledge of which indisputably depends upon 
 experience ; and in these cases there is no difficulty in 
 seeing the evidence of this dependence. In such cases, 
 the experiments which prove the law are prominently 
 stated in treatises upon the subject : they are given with 
 exact measures, and with an account of the means by 
 which errors were avoided : the experiments of more 
 recent times have either rendered more certain the law 
 originally asserted, or have pointed out some correction 
 of it as requisite : and the names, both of the discoverers 
 of the law and of its subsequent reformers, are well 
 known. For instance, the proposition that " The elastic 
 force of air varies as the density," was first proved by 
 Boyle, by means of operations of which the detail is given 
 in his Defence of his Pneumatical Experiments* ; and 
 by Marriotte in his Traite de rEquilibre des Liquides, 
 from whom it has generally been termed Marriotte's law. 
 After being confirmed by many other experimenters, 
 this law was suspected to be slightly inaccurate, and a 
 commission of the French Academy of Sciences was 
 appointed, consisting of several distinguished philoso- 
 phersf, to ascertain the truth or falsehood of this suspicion. 
 
 * Shaw's Boyle, Vol. n. p. 671. 
 
 t The members were Prony, Arago, Ampere, Girard, and Dulong. 
 The experiments were extended to a pressure of twenty-seven atmo- 
 spheres; and in no instance did the difference between the observed 
 
 P2 
 
212 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 The result of their investigations appeared to be, that 
 the law is exact, as nearly as the inevitable inaccuracies 
 of machinery and measures will allow us to judge. Here 
 we have an example of a law which is of the simplest 
 kind and form ; and which yet is not allowed to rest 
 upon its simplicity or apparent probability, but is rigor- 
 ously tested by experience. In this case, the assertion, 
 that the law depends upon experience, contains a refer- 
 ence to plain and notorious passages in the history of 
 science. 
 
 Now with regard to the principle that fluids press 
 equally in all directions, the case is altogether different. 
 It is, indeed, often asserted in works on hydrostatics, 
 that the principle is collected from experience, and some- 
 times a few experiments are described as exhibiting its 
 effect ; but these are such as to illustrate and explain, 
 rather than to prove, the truth of the principle : they 
 are never related to have been made with that exact- 
 ness of precaution and measurement, or that frequency 
 of repetition, which are necessary to establish a purely 
 experimental truth. Nor did such experiments occur as 
 important steps in the history of science. It does not 
 appear that Archimedes thought experiment necessary 
 to confirm the truth of the law as he employed it : on 
 the contrary, he states it in exactly the same shape as 
 the axioms which he employs in statics, and even in geo- 
 metry ; namely, as an assumption. Nor does any intel- 
 ligent student of the subject find any difficulty in assent- 
 ing to this fundamental principle of hydrostatics as soon 
 as it is propounded to him. Experiment was not requi- 
 site for its discovery; experiment is not necessary for 
 its proof at present ; and we may add, that experiment, 
 
 and calculated elasticity amount to one-hundredth of the whole; nor 
 did the difference appear to increase with the increase of pressure. 
 Fechner, Repertorium, i. 1 10. 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 213 
 
 though it may make the proposition more readily intelli- 
 gible, can add nothing to our conviction of its truth 
 when it is once understood. 
 
 14. Foundation of the above Axiom. But it will 
 naturally be asked, What then is the ground of our 
 conviction of this doctrine of the equal pressure of a 
 fluid in all directions? And to this I reply, that the 
 reasons of this conviction are involved in our idea of a 
 fluid, which is considered as matter, and therefore as 
 capable of receiving, resisting, and transmitting force 
 according to the general conception of matter ; and which 
 is also considered as matter which has its parts perfectly 
 moveable among one another. For it follows from 
 these suppositions, that if the fluid be confined, a pres- 
 sure which thrusts in one side of the containing vessel, 
 may cause any other side to bulge outwards, if there be 
 a part of the surface which has not strength to resist 
 this pressure from within. And that this pressure, when 
 thus transferred into a direction different from the ori- 
 ginal one, is not altered in intensity, depends upon this 
 consideration ; that any difference in the two pressures 
 would be considered as a defect of perfect fluidity, since 
 the fluidity would be still more complete, if this entire 
 and undiminished transmission of pressure in all direc- 
 tions were supposed. If, for instance, the lateral pres- 
 sure were less than the vertical, this could be conceived 
 no other way than as indicating some rigidity or adhesion 
 of the parts of the fluid. When the fluidity is perfect, 
 the two pressures which act in the two different parts of 
 the fluid exactly balance each other : they are the action 
 and the reaction; and must hence be equal by the same 
 necessity as two directly opposite forces in statics. 
 
 But it may be urged, that even if we grant that this 
 conception of a perfect fluid, as a body which has its 
 parts perfectly moveable among each other, leads us 
 
214 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 necessarily to the principle of the equality of hydrostatic 
 pressure in all directions, still thrs conception itself is 
 obtained from experience, or suggested by observation. 
 And to this we may reply, that the conception of a fluid, 
 as contemplated in mechanical theory, cannot be said to 
 be derived from experience, except in the same manner 
 as the conception of a solid and rigid body may be said 
 to be acquired by experience. For if we imagine a 
 vessel full of small, smooth spherical balls, such a collec- 
 tion of balls would approach to the nature of a fluid, in 
 having its parts moveable among each other ; and would 
 approach to perfect fluidity, as the balls became 
 smoother and smaller. And such a collection of balls 
 would also possess the statical properties of a fluid ; for 
 it would transmit pressure out of a vertical into a lateral 
 (or any other) direction, in the same manner as a fluid 
 would do. And thus a collection of solid bodies has 
 the same property which a fluid has; and the science 
 of Hydrostatics borrows from experience no principles 
 beyond those which are involved in the science of 
 Statics respecting solids. And since in this latter por- 
 tion of science, as we have already seen, none of the 
 principles depend for their evidence upon any special 
 experience, the doctrines of Hydrostatics also are not 
 proved by experience, but have a necessary truth bor- 
 rowed from the relations of our ideas. 
 
 It is hardly to be expected that the above reasoning 
 will, at first sight, produce conviction in the mind of the 
 reader, except he have, to a certain extent, acquainted 
 himself with the elementary doctrines of the science of 
 Hydrostatics as usually delivered; and have followed, 
 with clear and steady apprehension, some of the trains 
 of reasoning by which the pressures of fluids are deter- 
 mined ; as, for instance, the explanation of what is called 
 the Hydrostatic, Paradox. The necessity of such a dis- 
 
ESTABLISHMENT OF THE PRINCIPLES OF STATICS. 215 
 
 cipline in order that the reader may enter fully into this 
 part of our speculations, naturally renders them less 
 popular ; but this disadvantage is inevitable in our plan. 
 We cannot expect to throw light upon philosophy by 
 means of the advances which have been made in the 
 mathematical and physical sciences, except we really 
 understand the doctrines which have been firmly esta- 
 blished in those sciences. This preparation for philoso- 
 phizing may be somewhat laborious ; but such labour is 
 necessary if we would pursue speculative truth with all 
 the advantages which the present condition of human 
 knowledge places within our reach. 
 
 We may add, that the consequences to which we are 
 directed by the preceding opinions, are of very great im- 
 portance in their bearing upon our general views respect- 
 ing human knowledge. I trust to be able to show, that 
 some important distinctions are illustrated, some per- 
 plexing paradoxes solved, and some large anticipations 
 of the future extension of our knowledge suggested, by 
 means of the conclusions to which the preceding discus- 
 sions have conducted us. But before I proceed to these 
 general topics, I must consider the foundations of some 
 of the remaining portions of Mechanics. 
 
 CHAPTER VII. 
 
 OF THE ESTABLISHMENT OF THE PRINCIPLES 
 OF DYNAMICS. 
 
 1. IN the History of Mechanics, I have traced the 
 steps by which the three Laws of Motion and the other 
 principles of mechanics were discovered, established, and 
 extended to the widest generality of form and applica- 
 tion. We have, in these laws, examples of principles 
 which were, historically speaking, obtained by reference 
 
216 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 to experience. Bearing in mind the object and the re- 
 sult of the preceding discussions, we cannot but turn 
 with much interest to examine these portions of science ; 
 to inquire whether there be any real difference in the 
 grounds and nature between the knowledge thus ob- 
 tained, and those truths which we have already contem- 
 plated; and which, as we have seen, contain their own 
 evidence, and do not require proof from experiment. 
 
 2. The First Law of Motion. The first law of mo- 
 tion is, that When a body moves not acted upon ~by any 
 force, it mill go on perpetually in a straight line, and 
 with a uniform velocity. Now what is the real ground 
 of our assent to this proposition ? That it is not at first 
 sight a self-evident truth, appears to be clear ; since from 
 the time of Aristotle to that of Galileo the opposite 
 assertion was held to be true ; and it was believed that 
 all bodies in motion had, by their own nature, a constant 
 tendency to move more and more slowly, so as to stop at 
 last. This belief, indeed, is probably even now enter- 
 tained by most persons, till their attention is fixed upon 
 the arguments by which the first law of motion is esta- 
 blished. It is, however, not difficult to lead any person 
 of a speculative habit of thought to see that the retard- 
 ation which constantly takes place in the motion of all 
 bodies when left to themselves, is, in reality, the effect 
 of extraneous forces which destroy the velocity. A top 
 ceases to spin because the friction against the ground 
 and the resistance of the air gradually diminish its mo- 
 tion, and not because its motion has any internal prin- 
 ciple of decay or fatigue. This may be shown, and was, 
 in fact, shown by Hooke before the Royal Society, at the 
 time when the laws of motion were still under discus- 
 sion, by means of experiments in which the weight of 
 the top is increased, and the resistance to motion offered 
 by its support, is diminished ; for by such contrivances 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 217 
 
 its motion is made to continue much longer than it 
 would otherwise do. And by experiments of this nature, 
 although we can never remove the whole of the external 
 impediments to continued motion, and although, conse- 
 quently, there will always be some retardation ; and an 
 end of the motion of a body left to itself, however long 
 it may be delayed, must at last come ; yet we can esta- 
 blish a conviction that if all resistance could de removed, 
 there would be no diminution of velocity, and thus the 
 motion would go on for ever. 
 
 If we call to mind the axioms which we formerly 
 stated, as containing the most important conditions 
 involved in the idea of Cause, it will be seen that our 
 conviction in this case depends upon the first axiom of 
 Causation, that nothing can happen without a cause. 
 Every change in the velocity of the moving body must 
 have a cause ; and if the change can, in any manner, be 
 referred to the presence of other bodies, these are said 
 to exert force upon the moving body: and the conception 
 of force is thus evolved from the general idea of cause. 
 Force is any cause which has motion, or change of 
 motion, for its effect ; and thus, all the change of velocity 
 of a body which can be referred to extraneous bodies, as 
 the air which surrounds it, or the support on which it 
 rests, is considered as the effect of forces; and this 
 consideration is looked upon as explaining the difference 
 between the motion which really takes places in the expe- 
 riment, and that motion which, as the law asserts, would 
 take place if the body were not acted on by any forces. 
 
 Thus the truth of the first law of motion depends 
 upon the axiom that no change can take place without a 
 cause ; and follows from the definition of force, if we sup- 
 pose that there can be none but an external cause of 
 change. But in order to establish the law, it was neces- 
 sary further to be assured that there is no internal cause 
 
218 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 of change of velocity belonging to all matter whatever, 
 and operating in such a manner that the mere progress 
 of time is sufficient to produce a diminution of velocity 
 in all moving bodies. It appears from the history of 
 mechanical science, that this latter step required a refer- 
 ence to observation and experiment ; and that the first 
 law of motion is so far, historically at least, dependent 
 upon our experience. 
 
 But notwithstanding this historical evidence of the 
 need which we have of a reference to observed facts, in 
 order to place this first law of motion out of doubt, it has 
 been maintained by very eminent mathematicians and 
 philosophers, that the law is, in truth, evident of itself, 
 and does not really rest upon experimental proof. Such, 
 for example, is the opinion of D'Alembert *, who offers 
 what is called an d priori proof of this law ; that is, a 
 demonstration derived from our ideas alone. When a 
 body is put in motion, either, he says, the cause which 
 puts it in motion at first, suffices to make it move one 
 foot, or the continued action of the cause during this foot 
 is requisite for the motion. In the first case, the same 
 reason which made the body proceed to the end of the 
 first foot will hold for its going on through a second, 
 a third, a fourth foot, and so on for any number. In 
 the second case, the same reason which made the force 
 continue to act during the first foot, will hold for its 
 acting, and therefore for the body moving during each 
 succeeding foot. And thus the body, once beginning to 
 move, must go on moving for ever. 
 
 It is obvious that we might reply to this argument, 
 that the reasons for the body proceeding during each 
 succeeding foot may not necessarily be all the same ; for 
 among these reasons may be the time which has elapsed ; 
 and thus the velocity may undergo a change as the time 
 
 * Dynamique. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 210 
 
 proceeds : and we require observation to inform us that 
 it does not do so. 
 
 Professor Playfair has presented nearly the same 
 argument, although in a different and more mathematical 
 form*. If the velocity change, says he, it must change 
 according to some expression of calculation depending 
 upon the time, or, in mathematical language, must be a 
 function of the time. If the velocity diminish as the 
 time increases, this may be expressed by stating the velo- 
 city in each case as a certain number, from which another 
 quantity, or term, increasing as the time increases, is 
 subtracted. But, Playfair adds, there is no condition 
 involved in the nature of the case, by which the coeffi- 
 cients, or numbers which are to be employed, along with 
 the number representing the time, in calculating this 
 second term, can be determined to be of one magnitude 
 rather than of any other. Therefore he infers there can 
 be no such coefficients, and that the velocity is in each 
 case equal to some constant number, independent of the 
 time ; and is therefore the same for all times. 
 
 In reply to this we may observe, that the circum- 
 stance of our not seeing in the nature of the case any- 
 thing which determines for us the coefficients above 
 spoken off, cannot prove that they have not some certain 
 value in nature. We do not see in the nature of the 
 case anything which should determine a body to fall six- 
 teen feet in a second of time, rather than one foot or one 
 hundred feet : yet in fact the space thus run through by 
 falling bodies is determined to a certain magnitude. It 
 would be easy to assign a mathematical expression for 
 the velocity of a body, implying that one-hundredth of the 
 velocity, or any other fraction, is lost in each second f: 
 
 * Outlines, &c., p. 26. 
 
 t This would be the case, if, i being the number of seconds elapsed, 
 
220 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 and where is the absurdity of supposing such an expres- 
 sion really to represent the velocity ? 
 
 Most modern writers on mechanics have embraced 
 the opposite opinion, and have ascribed our knowledge 
 of this first law of motion to experience. Thus M. 
 Poisson, one of the most eminent of the mathematicians 
 who have written on this subject, says*, " We cannot 
 affirm a priori that the velocity communicated to a body 
 will not become slower and slower of itself, and end by 
 being entirely extinguished. It is only by experience 
 and induction that this question can be decided." 
 
 Yet it cannot be denied that there is much force in 
 those arguments by which it is attempted to shew that 
 the First Law of Motion, such as we find it, is more 
 consonant to our conceptions than any other would be. 
 The Law, as it exists, is the most simple that we can 
 conceive. Instead of having to determine by experi- 
 ments what is the law of the natural change of velocity, 
 we find the Law to be that it does not change at all. To a 
 certain extent, the Law depends upon the evident axiom, 
 that no change can take place without a cause. But 
 the question further occurs, whether the mere lapse of 
 time may not be a cause of change of velocity. In order 
 to ensure this, we have recourse to experiment ; and the 
 result is that time alone does not produce any such 
 change. In addition to the conditions of change which 
 we collect from our own Ideas, we ask of Experience what 
 other conditions and circumstances she has to offer ; and 
 the answer is, that she can point out none. When we 
 have removed the alterations which external causes, in 
 
 and C some constant quantity, the velocity were expressed by this 
 mathematical formula, 
 
 * Poisson, Dynamique. Ed. 2, Art. 113. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 221 
 
 our very conception of them, occasion, there are no 
 longer any alterations. Instead of having to guide our- 
 selves by experience, we learn that on this subject she 
 has nothing to tell us. Instead of having to take into 
 account a number of circumstances, we find that we have 
 only to reject all circumstances. The velocity of a body 
 remains unaltered by time alone, of whatever kind the 
 body itself be. 
 
 But the doctrine that time alone is not a cause of 
 change of velocity in any body is further recommended 
 to us by this consideration ; that time is conceived by 
 us not as a cause, but only as a condition of other causes 
 producing their effects. Causes operate in time ; but it 
 is only when the cause exists, that the lapse of time can 
 give rise to alterations. When therefore all external 
 causes of change of velocity are supposed to be removed, 
 the velocity must continue identical with itself, whatever 
 the time which elapses. An eternity of negation can 
 produce no positive result. 
 
 Thus, though the discovery of the First Law of 
 Motion was made, historically speaking, by means of 
 experiment, we have now attained a point of view in 
 which we see that it might have been certainly known 
 to be true independently of experience. This law in its 
 ultimate form, when completely simplified and steadily 
 contemplated, assumes the character of a self-evident 
 truth. We shall find the same process to take place in 
 other instances. And this feature in the progress of 
 science will hereafter be found to suggest very important 
 views with regard both to the nature and prospects of 
 our knowledge. 
 
 3. Gravity is a Uniform Force. We shall find 
 observations of the same kind offering themselves in a 
 manner more or less obvious, with regard to the other 
 principles of Dynamics. The determination of the laws 
 
222 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 according to which bodies fall downwards by the com- 
 mon action of gravity, has already been noticed in the 
 History of Mechanics*, as one of the earliest positive 
 advances in the doctrine of motion. These laws were 
 first rightly stated by Galileo, and established by rea- 
 soning and by experiment, not without dissent and con- 
 troversy. The amount of these doctrines is this : That 
 gravity is a uniform accelerating force ; such a uniform 
 force having this for its character, that it makes the 
 velocity increase in exact proportion to the time of 
 motion. The relation which the spaces described by the 
 body bear to the times in which they are described, is 
 obtained by mathematical deduction from this definition 
 of the force. 
 
 The clear Definition of a uniform accelerating force, 
 and the Proposition that gravity is such a force, were 
 co-ordinate and contemporary steps in this discovery. 
 In defining accelerating force, reference, tacit or ex- 
 press, was necessarily made to the second of the general 
 axioms respecting causation, That causes are measured 
 by their effects. Force, in the cases now under our 
 notice, is conceived to be, as we have already stated, 
 (p. 217,) any cause which, acting from without, changes 
 the motion of a body. It must, therefore, in this accep- 
 tation, be measured by the magnitude of the changes 
 which are produced. But in what manner the changes 
 of motion are to be employed as the measures of force, is 
 learnt from observation of the facts which we see taking 
 place in the world. Experience interprets the axiom of 
 causation, from which otherwise we could not deduce 
 any real knowledge. We may assume, in virtue of our 
 general conceptions of force, that under the same cir- 
 cumstances, a greater change of motion implies a greater 
 force producing it ; but what are we to expect when the 
 
 * Hist. Ind. Sci., B. vi. c. ii. sect. 2. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 223 
 
 circumstances change ? The weight of a body makes it 
 fall from rest at first, and causes it to move more quickly 
 as it descends lower. We may express this by saying, 
 that gravity, the universal force which makes all terres- 
 trial bodies fall when not supported, by its continuous 
 action first gives velocity to the body when it has none, 
 and afterwards adds velocity to that which the body 
 already has. But how is the velocity added propor- 
 tioned to the velocity which already exists? Force 
 acting on a body at rest, and on a body in motion, 
 appears under very different conditions; how are the 
 effects related ? Let the force be conceived to be in both 
 cases the same, since force is conceived to depend upon 
 the extraneous bodies, and not upon the condition of the 
 moving mass itself. But the force being the same, the 
 effects may still be different. It is at first sight con- 
 ceivable that the body, acted upon by the same gravity, 
 may receive a less addition of velocity when it is already 
 moving in the direction in which this gravity impels it ; 
 for if we ourselves push a body forwards, we can produce 
 little additional effect upon it when it is already moving 
 rapidly away from us. May it not be true, in like man- 
 ner, that although gravity be always the same force, its 
 effect depends upon the velocity which the body under 
 its influence already possesses ? 
 
 Observation and reasoning combined, as we have 
 said, enabled Galileo to answer these questions. He as- 
 serted and proved that we may consistently and properly 
 measure a force by the velocity which is by it generated 
 in a body, in some certain time, as one second; and 
 further, that if we adopt this measure, gravity will be a 
 force of the same value under all circumstances of the 
 body which it affects; since it appeared that, in fact, a 
 falling body does receive equal increments of velocity 
 in equal times from first to last. 
 
224 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 If it be asked whether we could have known, anterior 
 to, or independent of, experiment, that gravity is a uni- 
 form force in the sense thus imposed upon the term ; 
 it appears clear that we must reply, that we could not 
 have attained to such knowledge, since other laws of the 
 motion of bodies downwards are easily conceivable, and 
 nothing but observation could inform us that one of 
 these laws does not prevail in fact. Indeed, we may add, 
 that the assertion that the force of gravity is uniform, is 
 so far from being self-evident, that it is not even true ; 
 for gravity varies according to the distance from the 
 center of the earth ; and although this variation is so 
 small as to be, in the case of falling bodies, imperceptible, 
 it negatives the rigorous uniformity of the force as com- 
 pletely, though not to the same extent, as if the weight 
 of a body diminished in a marked degree, when it was 
 carried from the lower to the upper room of a house. It 
 cannot, then, be a truth independent of experience, that 
 gravity is uniform. 
 
 Yet, in fact, the assertion that gravity is uniform was 
 assented to, not only before it was proved, but even 
 before it was clearly understood. It was readily granted 
 by all, that bodies which fall freely are uniformly accele- 
 rated ; but while some held the opinion just stated, that 
 uniformly accelerated motion is that in which the velocity 
 increases in proportion to the time, others maintained, 
 that that is uniformly accelerated motion, in which the 
 velocity increases in proportion to the space ; so that, for 
 example, a body in falling vertically through twenty feet 
 should acquire twice as great a velocity as one which 
 falls through ten feet. 
 
 These two opinions are both put forward by the 
 interlocutors of Galileo's Dialogue on this subject*. And 
 the latter supposition is rejected, the author showing, 
 * Dialogo, in. p. 95. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 225 
 
 not that it is inconsistent with experience, but that it is 
 impossible in itself: inasmuch as it would inevitably lead 
 to the conclusion, that the fall through a large and a 
 small vertical space would occupy exactly the same time. 
 
 Indeed, Galileo assumes his definition of uniformly 
 accelerated motion as one which is sufficiently recom- 
 mended by its own simplicity. " If we attend carefully," 
 he says, " we shall find that no mode of increase of velocity 
 is more simple than that which adds equal increments in 
 equal times. Which we may easily understand if we 
 consider the close affinity of time and motion : for as the 
 uniformity of motion is defined by the equality of spaces 
 described in equal times, so we may conceive the uni- 
 formity of acceleration to exist when equal velocities are 
 added in equal times." 
 
 Galileo's mode of supporting his opinion, that bodies 
 falling by the action of gravity are thus uniformly acce- 
 lerated, consists, in the first place, in adducing the 
 maxim that nature always employs the most simple 
 means*. But he is far from considering this a decisive 
 argument. " I," says one of his speakers, " as it would 
 be very unreasonable in me to gainsay this or any other 
 definition which any author may please to make, since 
 they are all arbitrary, may still, without offence, doubt 
 whether such a definition, conceived and admitted in the 
 abstract, fits, agrees, and is verified in that kind of 
 accelerated motion which bodies have when they descend 
 naturally." 
 
 The experimental proof that bodies, when they fall 
 downwards, are uniformly accelerated, is (by Galileo) 
 derived from the inclined plane ; and therefore assumes 
 the proposition, that if such uniform acceleration prevail 
 in vertical motion, it will also hold when a body is com- 
 pelled to describe an oblique rectilinear path. This pro- 
 
 * Dialogo, in. p. 91. 
 VOL. I. W. P. Q 
 
226 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 position may be shown to be true, if (assuming by anti- 
 cipation the Third Law of Motion, of which we shall 
 shortly have to speak,) we introduce the conception of 
 a uniform statical force as the cause of uniform acce- 
 leration. For the force on the inclined plane bears 
 a constant proportion to the vertical force, and this 
 proportion is known from statical considerations. But 
 in the work of which we are speaking, Galileo does 
 not introduce this abstract conception of force as the 
 foundation of his doctrines. Instead of this, he pro- 
 poses, as a postulate sufficiently evident to be made 
 the basis of his reasonings, That bodies which descend 
 down inclined planes of different inclinations, but of 
 the same vertical height, all acquire the same velocity*. 
 But when this postulate has been propounded by one 
 of the persons of the dialogue, another interlocutor says, 
 "You discourse very probably; but besides this like- 
 lihood, I wish to augment the probability so far, that 
 it shall be almost as complete as a necessary demon- 
 stration." He then proceeds to describe a very inge- 
 nious and simple experiment, which shows that when a 
 body is made to swing upwards at the end of a string, 
 it attains to the same height, whatever is the path it 
 follows, so long as it starts from the lowest point with 
 the same velocity. And thus Galileo's postulate is ex- 
 perimentally confirmed, so far as the force of gravity can 
 be taken as an example of the forces which the postulate 
 contemplates : and conversely, gravity is proved to be a 
 uniform force, so far as it can be considered clear that 
 the postulate is true of uniform forces. 
 
 When we have introduced the conception and defi- 
 nition of accelerating force, Galileo's postulate, that 
 bodies descending down inclined planes of the same 
 vertical height, acquire the same velocity, may, by a 
 
 * Dialogo, in. p. 36. 
 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 227 
 
 few steps of reasoning, be demonstrated to be true of 
 uniform forces : and thus the proof that gravity, either in 
 vertical or oblique motion, is a uniform force, is con- 
 firmed by the experiment above mentioned ; as it also is, 
 on like grounds, by many other experiments, made upon 
 inclined planes and pendulums. 
 
 Thus the propriety of Galileo's conception of a uni- 
 form force, and the doctrine that gravity is a uniform 
 force, were confirmed by the same reasonings and experi- 
 ments. We may make here two remarks ; First, that the 
 conception, when established and rightly stated, appears 
 so simple as hardly to require experimental proof; a 
 remark which we have already made with regard to the 
 First Law of Motion : and Second, that the discovery of 
 the real law of nature was made by assuming proposi- 
 tions which, without further proof, we should consider as 
 very precarious, and as far less obvious, as well as less 
 evident, than the law of nature in its simple form. 
 
 4. The Second Law of Motion. When a body, instead 
 of falling downwards from rest, is thrown in any direc- 
 tion, it describes a curve line, till its motion is stopped. 
 In this, and in all other cases in which a body describes 
 a curved path in free space, its motion is determined by 
 the Second Law of Motion. The law, in its general 
 form, is as follows: When a body is thus cast forth 
 and acted upon by a force in a direction transverse to its 
 motion, the result is, That there is combined with the 
 motion with which the body is thrown, another motion, 
 exactly the same as that which the same force would have 
 communicated to a body at rest. 
 
 It will readily be understood that the basis of this 
 law is the axiom already stated, that effects are measured 
 by their causes. In virtue of this axiom, the effect of 
 gravity acting upon a body in a direction transverse to its 
 motion, must measure the accelerative or deflective force 
 
 Q2 
 
228 PHir/JSOPHY OF THK MECHANICAL 8CIENCI 
 
 of gravity under those circumstances. If this effect var\ 
 with the varying velocity and direction of the body thus 
 acted upon, the deflective force of gravity also will vary 
 with those circumstances. The more simple supposition 
 is, that the deflective force of gravity is the same, whatever 
 be the velocity and direction of the body which is sub- 
 jected to its influence: and this is the supposition which 
 we find to be verified by facts. For example, a ball let 
 fall from the top of a ship's upright mast, when she is 
 sailing steadily forward, will fall at the foot of the mast, 
 just as if it were let fall while the ship were at rest ; thus 
 showing that the motion which gravity gives to the hall 
 is compounded with the horizontal motion which the ball 
 shares with the ship from the first. This general and 
 simple conception of motions as roMpon'mlcd with OIK; 
 another, represents, it is proved, the manner in which 
 the motion produced by gravity modifies any other mo- 
 tion which the body may previously have had. 
 
 The discussions which terminated in the general re- 
 ception of this Second Law of Motion among mechanical 
 writers, were much mixed up with the arguments for and 
 against the Copernican system, which system represented 
 the earth as revolving upon its axis. For the obvious 
 argument against this system was, that if each point of the 
 earth's surface were thus in motion from west to east, a 
 stone dropt from the top of a tower would be left behind, 
 the tower moving away from it : and the; answer was, that 
 by this law of motion, the stone would have the earth's 
 motion impressed upon it, as well as that motion which 
 would arise from its gravity to the; earth ; arid that the 
 motion of the stone relative; to the tower would thus be 
 the same as if both earth and tower were at rest, (Jali- 
 leo further urged, as a presumption in favour of the opi- 
 nion that the two motions, the circular motion arising 
 from the rotation of the earth, and the downward motion 
 
OK nir flilM-llM I S OK PNXAMUS. 
 
 from the gravity of the stone, would be com- 
 pounded in the \>av we have described, ^neither of them 
 disturbing or diminishing the other,) that the first 
 motion \\as in its own nature 1 not liable to any change or 
 diminution*, as we learn from the First l.a\\ of Motion. 
 Nor was the subject lightly dismissed. The experiment 
 of the stone let fall from the top of the mast was made 
 in various forms by Gassendi; and in his Epistle, De 
 Motu /w/ T< .*><></ .]/</<'/ //<//.'>/<//<>, the rule now in ques- 
 tion is supported bv reference to these experiments. In 
 this manner, the general truth, the Second l.a\\ of 
 Motion. \\as established completely and bevc>iul ilispute. 
 Hut when this lav> had been pro>cnl to be true in a 
 general >ense, with sueh aei'urae> a> rmle experimeutvS 
 like thosi 1 oi (ialileo and (lassendi, would admit, it still 
 remained to be ascertained ^supposin^ our Uiu>\\ hnl^e ot 
 tlu law to bi^ the result of experience aloiu\^ \\ hether it 
 \\ere tnu % \>ith that prei-ise and rigorous exaet ness uhieh 
 more refined modes of experimenting eould tt^st. We 
 so willinglv believ( > in tlu^ simplieitv of laws of nature, 
 that the rigorous aceuracv of sueh a la\\, KUONMI to be at 
 least approximately true, \\as taken tor granted, till M>me 
 ground tor susptH-ttn^ the ei>utrarv should appear. ^ et 
 calculations ha\e not beiMi wanting which mi^ht confirm 
 the law as true to the last decree of aeeurai-v. Laplace 
 relates (Sj/^i. </// Mi>//t, h\re iv., chap. 1 lO that at t>uc 
 time In* had conceived it possible that the effect of 
 ti'raxitv upon the moon mi^ht be slight 1\ uuuliticd bv \\\c 
 moon's direction and velocity; and that in this \\av an 
 explanation mi^ht he found tor the moon's <frrv/< /<>//<'// 
 ^a deviation ot' her observed from her calculated place, 
 which long perplexed mathematicians). Hut it \\asatter 
 some time discovered that this feature in the moon's 
 motion arose from another cause; and the .second la\\ of 
 
 4 />:,;/, >.;,>. I I ]> III 
 
230 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 motion was confirmed as true in the most rigorous 
 sense. 
 
 Thus we see that although there were arguments 
 which might be urged in favour of this law, founded 
 upon the necessary relations of ideas, men became con- 
 vinced of its truth only when it was verified and con- 
 firmed by actual experiment. But yet in this case 
 again, as in the former ones, when the law had been 
 established beyond doubt or question, men were very 
 ready to believe that it was not a mere result of observa- 
 tion, that the truth which it contained was not derived 
 from experience, that it might have been assumed as 
 true in virtue of reasonings anterior to experience, and 
 that experiments served only to make the law more plain 
 and intelligible, as visible diagrams in geometry serve to 
 illustrate geometrical truths ; our knowledge not being 
 (they deemed) in mechanics, any more than in geometry, 
 borrowed from the senses. It was thought by many to 
 be self-evident, that the effect of a force in any direction 
 cannot be increased or diminished by any motion trans- 
 verse to the direction of the force which the body may 
 have at the same time : or, to express it otherwise, that 
 if the motion of the body be compounded of a horizontal 
 and vertical motion, the vertical motion alone will be 
 affected by the vertical force. This principle, indeed, 
 not only has appeared evident to many persons, but even 
 at the present day is assumed as an axiom by many of 
 the most eminent mathematicians. It is, for example, 
 so employed in the Mecanique Celeste of Laplace, which 
 may be looked upon as the standard of mathematical 
 mechanics in our time; and in the Mecanique Analy- 
 tique of Lagrange, the most consummate example which 
 has appeared of subtilty of thought on such subjects, as 
 well as of power of mathematical generalization*. And 
 
 * I may observe that the rule that we may compound motions, as 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 231 
 
 thus we have here another example of that circumstance 
 which we have already noticed in speaking of the First 
 Law of Motion, (Art. 2 of this Chapter,) and of the Law 
 that Gravity is a uniform Force, (Art. 3) ; namely, that 
 the law, though historically established by experiments, 
 appears, when once discovered and reduced to its most 
 simple and general form, to be self-evident. I am the 
 more desirous of drawing attention to this feature in 
 various portions of the history of science, inasmuch as it 
 will be found to lead to some very extensive and impor- 
 tant views, hereafter to be considered. 
 
 5. The Third Lain of Motion. We have, in the 
 definition of Accelerating Force, a measure of Forces, so 
 far as they are concerned in producing motion. We had 
 before, in speaking of the principles of statics, defined 
 the measure of Forces or Pressures, so far as they are 
 employed in producing equilibrium. But these two 
 aspects of Force are closely connected; and we require a 
 law which shall lay down the rule of their connexion. 
 By the same kind of muscular exertion by which we 
 
 the Law supposes, is involved in the step of resolving them ; which is 
 done in the passage to which I refer (Mec. Analyt. Ptie. i., sect. i. art. 3, 
 p. 225). " Si on con9oit que la mouvement d'un corps et les forces 
 qui le sollicitent soient decomposees suivant trois lignes droites perpen- 
 diculaires entre elles, on pourra considerer separement les mouvemens 
 et les forces relatives a chacun a de ces trois directions. Car a cause de 
 la perpendicularite des directions il est visible que chacun de ces mouve- 
 mens partiels peut etre regarde comme independant des deux autres, 
 et qu'il ne peut recevoir d'alteration que de la part de la force qui agit 
 dans la direction de ce mouvement ; Ton peut conclure que ces trois 
 mouvements doivent suivre, chacun en particulier, les lois des mouve- 
 mens rectilignes acceleres ou retardes par les forces donnees." Laplace 
 makes the same assumption in effect, {Mec. Cel. P. i., liv. i., art. 7 5 ) 
 by resolving the forces which act upon a point in three rectangular 
 directions, and reasoning separately concerning each direction. But in 
 his mode of treating the subject is involved a principle which belongs 
 to the Third Law of Motion, namely, the doctrine that the velocity is 
 as the force, of which we shall have to speak elsewhere. 
 
232 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 can support a heavy stone, we can also put it in motion. 
 The question then occurs, how is the rate and manner 
 of its motion determined ? The answer to this question 
 is contained in the Third Law of Motion, and it is to 
 this effect : that the Momentum which any pressure pro- 
 duces in the mass in a given time is proportional to the 
 pressure. By Momentum is meant the product of the 
 numbers which express the velocity and the mass of the 
 body : and hence, if the mass of the body be the same 
 in the instances which we compare, the rule is, That 
 the velocity is as the force which produces it ; and this is 
 one of the simplest ways of expressing the Third Law 
 of Motion. 
 
 In agreement with our general plan, we have to ask, 
 What is the ground of this rule ? What is the simplest 
 and most satisfactory form to which we can reduce the 
 proof of it ? Or, to take an instance ; if a double pres- 
 sure be exerted against a given mass, so disposed as to 
 be capable of motion, why must it produce twice the 
 velocity in the same time ? 
 
 To answer this question, suppose the double pressure 
 to be resolved into two single pressures : one of these 
 will produce a certain velocity; and the question is, why 
 an equal pressure, acting upon the same mass, will pro- 
 duce an equal velocity in addition to the former? Or, 
 stating the matter otherwise, the question is, why each 
 of the two forces will produce its separate effect, unal- 
 tered by the simultaneous action of the other force ? 
 
 This statement of the case makes it seem to approach 
 very near to such cases as are included in the Second 
 Law of Motion, and therefore it might appear that this 
 Third Law has no grounds distinct from the Second. 
 But it must be recollected that the word force has a dif- 
 ferent meaning in this case and in that ; in this place it 
 signifies pressure ; in the statement of the Second Law 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 233 
 
 its import was accelerative or deflective force, measured 
 by the velocity or deflexion generated. And thus the 
 Third Law of Motion, so far as our reasonings yet go, 
 appears to rest on a foundation different from the Second. 
 
 Accordingly, that part of the Third Law of Motion 
 which we are now considering, that the velocity gene- 
 rated is as the force, was obtained, in fact, by a separate 
 train of research. The first exemplification of this law 
 which was studied by mathematicians, was the motion 
 of bodies upon inclined planes: for the force which urges 
 a body down an inclined plane is known by statics, and 
 hence the velocity of its descent was to be determined. 
 Galileo originally* in his attempts to solve this problem 
 of the descent of a body down an inclined plane, did not 
 proceed from the principle which we have stated, (the 
 determination of the force which acts down the inclined 
 plane from statical considerations,) obvious as it may 
 seem ; but assumed, as we have already seen, a propo- 
 sition apparently far more precarious ; namely, that 
 a body sliding down a smooth inclined plane acquires 
 always the same velocity, so long as the vertical height 
 fallen through is the same. And this conjecture, (for 
 at first it was nothing more than a conjecture,) he 
 confirmed by an ingenious experiment ; in which bodies 
 acquired or lost the same velocity by descending or 
 ascending through the same height, although their paths 
 were different in other respects. 
 
 This was the form in which the doctrine of the mo- 
 tion of bodies down inclined planes was at first presented 
 in Galileo's Dialogues on the Science of Motion. But 
 his disciple Viviani was dissatisfied with the assumption 
 thus introduced ; and in succeeding editions of the Dia- 
 logues, the apparent chasm in the reasoning was much 
 narrowed, by making the proof depend upon a principle 
 
 * Dial, dclla Sc. Nuov. in., p. 9(i. See Hist. Ind. Sci. B. vi. c. ii. sect. 5. 
 
234 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 nearly identical with the third law of motion as we have 
 just stated it. In the proof thus added, " We are agreed," 
 says the interlocutor*, "that in a moving body the 
 impetus, energy, momentum, or propension to motion, is 
 as great as is the force or least resistance which suffices 
 to sustain it ;" and the impetus or momentum, in the 
 course of the proof, being taken to be as the velocity 
 produced in a given time, it is manifest that the prin- 
 ciple so stated amounts to this ; that the velocity pro- 
 duced is as the statical force. And thus this law of 
 motion appears, in the school of Galileo, to have been 
 suggested and established at first by experiment, but 
 afterwards confirmed and demonstrated by a priori 
 considerations. 
 
 We see, in the above reasoning, a number of abstract 
 terms introduced which are not, at first at least, very 
 distinctly defined, as impetus, momentum, &c. Of 
 these, momentum has been selected, to express that 
 quantity which, in a moving body, measures the statical 
 force impressed upon the body. This quantity is, as we 
 have just seen, proportional to the velocity in a given 
 body. It is also, in different bodies, proportional to the 
 mass of the body. This part of the third law of motion 
 follows from our conception of matter in general as con- 
 sisting of parts capable of addition. A double pressure 
 must be required to produce the same velocity in a 
 double mass ; for if the mass be halved, each half will 
 require an equal pressure ; and the addition, both of the 
 pressures and of the masses, will take place without dis- 
 turbing the effects. 
 
 The measure of the quantity of matter of a body con- 
 sidered as affecting the velocity which pressure produces 
 in the body, is termed its inertia, as we have already 
 stated, (p. 190.) Inertia is the property by which a 
 * Dialogo, p. 104. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 235 
 
 large mass of matter requires .a greater force than a 
 small mass, to give it an equal velocity. It belongs to 
 each portion of matter ; and portions of inertia are 
 added whenever portions of matter are added. Hence 
 inertia is as the quantity of matter ; which is only an- 
 other way of expressing this third law of motion, so far 
 as quantity of matter is concerned. 
 
 But how do we know the quantity of matter of a 
 body ? We may reply, that we take the weight as the 
 measure of the quantity of matter : but we may then be 
 again asked, how it appears that the weight is propor- 
 tional to the inertia ; which it must be, in order that the 
 quantity of matter may be proportional to both one and 
 the other. We answer, that this appears to be true 
 experimentally, because all bodies fall with equal veloci- 
 ties by gravity, when the known causes of difference are 
 removed. The observations of falling bodies, indeed, 
 are not susceptible of much exactness : but experiments 
 leading to the same result, and capable of great precision, 
 were made upon pendulums by Newton ; as he relates in 
 his Principia, Book in., prop. 6. They all agreed, he 
 says, with perfect accuracy : and thus the weight and the 
 inertia are proportional in all cases, and therefore each 
 proportional to the quantity of matter as measured by 
 the other. 
 
 The conception of inertia, as we have already seen in 
 chapter v., involves the notion of action and reaction ; 
 and thus the laws which involve inertia depend upon the 
 idea of mutual causation. The rule, that the velocity is 
 as the force, depends upon the principle of causation, 
 that the effect is proportional to the cause ; the effect 
 being here so estimated as to be consistent both with 
 the other laws of motion and with experiment. 
 
 But here, as in other cases, the question occurs 
 again ; Is experiment really requisite for the proof of 
 
236 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 this law ? If we look to authorities, we shall be not a 
 little embarrassed to decide. D'Alembert is against the 
 necessity of experimental proof. "Why," says he*, 
 " should we have recourse to this principle employed, at 
 the present day, by everybody, that the force is propor- 
 tional to the velocity? ... a principle resting solely 
 upon this vague and obscure axiom, that the effect is 
 proportional to the cause. We shall not examine here," 
 he adds, " if this principle is necessarily true ; we shall 
 only avow that the proofs which have hitherto been 
 adduced do not appear to us unexceptionable : nor shall 
 we, with some geometers, adopt it as a purely contingent 
 truth; which would be to ruin the certainty of me- 
 chanics, and to reduce it to be nothing more than an 
 experimental science. We shall content ourselves with 
 observing," he proceeds, " that certain or doubtful, clear 
 or obscure, it is useless in mechanics, and consequently 
 ought to be banished from the science." Though 
 D'Alembert rejects the third law of motion in this form, 
 he accepts one of equivalent import, which appears to 
 him to possess axiomatic certainty ; and this procedure 
 is in consistence with the course which he takes, of 
 claiming for the science of mechanics more than mere 
 experimental truth. On the contrary, Laplace considers 
 this third law as established by experiment. "Is the 
 force," he saysf, "proportioned to the velocity? This," 
 he replies, "we cannot know a priori, seeing that we 
 are in ignorance of the nature of moving force : we must 
 therefore, for this purpose, recur to experience ; for all 
 which is not a necessary consequence of the few data we 
 have respecting the nature of things, is, for us, only a re- 
 sult of observation." And again he saysj, "Here, then, 
 we have two laws of motion, the law of inertia [the first 
 law of motion], and the law of the force proportional to 
 
 * Dynamiqiie, Pref. p. x. t Mec Cel p. 15. J P. 18. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 237 
 
 the velocity, which are given by observation. They 
 are the most natural and the most simple laws which we 
 can imagine, and without doubt they flow from the very 
 nature of matter ; but this nature being unknown, they 
 are, for us, only observed facts : the only ones, however, 
 which mechanics borrows from experience." 
 
 It will appear, I think, from the views given in this 
 and several other parts of the present work, that we can- 
 not with justice say that we have very " few data respect- 
 ing the nature of things," in speculating concerning the 
 laws of the universe ; since all the consequences which 
 flow from the relations of our fundamental ideas, neces- 
 sarily regulate our knowledge of things, so far as we 
 have any such knowledge. Nor can we say that the na- 
 ture of matter is unknown to us, in any sense in which 
 we can conceive knowledge as possible. The nature ot 
 matter is no more unknown than the nature of space or 
 of number. In our conception of matter, as of space 
 and of number, are involved certain relations, which are 
 the necessary groundwork of our knowledge ; and any- 
 thing which is independent of these relations, is not un- 
 known, but inconceivable. 
 
 It must be already clear to the reader, from the 
 phraseology employed by these two eminent mathema- 
 ticians, that the question respecting the formation of the 
 third law of motion can only be solved by a careful con- 
 sideration of what we mean by observation and experi- 
 ence, nature and matter. But it will probably be gene- 
 rally allowed, that, taking into account the explanations 
 already offered of the necessary conditions of experience 
 and of the conception of inertia, this law of motion, that 
 the inertia is as the quantity of matter, is almost or alto- 
 gether self-evident. 
 
 6. Action and Reaction are Equal in Moving Bodies. 
 When we have to consider bodies as acting upon one 
 
238 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 another, and influencing each other's motions, the third 
 law of motion is still applied ; but along with this, we 
 also employ the general principle that action and reaction 
 are equal and opposite. Action and reaction are here to 
 be understood as momentum produced and destroyed, 
 according to the measure of action established by the 
 Third Law of Motion : and the cases in which this prin- 
 ciple is thus employed form so large a portion of those 
 in which the third law of motion is used, that some 
 writers (Newton at the head of them) have stated the 
 equality of action and reaction as the third law of motion. 
 
 The third law of motion being once established, the 
 equality of action and reaction, in the sense of mo- 
 mentum gained and lost, necessarily follows. Thus, if 
 a weight hanging by a string over the edge of a smooth 
 level table draw another weight along the table, the 
 hanging weight moves more slowly than it would do if 
 not so connected, and thus loses velocity by the con- 
 nexion ; while the other weight gains by the connexion 
 all the velocity which it has, for if left to itself it would 
 rest. And the pressures which restrain the descent of the 
 first body and accelerate the motion of the second, are 
 equal at all instants of time, for each of these pressures 
 is the tension of the string : and hence, by the third law 
 of motion, the momentum gained by the one body, and 
 the momentum lost by the other in virtue of the action 
 of this string, are equal. And similar reasoning may be 
 employed in any other case where bodies are connected. 
 
 The case where one body does not push or draw, 
 but strikes another, appeared at first to mechanical rea- 
 soners to be of a different nature from the others ; but a 
 little consideration was sufficient to show that a blow 
 is, in fact, only a short and violent pressure ; and that, 
 therefore, the general rule of the equality of momentum 
 lost and gained applies to this as well as to the other cases. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 239 
 
 Thus, in order to determine the case of the direct 
 action of bodies upon one another, we require no new 
 law of motion. The equality of action and reaction, 
 which enters necessarily into every conception of me- 
 chanical operation, combined with the measure of action 
 as given by the third law of motion, enables us to trace 
 the consequences of every case, whether of pressure or 
 of impact. 
 
 7. D'Alemberfs Principle. But what will be the 
 result when bodies do not act directly upon each other, 
 but are indirectly connected in any way by levers, strings, 
 pulleys, or in any other manner, so that one part of the 
 system has a mechanical advantage over another? The 
 result must still be determined by the principle that 
 action and reaction balance each other. The action and 
 reaction, being pressures in one sense, must balance each 
 other by the laws of statics, for these laws determine 
 the equilibrium of pressure. Now action and reaction, 
 according to their measures in the Third Law of Motion, 
 are momentum gained and lost, when the action is di- 
 rect ; and except the indirect action introduce some 
 modification of the law, they must have the same mea- 
 sure still. But, in fact, we cannot well conceive any 
 modification of the law to take place in this case; for 
 direct action is only one (the ultimate) case of indirect 
 action. Thus if two heavy bodies act at different points 
 of a lever, the action of each on the other is indirect ; 
 but if the two points come together, the action becomes 
 direct. Hence the rule must be that which we have 
 already stated ; for if the rule were false for indirect 
 action, it would also be false for direct action, for which 
 case we have shown it to be true. And thus we obtain 
 the general principle, that in any system of bodies \vhich 
 act on each other, action and reaction, estimated by mo- 
 mentum gained and lost, balance each other according 
 
240 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 to the laws of equilibrium. This principle, which is so 
 general as to supply a key to the solution of all pos- 
 sible mechanical problems, is commonly called D'Alem- 
 berfs Principle. The experimental proofs which con- 
 vinced men of the truth of the Third Law of Motion 
 were, many or most of them, proofs of the law in this 
 extended sense. And thus the proof of D'Alembert's 
 Principle, both from the idea of mechanical action and 
 from experience, is included in the proof of the law 
 already stated. 
 
 8. Connexion of Dynamical and Statical Principles. 
 The principle of equilibrium of D'Alembert just stated, 
 is the law which he would substitute for the Third Law 
 of Motion ; and he would thus remove the necessity for 
 an independent proof of that law. In like manner, the 
 Second Law of Motion is by some writers derived from 
 the principle of the composition of statical forces ; and 
 they would thus supersede the necessity of a reference to 
 experiment in that case. Laplace takes this course, and 
 thus, as we have seen, rests only the First and Third Law 
 of Motion upon experience. Newton, on the other hand, 
 recognizes the same connexion of propositions, but for 
 a different purpose ; for he derives the composition of 
 statical forces from the Second Law of Motion. 
 
 The close connexion of these three principles, the 
 composition of (statical) forces, the composition of (ac- 
 celerating) forces with velocities, and the measure of 
 (moving) forces by velocities, cannot be denied ; yet it 
 appears to be by no means easy to supersede the neces- 
 sity of independent proofs of the two last of these prin- 
 ciples. Both may be proved or illustrated by expe- 
 riment : and the experiments which prove the one are 
 different from those which establish the other. For 
 example, it appears by easy calculations, that when we 
 apply our principles to the oscillations of a pendulum, 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 241 
 
 the Second Law is proved by the fact, that the oscilla- 
 tions take place at the same rate in an east and west, 
 and in a north and south direction : under the same cir- 
 cumstances, the Third Law is proved by our finding that 
 the time of a small oscillation is proportional to the 
 square root of the length of a pendulum ; and similar 
 differences might be pointed out in other experiments, 
 as to their bearing upon the one law or the other. 
 
 9. Mechanical Principles become gradually more 
 simple and more evident. I will again point out in 
 general two circumstances which I have already noticed 
 in particular cases of the laws of motion. Truths are 
 often at first assumed in a form which is far from being 
 the most obvious or simple ; and truths once discovered 
 are gradually simplified, so as to assume the appearance 
 of self-evident truths. 
 
 The former circumstance is exemplified in several of 
 the instances which we have had to consider. The 
 assumption that a perpetual motion is impossible pre- 
 ceded the knowledge of the first law of motion. The 
 assumed equality of the velocities acquired down two in- 
 clined planes of the same height, was afterwards reduced 
 to the third law of motion by Galileo himself. In the 
 History"', we have noted Huyghens's assumption of the 
 equality of the actual descent and potential ascent of the 
 center of gravity : this was afterwards reduced by Her- 
 man and the Bernoullis, to the statical equivalence of the 
 solicitations of gravity and the vicarious solicitations of 
 the effective forces which act on each point ; and finally 
 to the principle of D'Alembert, which asserts that the 
 motions gained and lost balance each other. 
 
 This assertion of principles which now appear neither 
 obvious nor self-evident, is not to be considered as a 
 groundless assumption on the part of the discoverers by 
 
 * B. vi. c. v. sect. 2. 
 VOL. I. W. P. R 
 
242 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 whom it was made. On the contrary, it is evidence of 
 the deep sagacity and clear thought which were requisite 
 in order to make such discoveries. For these results are 
 really rigorous consequences of the laws of motion in 
 their simplest form : and the evidence of them was pro- 
 bably present, though undeveloped, in the minds of the 
 discoverers. We are told of geometrical students, who, 
 by a peculiar aptitude of mind, perceived the evidence of 
 some of the more advanced propositions of geometry 
 without going through the introductory steps. We must 
 suppose a similar aptitude for mechanical reasonings, 
 which, existing in the minds of Stevinus, Galileo, New- 
 ton, and Huyghens, led them to make those assumptions 
 which finally resolved themselves into the laws of motion. 
 We may observe further, that the simplicity and evi- 
 dence which the laws of mechanics have at length as- 
 sumed, are much favoured by the usage of words among 
 the best writers on such subjects. Terms which origi- 
 nally, and before the laws of motion were fully known, 
 were used in a very vague and fluctuating sense, were 
 afterwards limited and rendered precise, so that asser- 
 tions which at first appear identical propositions become 
 distinct and important principles. Thus force, motion, 
 momentum, are terms which were employed, though in a 
 loose manner, from the very outset of mechanical specu- 
 lation. And so long as these words retained the vagueness 
 of common language, it would have been a useless and 
 barren truism to say that " the momentum is proportional 
 to the force," or that " a body loses as much motion as 
 it communicates to another." But when " momentum " 
 and "quantity of motion" are defined to mean the pro- 
 duct of mass and velocity, these two propositions imme- 
 diately become distinct statements of the third law of 
 motion and its consequences. In like manner, the asser- 
 tion that "gravity is a uniform force" was assented to, 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 243 
 
 before it was settled what a uniform force was ; but this 
 assertion only became significant and useful when that 
 point had been properly determined. The statement 
 that "when different motions are communicated to the 
 same body their effects are compounded," becomes the 
 second law of motion, when we define what composition 
 of motions is. And the same process may be observed 
 in other cases. 
 
 And thus we see how well the form which science 
 ultimately assumes is adapted to simplify knowledge. 
 The definitions which are adopted, and the terms which 
 become current in precise senses, produce a complete 
 harmony between the matter and the form of our know- 
 ledge ; so that truths which were at first unexpected and 
 recondite, became familiar phrases, and after a few gene- 
 rations sound, even to common ears, like identical pro- 
 positions. 
 
 10. Controversy of the Measure of Force. In the 
 History of Mechanics*, we have given an account of the 
 controversy which, for some time, occupied the mathema- 
 ticians of Europe, whether the forces of bodies in motion 
 should be reckoned proportional to the velocity, or to the 
 square of the velocity. We need not here recall the 
 events of this dispute ; but we may remark, that its his- 
 tory, as a metaphysical controversy, is remarkable in this 
 respect, that it has been finally and completely settled ; 
 for it is now agreed among mathematicians that both 
 sides were right, and that the results of mechanical action 
 may be expressed with equal correctness by means of 
 momentum and of vis viva. It is, in one sense, as D' Alem- 
 bert has saidf, a dispute about words; but we are not 
 
 * B. vi. c. v. sect. 2. 
 
 t D'Alembert has also remarked (Dynamique, Pref. xxi.,) that this 
 controversy " shows how little justice and precision there is in the 
 pretended axiom that causes are proportional to their effects." But 
 
 R2 
 
244 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 to infer that, on that account, it was frivolous or useless ; 
 for such disputes are one principal means of reducing the 
 principles of our knowledge to their utmost simplicity 
 and clearness. The terms which are employed in the 
 science of mechanics are now liberated for ever, in the 
 minds of mathematicians, from that ambiguity which 
 was the battle-ground in the war of the vis viva. 
 
 But we may observe that the real reason of this con- 
 troversy was exactly that tendency which we have been 
 noticing ; the disposition of man to assume in his specu- 
 lations certain general propositions as true, and to fix the 
 sense of terms so that they shall fall in with this truth. 
 It was agreed, on all hands, that in the mutual action of 
 bodies the same quantity of force is always preserved; 
 and the question was, by which of the two measures this 
 rule could best be verified. We see, therefore, that the 
 dispute was not concerning a definition merely, but con- 
 cerning a definition combined with a general proposition. 
 Such a question may be readily conceived to have been 
 by no means unimportant ; and we may remark, in pass- 
 ing, that such controversies, although they are commonly 
 afterwards stigmatized as quarrels about words and defi- 
 nitions, are, in reality, events of considerable conse- 
 quence in the history of science ; since they dissipate all 
 ambiguity and vagueness in the use of terms, and bring 
 into view the conditions under which the fundamental 
 principles of our knowledge can be most clearly and 
 simply presented. 
 
 It is worth our while to pause for a moment on the 
 prospect that we have thus obtained, of the advance of 
 
 this reflection is by no means well founded. For since both measures 
 are true, it appears that causes may be justly measured by their effects, 
 even when very different kinds of effects are taken. That the axiom 
 does not point out one precise measure, till illustrated by experience or 
 by other considerations, we grant : but the same thing occurs in the 
 application of other axioms also. 
 
ESTABLISHMENT OF THE PRINCIPLES OF DYNAMICS. 245 
 
 knowledge, as exemplified in the history of Mechanics. 
 The general transformation of our views from vague to 
 definite, from complex to simple, from unexpected dis- 
 coveries to self-evident truths, from seeming contradic- 
 tions to identical propositions, is very remarkable, but it 
 is by no means peculiar to our subject. The same cir- 
 cumstances, more or less prominent, more or less deve- 
 loped, appear in the history of other sciences, according 
 to the point of advance which each has reached. They 
 bear upon very important doctrines respecting the pro- 
 spects, the limits, and the very nature of our knowledge. 
 And though these doctrines require to be considered with 
 reference to the whole body of science, yet the peculiar 
 manner in which they are illustrated by the survey of 
 the history of Mechanics, on which we have just been 
 engaged, appears to make this a convenient place for 
 introducing them to the reader. 
 
 CHAPTER VIII. 
 
 OF THE PARADOX OF UNIVERSAL PROPOSI- 
 TIONS OBTAINED FROM EXPERIENCE. 
 
 1. IT was formerly stated'"" that experience cannot 
 establish any universal or necessary truths. The number 
 of trials which we can make of any proposition is neces- 
 sarily limited, and observation alone cannot give us any 
 ground of extending the inference to untried cases. Ob- 
 served facts have no visible bond of necessary connexion, 
 and no exercise of our senses can enable us to discover 
 such connexion. We can never acquire from a mere 
 observation of facts, the right to assert that a proposition 
 is true in all cases, and that it could not be otherwise 
 than we find it to be. 
 
 * B. i., c. v. Of Experience. 
 
246 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 Yet, as we have just seen in the history of the laws of 
 motion, we may go on collecting our knowledge from 
 observation, and enlarging and simplifying it, till it ap- 
 proaches or attains to complete universality and seeming- 
 necessity. Whether the laws of motion, as we now know 
 them, can be rigorously traced to an absolute necessity in 
 the nature of things, we have not ventured absolutely to 
 pronounce. But we have seen that some of the most 
 acute and profound mathematicians have believed that, 
 for these laws of motion, or some of them, there was 
 such a demonstrable necessity compelling them to be 
 such as they are, and no other. Most of those who have 
 carefully studied the principles of Mechanics will allow 
 that some at least of the primary laws of motion approach 
 very near to this character of necessary truth ; and will 
 confess that it would be difficult to imagine any other 
 consistent scheme of fundamental principles. And almost 
 all mathematicians will allow to these laws an absolute 
 universality ; so that we may apply them without scruple 
 or misgiving, in cases the most remote from those to 
 which our experience has extended. What astronomer 
 would fear to refer to the known laws of motion, in rea- 
 soning concerning the double stars; although these objects 
 are at an immeasurably remote distance from that solar 
 system which has been the only field of our observation 
 of mechanical facts? What philosopher, in speculating 
 respecting a magnetic fluid, or a luminiferous ether, would 
 hesitate to apply to it the mechanical principles which 
 are applicable to fluids of known mechanical properties ? 
 When we assert that the quantity of motion in the world 
 cannot be increased or diminished by the mutual actions 
 of bodies, does not every mathematician feel convinced 
 that it would be an unphilosophical restriction to limit 
 this proposition to such modes of action as we have 
 tried? 
 

 PARADOX OF UNIVERSAL PROPOSITIONS. 247 
 
 Yet no one can doubt that, in historical fact, these 
 laws were collected from experience. That such is the 
 case, is no matter of conjecture. We know the time, the 
 persons, the circumstances, belonging to each step of each 
 discovery. I have, in the History, given an account of 
 these discoveries ; and in the previous chapters of the pre- 
 sent work, I have further examined the nature and the 
 import of the principles which were thus brought to light. 
 
 Here, then, is an apparent contradiction. Experi- 
 ence, it would seem, has done that which we had proved 
 that she cannot do. She has led men to propositions, 
 universal at least, and to principles which appear to some 
 persons necessary. What is the explanation of this con- 
 tradiction, the solution of this paradox ? Is it true that 
 Experience can reveal to us universal and necessary 
 truths? Does she possess some secret virtue, some un- 
 suspected power, by which she can detect connexions 
 and consequences which we have declared to be out of 
 her sphere? Can she see more than mere appearances, 
 and observe more than mere facts ? Can she penetrate, 
 in some way, to the nature of things ? descend below the 
 surface of phenomena to their causes and origins, so as 
 to be able to say what can and what can not be ; what 
 occurrences are partial, and what universal ? If this be 
 so, we have indeed mistaken her character and powers ; 
 and the whole course of our reasoning becomes pre- 
 carious and obscure. But, then, when we return upon 
 our path we cannot find the point at which we deviated, 
 we cannot detect the false step in our deduction. It 
 still seems that by experience, strictly so called, we 
 cannot discover necessary and universal truths. Our 
 senses can give us no evidence of a necessary connexion 
 in phenomena. Our observation must be limited, and 
 cannot testify concerning anything which is beyond its 
 limits. A general view of our faculties appears to prove 
 
248 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 it to be impossible that men should do what the history 
 of the science of mechanics shows that they have done. 
 
 2. But in order to try to solve this Paradox, let us 
 again refer to the History of Mechanics. In the cases 
 belonging to that science, in which propositions of the 
 most unquestionable universality, and most approaching 
 to the character of necessary truths, (as, for instance, the 
 laws of motion,) have been arrived at, what is the source 
 of the axiomatic character which the propositions thus 
 assume ? The answer to this question will, we may hope, 
 throw some light on the perplexity in which we appear 
 to be involved. 
 
 Now the answer to this inquiry is, that the laws 
 of motion borrow their axiomatic character from their 
 being merely interpretations of the Axioms of Causation. 
 Those axioms, being exhibitions of the Idea of Cause 
 under various aspects, are of the most rigorous univer- 
 sality and necessity. And so far as the laws of motion 
 are exemplifications of those axioms, these laws must be 
 no less universal and necessary. How these axioms are 
 to be understood ; in what sense cause and effect, action 
 and reaction, are to be taken, experience and observa- 
 tion did, in fact, teach inquirers on this subject; and 
 without this teaching, the laws of motion could never 
 have been distinctly known. If two forces act together, 
 each must produce its effect, by the axiom of causation ; 
 and, therefore, the effects of the separate forces must be 
 compounded. But a long course of discussion and expe- 
 riment must instruct men of what kind this composition 
 of forces is. Again ; action and reaction must be equal ; 
 but much thought and some trial were needed to show 
 what action and reaction are. Those metaphysicians who 
 enunciated Laws of motion without reference to expe- 
 rience, propounded only such laws as were vague and 
 inapplicable. But yet these persons manifested the 
 
PARADOX OF UNIVERSAL PROPOSITIONS. 249 
 
 indestructible conviction, belonging to man's speculative 
 nature, that there exist Laws of motion, that is, uni- 
 versal formulae, connecting the causes and effects when 
 motion takes place. Those mechanicians, again, who, 
 observed facts involving equilibrium and motion, and 
 stated some narrow rules, without attempting to ascend 
 to any universal and simple principle, obtained laws no 
 less barren and useless than the metaphysicians; for 
 they could not tell in what new cases, or whether in 
 any, their laws would be verified ; they needed a more 
 general rule, to show them the limits of the rule they 
 had discovered. They went wrong in each attempt to 
 solve a new problem, because their interpretation of 
 the terms of the axioms, though true, perhaps, in certain 
 cases, was not right in general. 
 
 Thus Pappus erred in attempting to interpret as a 
 case of the lever, the problem of supporting a weight 
 upon an inclined plane ; thus Aristotle erred in inter- 
 preting the doctrine that the weight of bodies is the 
 cause of their fall ; thus Kepler erred in interpreting the 
 rule that the velocity of bodies depends upon the force; 
 thus Bernoulli* erred in interpreting the equality of 
 action and reaction upon a lever in motion. In each 
 of these instances, true doctrines, already established, 
 (whether by experiment or otherwise,) were erroneously 
 applied. And the error was corrected by further reflec- 
 tion, which pointed out that another mode of interpreta- 
 tion was requisite, in order that the axiom which was 
 appealed to in each case might retain its force in the 
 most general sense. And in the reasonings which avoided 
 or corrected such errors, and which led to substantial 
 general truths, the object of the speculator always was 
 to give to the acknowledged maxims which the Idea of 
 Cause suggested, such a signification as should be con- 
 * Hist. Ind. Set., B. vi. c. v. sect. 2. 
 
250 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 sistent with their universal validity. The rule was not 
 accepted as particular at the outset, and afterwards gene- 
 ralized more and more widely ; but from the very first, 
 the universality of the rule was assumed, and the ques- 
 tion was, how it should be understood so as to be 
 universally true. At every stage of speculation, the law 
 was regarded as a general law. This was not an aspect 
 which it gradually acquired, by the accumulating con- 
 tributions of experience, but a feature of its original 
 and native character. What should happen universally, 
 experience might be needed to show : but that what 
 happened should happen universally, was implied in the 
 nature of knowledge. The universality of the laws of 
 motion was not gathered from experience, however much 
 the laws themselves might be so. 
 
 3. Thus we obtain the solution of our Paradox, so 
 far as the case before us is concerned. The laws of 
 motion borrow their form from the Idea of Causation, 
 though their matter may be given by experience: and 
 hence they possess a universality which experience cannot 
 give. They are certainly and universally valid ; and the 
 only question for observation to decide is, how they are 
 to be understood. They are like general mathematical 
 formulae, which are known to be true, even while we are 
 ignorant what are the unknown quantities which they 
 involve. It must be allowed, on the other hand, that so 
 long as these formulae are not interpreted by a real 
 study of nature, they are not only useless but prejudi- 
 cial ; filling men's minds with vague general terms, empty 
 maxims, and unintelligible abstractions, which they mis- 
 take for knowledge. Of such perversion of the specula- 
 tive propensities of man's nature, the world has seen too 
 much in all ages. Yet we must not, on that account, 
 despise these forms of truth, since without them, no 
 general knowledge is possible. Without general terms, 
 
PARADOX OF UNIVERSAL PROPOSITIONS. 251 
 
 and maxims, and abstractions, we can have no science, 
 no speculation ; hardly, indeed, consistent thought or 
 the exercise of reason. The course of real knowledge is, 
 to obtain from thought and experience the right inter- 
 pretation of our general terms, the real import of our 
 maxims, the true generalizations which our abstractions 
 involve. 
 
 4. If it be asked, How Experience is able to teach us 
 to interpret aright the general terms which the Axioms 
 of Causation involve ; whence she derives the light 
 which she is to throw on these general notions; the 
 answer is obvious ; namely, that the relations of causa- 
 tion are the conditions of Experience; that the general 
 notions are exemplified in the particular cases of which 
 she takes cognizance. The events which take place 
 about us, and which are the objects of our observation, 
 we cannot conceive otherwise than as subject to the 
 laws of cause and effect. Every event must have a 
 cause; Every effect must be determined by its cause; 
 these maxims are true of the phenomena which form 
 the materials of our experience. It is precisely to them, 
 that these truths apply. It is in the world which we 
 have before our eyes, that these propositions are univer- 
 sally verified ; and it is therefore by the observation of 
 what we see, that we must learn how these propositions 
 are to be understood. Every fact, every experiment, is 
 an example of these statements ; and it is therefore by 
 attention to and familiarity with facts and experiments, 
 that we learn the signification of the expressions in which 
 the statements are made ; just as in any other case we 
 learn the import of language by observing the manner 
 in which it is applied in known cases. Experience is 
 the interpreter of nature ; it being understood that she 
 is to make her interpretation in that comprehensive 
 phraseology which is the genuine language of science. 
 
252 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 5. We may return for an instant to the objection, 
 that experience cannot give us general truths, since, 
 after any number of trials confirming a rule, we may, 
 for aught we can foresee, have one which violates the 
 rule. When we have seen a thousand stones fall to the 
 ground, we may see one which does not fall under the 
 same, apparent circumstances. How then, it is asked, 
 can experience teach us that all stones, rigorously speak- 
 ing, will fall if unsupported? And to this we reply, 
 that it is not true that we can conceive one stone to be 
 suspended in the air, while a thousand others fall, with- 
 out believing some peculiar cause to support it; and 
 that, therefore, such a supposition forms no exception to 
 the law, that gravity is a force by which all bodies are 
 urged downwards. Undoubtedly we can conceive a body, 
 when dropt or thrown, to move in a line quite different 
 from other bodies: thus a certain missile* used by the 
 natives of Australia, and lately brought to this country, 
 when thrown from the hand in a proper manner, de- 
 scribes a curve, and returns to the place from whence it 
 was thrown. But did any one, therefore, even for an 
 instant suppose that the laws of motion are different for 
 this and for other bodies? On the contrary, was not 
 every person of a speculative turn immediately led to 
 inquire how it was that the known causes which modify 
 motion, the resistance of the air and the other causes, 
 produced in this instance so peculiar an effect ? And if 
 the motion had been still more unaccountable, it would 
 not have occasioned any uncertainty whether it were 
 consistent with the agency of gravity and the laws of 
 motion. If a body suddenly alter its direction, or move 
 in any other unexpected manner, we never doubt that 
 there is a cause of the change. We may continue quite 
 ignorant of the nature of this cause, but this ignorance 
 
 * Called the Bo-me-rang. 
 
PARADOX OF UNIVERSAL PROPOSITIONS. 253 
 
 never occasions a moment's doubt that the cause exists 
 and is exactly suited to the effect. And thus experience 
 can prove or discover to us general rules, but she can 
 never prove that general rules do not exist. Anomalies, 
 exceptions, unexplained phenomena, may remind us that 
 we have much still to learn, but they can never make 
 us suppose that truths are not universal. We may ob- 
 serve facts that show us we have not fully understood 
 the meaning of our general laws, but we can never find 
 facts which show our laws to have no meaning. Our 
 experience is bound in by the limits of cause and effect, 
 and can give us no information concerning any region 
 where that relation does not prevail. The whole series 
 of external occurrences and objects, through all time 
 and space, exists only, and is conceived only, as subject 
 to this relation ; and therefore we endeavour in vain to 
 imagine to ourselves when and where and how excep- 
 tions to this relation may occur. The assumption of the 
 connexion of cause abd effect is essential to our expe- 
 rience, as the recognition of the maxims which express 
 this connexion is essential to our knowledge. 
 
 6. I have thus endeavoured to explain in some 
 measure how, at least in the field of our mechanical 
 knowledge, experience can discover universal truths, 
 though she cannot give them their universality; and 
 how such truths, though borrowing their form from our 
 ideas, cannot be understood except by the actual study 
 of external nature. And thus with regard to the laws 
 of motion, and other fundamental principles of Mechanics, 
 the analysis of our ideas and the history of the progress 
 of the science well illustrate each other. 
 
 If the paradox of the discovery of universal truths 
 by experience be thus solved in one instance, a much 
 wider question offers itself to us ; How far the difficulty, 
 and how far the solution, are applicable to other sub- 
 
254 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 jects. It is easy to see that this question involves most 
 grave and extensive doctrines with regard to the whole 
 compass of human knowledge : and the views to which 
 we have been led in the present Book of this work are, 
 we trust, fitted to throw much light upon the general 
 aspect of the subject. But after discussions so abstract, 
 and perhaps obscure, as those in which we have been 
 engaged for some chapters, I willingly postpone to a 
 future occasion an investigation which may perhaps 
 appear to most readers more recondite and difficult 
 still. And we have, in fact, many other special fields 
 of knowledge to survey, before we are led by the order 
 of our subject, to those general questions and doctrines, 
 those antitheses brought into view and again resolved, 
 which a view of the whole territory of human know- 
 ledge suggests, and by which the nature and conditions 
 of knowledge are exhibited. 
 
 Before we quit the subject of mechanical science we 
 shall make a few remarks on another doctrine which 
 forms part of the established truths of the science, 
 namely, the doctrine of universal gravitation. 
 
 CHAPTER IX. 
 
 OF THE ESTABLISHMENT OF THE LAW OF 
 UNIVERSAL GRAVITATION. 
 
 THE doctrine of universal gravitation is a feature of so 
 much importance in the history of science that we shall 
 not pass it by without a few remarks on the nature and 
 evidence of the doctrine. 
 
 1. To a certain extent the doctrine of the attraction 
 of bodies according to the law of the inverse square of 
 the distance, exhibits in its progress among men the 
 
ESTABLISHMENT OF UNIVERSAL GRAVITATION. 255 
 
 same general features which we have noticed in the his- 
 tory of the laws of motion. This doctrine was main- 
 tained a priori on the ground of its simplicity, and as- 
 serted positively, even before it was clearly understood : 
 notwithstanding this anticipation, its establishment 
 on the ground of facts was a task of vast labour and 
 sagacity : when it had been so established in a general 
 way, there occurred at later periods, an occasional sus- 
 picion that it might be approximately true only : these 
 suspicions led to further researches, which showed the 
 rule to be rigorously exact : and at present there are 
 mathematicians who maintain, not only that it is true, 
 but that it is a necessary property of matter. A very 
 few words on each of these points will suffice. 
 
 2. I have shown in the History of Science*, that the 
 attraction of the sun according to the inverse square of 
 the distance, had been divined by Bullialdus, Hooke, 
 H alley, and others, before it was proved by Newton. 
 Probably the reason which suggested this conjecture was, 
 that gravity might be considered as a sort of emanation ; 
 and that thus, like light or any other effect diffused from 
 a center, it must follow the law just stated, the efficacy 
 of the force being weakened in receding from the center, 
 exactly in proportion to the space through which it is 
 diffused. It cannot be denied that such a view appears 
 to be strongly recommended by analogy. 
 
 When it had been proved by Newton that the planets 
 were really retained in their elliptical orbits by a central 
 force, his calculations also showed that the above-stated 
 law of the force must be at least very approximately 
 correct, since otherwise the aphelia of the orbits could 
 not be so nearly at rest as they were. Yet when it 
 seemed as if the motion of the moon's apogee could not 
 be accounted for without some new supposition, the a 
 
 * B. vn. c. i. 
 
256 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 priori argument in favour of the inverse square did not 
 prevent Clairaut from trying the hypothesis of a small 
 term added to that which expressed the ancient law : 
 but when, in order to test the accuracy of this hypothe- 
 sis, the calculation of the motion of the moon's apogee 
 was pushed to a greater degree of exactness than had 
 been obtained before, it was found that the new term 
 vanished of itself; and that the inverse square now ac- 
 counted for the whole of the motion. And thus, as in 
 the case of the second law of motion, the most scrupulous 
 examination terminated in showing the simplest rule to 
 be rigorously true. 
 
 3. Similar events occurred in the history of another 
 part of the law of gravitation : namely, that the attrac- 
 tion is proportional to the quantity of matter attracted. 
 This part of the law may also be thus stated, That the 
 weight of bodies arising from gravity is proportional to 
 their inertia; and thus, that the accelerating force on 
 all bodies under the same circumstances is the same. 
 Newton made experiments which proved this with re- 
 gard to terrestrial bodies ; for he found that, at the end 
 of equal strings, balls of all substances, gold, silver, 
 lead, glass, wood, &c., oscillated in equal times''". But 
 a few years ago, doubts arose among the German astro- 
 nomers whether this law was rigorously true with regard 
 to the planetary bodies. Some calculations appeared 
 to prove, that the attraction of Jupiter as shown by the 
 perturbations which he produces in the small planets 
 Juno, Vesta, and Pallas, was different from the attrac- 
 tion which he exerts on his own satellites. Nor did 
 there appear to these philosophers anything inconceiv- 
 able in the supposition that the attraction of a planet 
 might be thus elective. But when Mr. Airy obtained 
 a more exact determination of the mass of Jupiter, as 
 
 * Prin. Lib. in., Prop. 6. 
 
ESTABLISHMENT OF UNIVERSAL GRAVITATION. 257 
 
 indicated by his effect on his satellites, it was found 
 that this suspicion was unfounded ; and that there was, 
 in this case, no exception to the universality of the rule, 
 that this cosmical attraction is in the proportion of the 
 attracted mass. 
 
 4. Again : when it had thus been shown that a 
 mutual attraction of parts, according to the law above 
 mentioned, prevailed throughout the extent of the solar 
 system, it might still be doubted whether the same law 
 extended to other regions of the universe. It might 
 have been perhaps imagined that each fixed star had 
 its peculiar law of force. But the examination of the 
 motions of double stars about each other, by the two 
 Herschels and others, appears to show that these bodies 
 describe ellipses as the planets do ; and thus extends the 
 law of the inverse squares to parts of the universe im- 
 measurably distant from the whole solar system. 
 
 5. Since every doubt which has been raised with 
 regard to the universality and accuracy of the law of 
 gravitation, has thus ended in confirming the rule, it is 
 not surprizing that men's minds should have returned 
 with additional force to those views which had at first 
 represented the law as a necessary truth, capable of being 
 established by reason alone. When it had been proved 
 by Newton that gravity is really a universal attribute of 
 matter as far as we can learn, his pupils were not con- 
 tent without maintaining it to be an essential quality. 
 This is the doctrine held by Cotes in the preface to the 
 second edition of the Principia (1712): "Gravity," he 
 says, " is a primary quality of bodies, as extension, mo- 
 bility, and impenetrability are." But Newton himself 
 by no means went so far. In his second Letter to 
 Bentley (1693), he says: "You sometimes speak of 
 gravity as essential and inherent to matter; pray do 
 not ascribe that notion to me. The cause of gravity," 
 
 VOL. i. w. P. S 
 
258 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 he adds, " I do not pretend to know, and would take 
 more time to consider of it." 
 
 Cotes maintains his opinion by urging, that we learn 
 by experience that all bodies possess gravity, and that we 
 do not learn in any other way that they are extended, 
 moveable, or solid. But we have already seen, that the 
 ideas of space, time, and reaction, on which depend 
 extension, mobility, and solidity, are not results, but 
 conditions, of experience. We cannot conceive a body 
 except as extended ; we cannot conceive it to exert 
 mechanical action except with some kind of solidity. 
 But so far as our conceptions of body have hitherto 
 been developed, we find no difficulty in conceiving two 
 bodies which do not attract each other. 
 
 6. Newton lays down, in the second edition of the 
 Principia, this " Rule of Philosophizing" (Book in.) ; 
 that "The qualities of bodies which cannot be made 
 more or less intense, and which belong to all bodies on 
 which we are able to make experiments, are to be held 
 to be qualities of all bodies in general." And this Rule 
 is cited in the sixth Proposition of the Third Book of 
 the Principia, (Cor. 2,) in order to prove that gravity, 
 proportional to the quantity of matter, may be asserted 
 to be a quality of all bodies universally. But we may 
 remark that a Rule of Philosophizing, itself of precarious 
 authority, cannot authorize us in ascribing universality 
 to an empirical result. Geometrical and statical pro- 
 perties are seen to be necessary, and therefore universal : 
 but Newton appears disposed to assert a like universality 
 of gravity, quite unconnected with any necessity. It 
 would be a very inadequate statement, indeed a false 
 representation, of statical truth, if we were to say, that 
 because every body which has hitherto been tried has 
 been found to have a center of gravity, we venture to 
 assert that all bodies whatever have a center of gravity. 
 
ESTABLISHMENT OF UNIVERSAL GRAVITATION. 259 
 
 And if we are ever able to assert the absolute univer- 
 sality of the law of gravitation, we shall have to rest 
 this truth upon the clearer developement of our ideas of 
 matter and force ; not upon a Rule of Philosophizing, 
 which, till otherwise proved, must be a mere rule of 
 prudence, and which the opponent may refuse to admit. 
 7. Other persons, instead of asserting gravity to be 
 in its own nature essential to matter, have made hypo- 
 theses concerning some mechanism or other, by which 
 this mutual attraction of bodies is produced*"". Thus 
 the Cartesians ascribed to a vortex the tendency of 
 bodies to a center ; Newton himself seems to have been 
 disposed to refer this tendency to the elasticity of an 
 ether ; Le Sage propounded a curious hypothesis, in 
 which this attraction is accounted for by the impulse 
 of infinite streams of particles flowing constantly through 
 the universe in all directions. In these speculations, 
 the force of gravity is resolved into the pressure or im- 
 pulse of solids or fluids. On the other hand, hypotheses 
 have been propounded, in which the solidity, and other 
 physical qualities of bodies, have been explained by 
 representing the bodies as a collection of points, from 
 which points, repulsive, as well as attractive, forces 
 emanate. This view of the constitution of bodies was 
 maintained and developed by Boscovich, and is hence 
 termed " Boscovich's Theory :" and the discussion of it 
 will more properly come under our review at a future 
 period, when we speak of the question whether bodies 
 are made up of atoms. But we may observe, that New- 
 ton himself appears to have inclined, as his followers 
 certainly did, to this mode of contemplating the physical 
 properties of bodies. In his Preface to the Principia, 
 after speaking of the central forces which are exhibited 
 
 * See Vince, Observations on the Hypothesis respecting Gravitation, 
 and the Critique of that work, Edinb. Rev. Vol. xin. 
 
 S 2 
 
260 PHILOSOPHY OF THE MECHANICAL SCONCES. 
 
 in cosmical phenomena, he says : " Would that we could 
 derive the other phenomena of Nature from mechanical 
 principles by the same mode of reasoning. For many 
 things move me, so that I suspect all these phenomena 
 may depend upon certain forces, by which the particles 
 of bodies, through causes not yet known, are either im- 
 pelled to each other and cohere according to regular 
 figures, or are repelled and recede from each other : 
 which forces being unknown, philosophers have hitherto 
 made their attempts upon nature in vain." 
 
 8. But both these hypotheses ; that by w^hich cohe- 
 sion and solidity are reduced to attractive and repulsive 
 forces, and that by which attraction is reduced to the 
 impulse and pressure of media ; are hitherto merely 
 modes of representing mechanical laws of nature ; and 
 cannot, either of them, be asserted as possessing any evi- 
 dent truth or peremptory authority to the exclusion of 
 the other. This consideration may enable us to estimate 
 the real weight of the difficulty felt in assenting to the 
 mutual attraction of bodies not in contact with each 
 other ; for it is often urged that this attraction of bodies 
 at a distance is an absurd supposition. 
 
 The doctrine is often thus stigmatized, both by popu- 
 lar and by learned writers. It was long received as a 
 maxim in philosophy (as Monboddo informs us '*), that a 
 body cannot act where it is not, any more than when it 
 is not. But to this we reply, that time is a necessary 
 condition of our conception of causation, in a different 
 manner from space. The action of force can only be 
 conceived as taking place in a succession of moments, in 
 each of which cause and effect immediately succeed each 
 other : and thus the interval of time between a cause arid 
 its remote effect is filled up by a continuous succession 
 of events connected by the same chain of causation. But 
 
 * Ancient Metaphysics, Vol. n. p. 175. 
 
ESTABLISHMENT OF UNIVERSAL GRAVITATION. 261 
 
 in space, there is no such visible necessity of continuity ; 
 the action and reaction may take place at a distance from 
 each other; all that is necessary being that they be 
 equal and opposite. 
 
 Undoubtedly the existence of attraction is rendered 
 more acceptable to common apprehension by supposing 
 some intermediate machinery, a cord, or rod, or fluid, 
 by which the forces may be conveyed from one point 
 to another. But such images are rather fitted to satisfy 
 those prejudices which arise from the earlier application 
 of our ideas of force, than to exhibit the real nature of 
 those ideas. If we suppose two bodies to pull each other 
 by means of a rod or a cord, we only suppose, in addition 
 to those equal and opposite forces acting upon the two 
 bodies which forces are alone essential to mutual attrac- 
 tion, a certain power of resisting transverse pressure at 
 every point of the intermediate line : which additional 
 supposition is entirely useless, and quite unconnected 
 with the essential conditions of the case. When the New- 
 tonians were accused of introducing into philosophy an 
 unknown cause which they termed attraction, they justly 
 replied that they knew as much respecting attraction 
 as their opponents did about impulse. In each case we 
 have a knowledge of the conception in question so far as 
 we clearly apprehend it under the conditions of those 
 axioms of mechanical causation which form the basis of 
 our science on such subjects. 
 
 Having thus examined the degree of certainty and 
 generality to which our knowledge of the law of univer- 
 sal gravitation has been carried, by the progress of 
 mechanical discovery and speculation up to the present 
 time, we might proceed to the other branches of science, 
 and examine in like manner their grounds and conditions. 
 But before we do this, it will be worth our while to 
 attend for a moment to the effect which the progress of 
 
262 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 mechanical ideas among mathematicians and mechanical 
 philosophers has produced upon the minds of other per- 
 sons, who share only in an indirect and derivative man- 
 ner in the influence of science. 
 
 CHAPTER X. 
 
 OF THE GENERAL DIFFUSION OF CLEAR 
 MECHANICAL IDEAS. 
 
 1. WE have seen how the progress of knowledge 
 upon the subject of motion and force has produced, in 
 the course of the world's history, a great change in the 
 minds of acute and speculative men ; so that such per- 
 sons can now reason with perfect steadiness and precision 
 upon subjects on which, at first, their thoughts were 
 vague and confused ; and can apprehend, as truths of 
 complete certainty and evidence, laws which it required 
 great labour and time to discover. This complete deve- 
 lopement and clear manifestation of mechanical ideas 
 has taken place only among mathematicians and philo- 
 sophers. But yet a progress of thought upon such 
 subjects, an advance from the obscure to the clear, and 
 from errour to truth, may be traced in the world at 
 large, and among those who have not directly cultivated 
 the exact sciences. This diffused and collateral influence 
 of science manifests itself, although in a wavering and 
 fluctuating manner, by various indications, at various 
 periods of literary history. The opinions and reasonings 
 which are put forth upon mechanical subjects, and above 
 all, the adoption, into common language, of terms and 
 phrases belonging to the prevalent mechanical systems, 
 exhibit to us the most profound discoveries and specula- 
 tions of philosophers in their eifect upon more common 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 263 
 
 and familiar trains of thought. This effect is by no 
 means unimportant, and we shall point out some ex- 
 amples of such indications as we have mentioned. 
 
 2. The discoveries of the ancients in speculative 
 mechanics were, as we have seen, very scanty; and 
 hardly extended their influence to the unmathematical 
 world. Yet the familiar use of the term " center of 
 of gravity" preserved and suggested the most important 
 part of what the Greeks had to teach. The other phrases 
 which they employed, as momentum, energy, virtue, 
 force, and the like, never had any exact meaning, even 
 among mathematicians; and therefore never, in the 
 ancient world, became the means of suggesting just 
 habits of thought. I have pointed out, in the History 
 of Science, several circumstances which appear to denote 
 the general confusion of ideas which prevailed upon 
 mechanical subjects during the times of the Roman 
 empire. I have there taken as one of the examples of 
 this confusion, the fable narrated by Pliny and others 
 concerning the echineis, a small fish, which was said to 
 stop a ship merely by sticking to it*. This story was 
 adduced as betraying the absence of any steady appre- 
 hension of the equality of action and reaction ; since the 
 fish, except it had some immoveable obstacle to hold by, 
 must be pulled forward by the ship, as much as it pulled 
 the ship backward. If the writers who speak of this 
 wonder had shown any perception of the necessity of 
 a reaction, either produced by the rapid motion of the 
 fish's fins in the water, or in any other way, they would 
 not be chargeable with this confusion of thought ; but 
 from their expressions it is, I think, evident that they 
 saw no such necessity f. Their idea of mechanical action 
 
 * Hist. Ind. Sci. B. iv. c. i. sect. 2. 
 
 t See Prof. Powell, On the Nature and Evidence of the Laws of 
 Motion. Reports of the Ashmolean Society. Oxford. 1837- Professor 
 
264 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 was not sufficiently distinct to enable them to see the 
 absurdity of supposing an intense pressure with no 
 obstacle for it to exert itself against. 
 
 3. We may trace, in more modern times also, indica- 
 tions of a general ignorance of mechanical truths. Thus 
 the phrase of shooting at an object "point-blank," im- 
 plies the belief that a cannon-ball describes a path of 
 which the first portion is a straight line. This error 
 was corrected by the true mechanical principles which 
 Galileo and his followers brought to light; but these 
 principles made their way to popular notice, principally 
 in consequence of their application to the motions of the 
 solar system, and to the controversies which took place 
 respecting those motions. Thus by far the most power- 
 ful argument against the reception of the Copernican 
 system of the universe, was that of those who asked, 
 Why a stone dropt from a tower was not left behind by 
 the motion of the earth ? The answer to this question, 
 now universally familiar, involves a reference to the true 
 doctrine of the composition of motions. Again; Kepler's 
 persevering and strenuous attempts'* to frame a phy- 
 sical theory of the universe were frustrated by his igno- 
 rance of the first law of motion, which informs us that 
 a body will retain its velocity without any maintaining 
 force. He proceeded upon the supposition that the sun's 
 force was requisite to keep up the motion of the planets, 
 
 Powell has made an objection to my use of this instance of confusion 
 of thought; the remark in the text seems to me to justify what I said 
 in the History. As an evidence that the fish was not supposed to pro- 
 duce its effect by its muscular power acting on the water, we may take 
 what Pliny says, Nat. Hist., xxxii. 1, " Domat mundi rabiem, nullo 
 suo labore ; non retinendo, aut alio modo quam adhaerendo :" and also 
 what he states in another place (ix. 41,) that when it is preserved in 
 pickle, it may be used in recovering gold which has fallen into a deep 
 well. All this implies adhesion alone, with no conception of reaction. 
 * Hist. Ind. Sci., B. v. c. iv., and B. vn. c. i. 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 265 
 
 as well as to deflect and modify it ; and he was thus 
 led to a system which represented the sun as carrying 
 round the planets in their orbits by means of a vortex, 
 produced by his revolution. The same neglect of the 
 laws of motion presided in the formation of Descartes' 
 system of vortices. Although Descartes had enunciated 
 in words the laws of motion, he and his followers showed 
 that they had not the practical habit of referring to 
 these mechanical principles ; and dared not trust the 
 planets to move in free space without some surrounding 
 machinery to support them*. 
 
 4. When at last mathematicians, following Newton, 
 had ventured to consider the motion of each planet as a 
 mechanical problem not different in its nature from the 
 motion of a stone cast from the hand; and when the 
 solution of this problem and its immense consequences 
 had become matters of general notoriety and interest ; 
 the new views introduced, as is usual, new terms, which 
 soon became extensively current. We meet with such 
 phrases as " flying off in the tangent," and " deflexion 
 from the tangent;" with antitheses between "centripetal" 
 and "centrifugal force," or between "projectile" and 
 " central force." " Centers of force," " disturbing forces," 
 " perturbations," and " perturbations of higher orders," 
 are not unfrequently spoken of: and the expression "to 
 gravitate," and the term " universal gravitation," acquired 
 a permanent place in the language. 
 
 Yet for a long time, and even up to the present day, 
 we find many indications that false and confused appre- 
 hensions on such subjects are by no means extirpated. 
 
 * I have, in the History, applied to Descartes the character which 
 Bacon gives to Aristotle, " Audax simtil et pavidus :" though he was 
 bold enough to enunciate the laws of motion without knowing them 
 aright, he had not the courage to leave the planets to describe their 
 orbits by the agency of those laws, without the machinery of contact. 
 
266 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 Arguments are urged against the mechanical system of 
 the universe, implying in the opponents an absence of 
 all clear mechanical notions. Many of this class of 
 writers retrograde to Kepler's point of view. This is, 
 for example, the case with Lord Monboddo, who, arguing 
 on the assumption that force is requisite to maintain, as 
 well as to deflect motion, produced a series of attacks 
 upon the Newtonian philosophy; which he inserted in 
 his Ancient Metaphysics, published in 1779 and the 
 succeeding years. This writer (like Kepler), measures 
 force by the velocity which the body has*, not by that 
 which its gains. Such a use of language would prevent 
 our obtaining any laws of motion at all. Accordingly, 
 the author, in the very next page to that which I have 
 just quoted, abandons this measure of force, and, in cur- 
 vilinear motion, measures force by "the fall from the 
 extremity of the arc." Again ; in his objections to the 
 received theory, he denies that curvilinear motion is 
 compounded, although his own mode of considering such 
 motion assumes this composition in the only way in 
 which it was ever intended by mathematicians. Many 
 more instances might be adduced to show that a want 
 of cultivation of the mechanical ideas rendered this phi- 
 losopher incapable of judging of a mechanical system. 
 
 The following extract from the Ancient Metaphy- 
 sics, may be sufficient to show the value of the author's 
 criticism on the subjects of which we are now speaking. 
 His object is to prove that there do not exist a centri- 
 petal and a centrifugal force in the case of elliptical 
 motion. "Let any man move in a circular or elliptical 
 line described to him ; and he will find no tendency in 
 himself either to the center or from it, much less both. 
 If indeed he attempt to make the motion with great 
 velocity, or if he do it carelessly and inattentively, he 
 * Anc. Met. Vol n. B. v. c. vi., p. 413. 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 267 
 
 may go out of the line, either towards the center or from 
 it : but this is to be ascribed, not to the nature of the 
 motion, but to our infirmity ; or perhaps to the animal 
 form, which is more fitted for progressive motion in a 
 right line than for any kind of curvilinear motion. But 
 this is not the case with a sphere or spheroid, which is 
 equally adapted to motion in all directions *." We need 
 hardly remind the reader that the manner in which a 
 man running round a small circle, finds it necessary to 
 lean inwards, in order that there may be a centripetal 
 inclination to counteract the centrifugal force, is a 
 standard example of our mechanical doctrines ; and this 
 fact (quite familiar in practice as well as theory,) is in 
 direct contradiction of Lord Monboddo's assertion. 
 
 5. A similar absence of distinct mechanical thought 
 appears in some of the most celebrated metaphysicians 
 of Germany. I have elsewhere noted f the opinion ex- 
 pressed by Hegel, that the glory which belongs to Kepler 
 has been unjustly transferred to Newton ; and I have 
 suggested, as the explanation of this mode of thinking, 
 that Hegel himself, in the knowledge of mechanical 
 truth, had not advanced beyond Kepler's point of view. 
 Persons who possess conceptions of space and number, 
 but who have not learnt to deal with ideas of force and 
 causation, may see more value in the discoveries of Kepler 
 than in those of Newton. Another exemplification of 
 this state of mind may be found in Mr. Schellings spe- 
 culations ; for instance, in his Lectures on the Method of 
 Academical Study. In the twelfth Lecture, on the Study 
 of Physics and Chemistry, he says, (p. 266,) " What the 
 mathematical natural philosophy has done for the know- 
 ledge of the laws of the universe since the time that 
 they were discovered by his (Kepler's) godlike genius, is, 
 
 * Anc. Met., Yol. i. B. ii. c. 19, p. 264. 
 t Hist. Ind. Sci., B. vu. c. ii. sect. 5. 
 
268 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 as is well known, this: it has attempted a construction 
 of those laws which, according to its foundations, is alto- 
 gether empirical. We may assume it as a general rule, 
 that in any proposed construction, that which is not a 
 pure general form cannot have any scientific import 
 or truth. The foundation from which the centrifugal 
 motion of the bodies of the world is derived, is no ne- 
 cessary form, it is an empirical fact. The Newtonian 
 attractive force, even if it be a necessary assumption for 
 a merely reflective view of the subject, is still of no 
 significance for the Reason, which recognizes only abso- 
 lute relations. The grounds of the Keplerian laws can 
 be derived, without any empirical appendage, purely 
 from the doctrine of Ideas, and of the two Unities, which 
 are in themseves one Unity, and in virtue of which each 
 being, while it is absolute in itself, is at the same time 
 in the absolute, and reciprocally." 
 
 It will be observed, that in this passage our mecha- 
 nical laws are objected to because they are not necessary 
 results of our ideas ; which, however, as we have seen, 
 according to the opinion of some eminent mechanical 
 philosophers, they are. But to assume this evident 
 necessity as a condition of every advance in science, is 
 to mistake the last, perhaps unattainable step, for the 
 first, which lies before our feet. And, without inquiring 
 further about " the Doctrine of the two Unities," or the 
 manner in which from that doctrine we may deduce the 
 Keplerian laws, we may be well convinced that such a 
 doctrine cannot supply any sufficient reason to induce us 
 to quit the inductive path by which all scientific truth 
 up to the present time has been acquired. 
 
 6. But without going to schools of philosophy oppo- 
 sed to the Inductive School, we may find many loose and 
 vague habits of thinking on mechanical subjects among 
 the common classes of readers and reasoners. And 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 269 
 
 there are some familiar modes of employing the phrase- 
 ology of mechanical science, which are, in a certain 
 degree, chargeable with inaccuracy, and may produce 
 or perpetuate confusion. Among such cases we may 
 mention the way in which the centripetal and centri- 
 fugal forces, and also the projectile and central forces 
 of the planets, are often compared or opposed. Such 
 antitheses sometimes proceed upon the false notion that 
 the two members of these pairs of forces are of the 
 same kind : whereas on the contrary the projectile force 
 is a hypothetical impulsive force which may, at some 
 former period, have caused the motion to begin ; while 
 the central force is an actual force, which must act con- 
 tinuously and during the whole time of the motion, in 
 order that the motion may go on in the curve. In the 
 same manner the centrifugal force is not a distinct force 
 in a strict sense, but only a certain result of the first 
 law of motion, measured by the portion of centripetal 
 force which counteracts it. Comparisons of quantities 
 so heterogeneous imply confusion of thought, and often 
 suggest baseless speculations and imagined reforms of 
 the received opinions. 
 
 7. I might point out other terms and maxims, in 
 addition to those already mentioned, which, though for- 
 merly employed in a loose and vague manner, are now 
 accurately understood and employed by all just thinkers; 
 and thus secure and diffuse a right understanding of me- 
 chanical truths. Such are momentum, inertia, quantity 
 of matter, quantity of motion; thai force is proportional 
 to its effects; that action and reaction are equal; that 
 what is gained in force by machinery is lost in time ; 
 that the quantity of motion in the world cannot be either 
 increased or diminished. When the expression of the 
 truth thus becomes easy and simple, clear and con- 
 vincing, the meanings given to words and phrases by 
 
270 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 discoverers glide into the habitual texture of men's rea- 
 sonings, and the effect of the establishment of true 
 mechanical principles is felt far from the school of the 
 mechanician. If these terms and maxims are understood 
 with tolerable clearness, they carry the influence of 
 truth to those who have no direct access to its sources. 
 Many an extravagant project in practical machinery, and 
 many a wild hypothesis in speculative physics, has been 
 repressed by the general currency of such maxims as we 
 have just quoted. 
 
 8. Indeed so familiar and evident are the elementary 
 truths of mechanics when expressed in this simple form, 
 that they are received as truisms ; and men are disposed 
 to look back with surprize and scorn at the speculations 
 which were carried on in neglect of them. The most 
 superficial reasoner of modern times thinks himself enti- 
 tled to speak with contempt and ridicule of Kepler's 
 hypothesis concerning the physical causes of the celestial 
 motions: and gives himself credit for intellectual supe- 
 riority, because he sees, as self-evident, what such a man 
 could not discover at all. It is well for such a person to 
 recollect, that the real cause of his superior insight is 
 not the pre-eminence of his faculties, but the successful 
 labours of those who have preceded him. The language 
 which he has learnt to use unconsciously, has been 
 adapted to, and moulded on, ascertained truths. When 
 he talks familiarly of " accelerating forces" and " de- 
 flexions from the tangent," he is assuming that which 
 Kepler did not know, and which it cost Galileo and his 
 disciples so much labour and thought to establish. Lan- 
 guage is often called an instrument of thought ; but it 
 is also the nutriment of thought; or rather, it is the 
 atmosphere in which thought lives : a medium essential 
 to the activity of our speculative power, although invi- 
 sible and imperceptible in its operation ; and an element 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 271 
 
 modifying, by its qualities and changes, the growth and 
 complexion of the faculties which it feeds. In this way 
 the influence of preceding discoveries upon subsequent 
 ones, of the past upon the present, is most penetrating 
 and universal, though most subtle and difficult to trace. 
 The most familiar words and phrases are connected by 
 imperceptible ties with the reasonings and discoveries of 
 former men and distant times. Their knowledge is an 
 inseparable part of ours ; the present generation inherits 
 and uses the scientific wealth of all the past. And this 
 is the fortune, not only of the great and rich in the 
 intellectual world : of those who have the key to the 
 ancient storehouses, and who have accumulated treasures 
 of their own; but the humblest inquirer, while he 
 puts his reasonings into words, benefits by the labours 
 of the greatest discoverers. When he counts his little 
 wealth, he finds that he has in his hands coins which 
 bear the image and superscription of ancient and modern 
 intellectual dynasties ; and that in virtue of this posses- 
 sion, acquisitions are in his power, solid knowledge 
 within his reach, which none could ever have attained 
 to, if it were not that the gold of truth, once dug out of 
 the mine, circulates more and more widely among man- 
 kind. 
 
 9. Having so fully examined, in the preceding in- 
 stances, the nature of the progress of thought which 
 science implies, both among the peculiar cultivators of 
 science, and in that wider world of general culture which 
 receives only an indirect influence from scientific disco- 
 veries, we shall not find it necessary to go into the same 
 extent of detail with regard to the other provinces of 
 human knowledge. In the case of the Mechanical 
 Sciences, we have endeavoured to show, not only that 
 Ideas are requisite in order to form into a science the 
 Facts which nature offers to us, but that we can advance, 
 
272 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 almost or quite, to a complete identification of the Facts 
 with the Ideas. In the sciences to which we now pro- 
 ceed, we shall not seek to fill up the chasm by which 
 Facts and Ideas are separated ; but we shall endeavour 
 to detect the Ideas which our knowledge involves, to 
 show how essential these are ; and in some respects to 
 trace the mode in which they have been gradually de- 
 veloped among men. 
 
 10. The motions of the heavenly bodies, their laws, 
 their causes, are among the subjects of the first division 
 of the Mechanical Sciences ; and of these sciences we 
 formerly sketched the history, and have now endeavoured 
 to exhibit the philosophy. If we were to take any other 
 class of motions, their laws and causes might give rise 
 to sciences which would be mechanical sciences in exactly 
 the same sense in which Physical Astronomy is so. The 
 phenomena of magnets, of electrical bodies, of galva- 
 nical apparatus, seem to form obvious materials for such 
 sciences ; and if they were so treated, the philosophy of 
 such branches of knowledge would naturally come under 
 our consideration at this point of our progress. 
 
 But on looking more attentively at the sciences of 
 Electricity, Magnetism, and Galvanism, we discover 
 cogent reasons for transferring them to another part of 
 our arrangement ; we find it advisable to associate them 
 with Chemistry, and to discuss their principles when 
 we can connect them with the principles of chemical 
 science. For though the first steps and narrower gene- 
 ralizations of these sciences depend upon mechanical 
 ideas, the highest laws and widest generalizations which 
 we can reach respecting them, involve chemical rela- 
 tions. The progress of these portions of knowledge is 
 in some respects opposite to the progress of Physical 
 Astronomy. In this, we begin with phenomena which 
 appear to indicate peculiar and various qualities in the 
 
DIFFUSION OF CLEAR MECHANICAL IDEAS. 273 
 
 bodies which we consider, (namely, the heavenly bodies,) 
 and we find in the end that all these qualities resolve 
 themselves into one common mechanical property, which 
 exists alike in all bodies and parts of bodies. On the 
 contrary, in studying magnetical and electrical laws, we 
 appear at first to have a single extensive phenomenon, 
 attraction and repulsion : but in our attempts to gene- 
 ralize this phenomenon, we find that it is governed by 
 conditions depending upon something quite separate 
 from the bodies themselves, upon the presence and dis- 
 tribution of peculiar and transitory agencies ; and, so far 
 as we can discover, the general laws of these agencies 
 are of a chemical nature, and are brought into action by 
 peculiar properties of special substances. In cosmical 
 phenomena, everything, in proportion as it is referred to 
 mechanical principles, tends to simplicity, to permanent 
 uniform forces, to one common, positive, property. In 
 magnetical and electrical appearances, on the contrary, 
 the application of mechanical principles leads only to 
 a new complexity, which requires a new explanation; 
 and this explanation involves changeable and various 
 forces, gradations and oppositions of qualities. The 
 doctrine of the universal gravitation of matter is a simple 
 and ultimate truth, in which the mind can acquiesce 
 and repose. We rank gravity among the mechanical 
 attributes of matter, and we see no necessity to derive 
 it from any ulterior properties. Gravity belongs to mat- 
 ter, independent of any conditions. But the conditions of 
 magnetic or electrical activity require investigation as 
 much as the laws of their action. Of these conditions 
 no mere mechanical explanation can be given ; we are 
 compelled to take along with us chemical properties 
 and relations also : and thus magnetism, electricity, gal- 
 vanism, are wiechanico-chemical sciences. 
 
 11. Before considering these, therefore, I shall treat 
 VOL. i. w. P. T 
 
274 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 of what I shall call Secondary Mechanical Sciences ; by 
 which expression I mean the sciences depending upon 
 certain qualities which our senses discover to us in 
 bodies; Optics, which has visible phenomena for its 
 subject; Acoustics, the science of hearing; the doctrine 
 of Heat, a quality which our touch recognizes : to this 
 last science I shall take the liberty of sometimes giving 
 the name Thermotics, analogous to the names of the 
 other two. If our knowledge of the phenomena of Smell 
 and Taste had been successfully cultivated and syste- 
 matized, the present part of our work would be the 
 place for the philosophical discussion of those sensations 
 as the subjects of science. 
 
 The branches of knowledge thus grouped in one class 
 involve common Fundamental Ideas, from which their 
 principles are derived in a mode analogous, at least in 
 a certain degree, to the mode in which the principles of 
 the mechanical sciences are derived from the funda- 
 mental ideas of causation and reaction. We proceed 
 now to consider these Fundamental Ideas, their nature, 
 development, and consequences. 
 
 ADDITIONAL NOTE TO CHAPTER IV. ON THE AXIOMS 
 WHICH RELATE TO THE IDEA OF CAUSE. 
 
 THE Axiom that Reaction is equal and opposite to Action, may appear 
 to be at variance with a maxim concerning Cause which is commonly 
 current ; namely, that the " Cause precedes Effect, and Effect follows 
 Cause." For it may be said, if A, the Action, arid R, the Reaction, can 
 be considered as mutually the cause of each other, A must precede R, 
 and yet must follow it, which is impossible. But to this I reply, that 
 in those cases of direct Causation to which the maxim applies, the Cause 
 and Effect are not successive, but simultaneous. If I press against some 
 obstacle, the obstacle resists and returns the pressure at the instant it is 
 exerted, not after any interval of time, however small. The common 
 
NOTES ON CHAPTERS IV. AND VI. 275 
 
 maxim, that the effect follows the cause, has arisen from the practice of 
 considering, as examples of cause and effect, not instantaneous forces or 
 causes, and the instantaneous changes which they produce ; but taking, 
 instead of this latter, the cumulative effects produced in the course of 
 time, and compared with like results occurring without the action of the 
 cause. Thus, if we alter the length of a clock-pendulum, this change 
 produces, as its effect, a subsequent change of rate in the clock : because 
 the rate is measured by the accumulated effects of the pendulum's gravity, 
 before and after the change. But the pendulum produces its mechanical 
 effect upon the escapement, at the moment of its contact, and each 
 wheel upon the next, at the moment of its contact. As has been said 
 in a Review of this work, " The time lost in cases of indirect physical 
 causation is consumed in the movements which take place among the 
 parts of the mechanism in action, by which the active forces so trans- 
 formed into momentum are transported over intervals of space to new 
 points of action, the motion of matter in such cases being regarded as a 
 mere carrier of force." (Quarterly Rev., No. cxxxv., p. 212.) See this 
 subject further treated in a Memoir entitled, " Discussion of the Ques- 
 tion : Are Cause and Effect Successive or Simultaneous ?" in the 
 Memoirs of the Cambridge Philosophical Society, Vol. vu. Part iii. 
 
 ADDITIONAL NOTE TO CHAPTER VI., SECT. 5. ON 
 THE CENTER OF GRAVITY. 
 
 To the doctrine that mechanical principles, such as the one here under 
 consideration (that the pressure on the point of support is equal to the 
 sum of the weights), are derived from our Ideas, and do not flow from 
 but regulate our experience, objections are naturally made by those who 
 assert all our knowledge to be derived from experience. How, they ask, 
 can we know the properties of pressures, levers and the like, except 
 from experience? What but experience can possibly inform us that a 
 force applied transversely to a lever will have any tendency to turn the 
 lever on its center ? This cannot be, except we suppose in the lever 
 tenacity, rigidity and the like, which are qualities known only by 
 experience. And it is obvious that this line of argument might be 
 carried on through the whole subject. 
 
 My answer to this objection is a remark of the same kind as one 
 which I have made respecting the Ideas of Space, Time, and Number, 
 in a Note at the end of Chapter x. of the last Book. The mind, in 
 apprehending events as causes and effects, is governed by Laws of its 
 own Activity ; and these Laws govern the results of the mind's action ; 
 
 T 2 
 
276 PHILOSOPHY OF THE MECHANICAL SCIENCES. 
 
 and make these results conform to the Axioms of Causation. But this 
 activity of the mind is awakened and developed by being exercised ; 
 and in dealing with the examples of cause and effect here spoken of, 
 (namely, pressure and resistance, force and motion,) the mind's activity 
 is necessarily governed also by the bodily powers of perception and 
 action. We are human beings only in so far as we have existed in space 
 and time, and of our human faculties, developed by our existence in space 
 and time, space and time arc necessary conditions. In like manner, we 
 are human beings only in so far as we have bodies, and bodily organs ; 
 and our bodies necessarily imply material objects external to us. And 
 hence our human faculties, developed by our bodily existence in a 
 material world, have the conditions of matter for their necessary Laws. 
 I have already said (Chap, v.) that our conception of Force arises with 
 our consciousness of our own muscular exertions; that Force cannot 
 be conceived without Resistance to exercise itself upon ; and that this 
 resistance is supplied by Matter. And thus the conception of Matter, 
 and of the most general modes in which Matter receives, resists, and 
 transmits force, are parts of our constitution which, though awakened 
 and unfolded by our being in a material world, are not distinguishable 
 from the original structure of the mind. I do not ascribe to the 
 mind Ideas which it would have, even if it had no intercourse with 
 the world of space, time, and matter; because we cannot imagine a 
 mind in such a state. But I attempt to point out and classify those 
 Conditions of all Experience, to which the intercourse of all minds with 
 the material world has necessarily given rise in all. Truths thus neces- 
 sarily acquired in the course of all experience, cannot be said to be 
 learnt from experience^ in the same sense in which particular facts, at 
 definite times, are learnt from experience, learnt by some persons and 
 not by others, learnt with more or less of certainty. These latter 
 special truths of experience will be very important subjects of our con- 
 sideration; but our whole chance of discussing them with any profit 
 depends upon our keeping them distinct from the necessary and uni- 
 versal conditions of experience. Here, as everywhere, we must keep 
 in view the fundamental antithesis of Ideas and Facts. 
 
277 
 
 BOOK IV. 
 
 THE PHILOSOPHY OF THE SECONDARY 
 MECHANICAL SCIENCES. 
 
 CHAPTER I. 
 
 OF THE IDEA OF A MEDIUM AS COMMONLY 
 EMPLOYED. 
 
 1. Of Primary and Secondary Qualities. IN the 
 same way in which the mechanical sciences depend upon 
 the Idea of Cause, and have their principles regulated 
 by the development of that Idea, it will be found that 
 the sciences which have for their subject Sound, Light, 
 and Heat, depend for their principles upon the Funda- 
 mental Idea of Media by means of which we perceive 
 those qualities. Like the idea of cause, this idea of a 
 medium is unavoidably employed, more or less distinctly, 
 in the common, unscientific operations of the under- 
 standing; and is recognized as an express principle in 
 the earliest speculative essays of man. But here also, 
 as in the case of the mechanical sciences, the develope- 
 ment of the idea, and the establishment of the scientific 
 truths which depend upon it, was the business of a 
 succeeding period, and was only executed by means of 
 long and laborious researches, conducted with a constant 
 reference to experiment and observation. 
 
 Among the most prominent manifestations of the 
 influence of the idea of a medium of which we have 
 now to speak, is the distinction of the qualities into 
 
278 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 primary r , and secondary qualities. This distinction has 
 been constantly spoken of in modern times : yet it has 
 often been a subject of discussion among metaphysicians 
 whether there be really such a distinction, and what the 
 true difference is. Locke states it thus* : original or 
 primary qualities of bodies are " such as are utterly in- 
 separable from the body in what estate soever it may 
 be, such as sense constantly finds in every particle of 
 matter which has bulk enough to be perceived, and the 
 mind finds inseparable from every particle of matter, 
 though less than to make itself singly perceived by our 
 senses :" and he enumerates them as solidity, extension, 
 figure, motion or rest, and number. Secondary qualities, 
 on the other hand, are such "which in truth are nothing 
 in the objects themselves, but powers to produce various 
 sensations in us by their primary qualities, i. e., by the 
 bulk, figure, texture, and motion of their insensible 
 parts, as colours, sounds, tastes, &c." 
 
 Dr. Reidf, reconsidering this subject, puts the differ- 
 ence in another way. There is, he says, a real foundation 
 for the distinction of primary and secondary qualities, 
 and it is this : " That our senses give us a direct and dis- 
 tinct notion of the primary qualities, and inform us what 
 they are in themselves ; but of the secondary qualities, 
 our senses give us only a relative and obscure notion. 
 They inform us only that they are qualities that affect us 
 in a certain manner, that is, produce in us a certain sen- 
 sation ; but as to what they are in themselves, our senses 
 leave us in the dark." 
 
 Dr. Brown J states the distinction somewhat other- 
 wise. We give the name of matter, he observes, to that 
 which has extension and resistance : these, therefore, are 
 primary qualities of matter, because they compose our 
 
 * Essay, B. n. ch. viii. s. 9, 10. t Essays, B. n. c. xvii. 
 
 J Lectures, n. 12. 
 
OF THE IDEA OF A MEDIUM. 279 
 
 definition of it. All other qualities are secondary, since 
 they are ascribed to bodies only because we find them 
 associated with the primary qualities which form our 
 notion of those bodies. 
 
 It is not necessary to criticize very strictly these vari- 
 ous distinctions. If it were, it would be easy to find 
 objections to them. Thus Locke, it may be observed, 
 does not point out any reason for believing that his 
 secondary qualities are produced by the primary. How 
 are we to learn that the colour of a rose arises from the 
 bulk, figure, texture, and motion of its particles ? Cer- 
 tainly our senses do not teach us this; and in what other 
 way, on Locke's principles, can we learn it? Reid's 
 statement is not more free from the same objection. 
 How does it appear that our notion of Warmth is rela- 
 tive to our own sensations more than our notion of 
 Solidity ? And if we take Brown's account, we may still 
 ask whether our selection of certain qualities to form 
 our idea and definition of matter be arbitrary and with- 
 out reason? If it be, how can it make a real distinction? 
 if it be not, what is the reason ? 
 
 I do not press these objections, because I believe that 
 any of the above accounts of the distinction of primary 
 and secondary qualities is right in the main, however 
 imperfect it may be. The difference between such 
 qualities as Extension and Solidity on the one hand, 
 and Colour or Fragrance on the other, is assented to 
 by all, with a conviction so firm and indestructible, that 
 there must be some fundamental principle at the bottom 
 of the belief, however difficult it may be to clothe the 
 principle in words. That successive efforts to express 
 the real nature of the difference were made by men so 
 clear-sighted and acute as those whom I have quoted, 
 even if none of them are satisfactory, shows how strong 
 and how deeply-seated is the perception of truth which 
 impels us to such attempts. 
 
280 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 The most obvious mode of stating the difference of 
 primary and secondary qualities, as it naturally offers 
 itself to speculative minds, appears to be that employed 
 by Locke, slightly modified. Certain of the qualities of 
 bodies, as their bulk, figure, and motion, are perceived 
 immediately in the bodies themselves. Certain other 
 qualities as sound, colour, heat, are p'erceived by means 
 of some medium. Our conviction that this is the case 
 is spontaneous and irresistible ; and this difference of 
 qualities immediately and mediately perceived is the dis- 
 tinction of primary and secondary qualities. We proceed 
 further to examine this conviction. 
 
 2. The Idea of Externality. In reasoning concern- 
 ing the secondary qualities of bodies, we are led to assume 
 the bodies to be external to us, and to be perceived by 
 means of some medium intermediate between us and 
 them. These assumptions are fundamental conditions 
 of perception, inseparable from it even in thought. 
 
 That objects are external to us, that they are without 
 us, that they have outness, is as clear as it is that these 
 words have any meaning at all. This conviction is, in- 
 deed, involved in the exercise of that faculty by which 
 we perceive all things as existing in space ; for by this 
 faculty we place ourselves and other objects in one com- 
 mon space, and thus they are exterior to us. It may be 
 remarked that this apprehension of objects as external 
 to us, although it assumes the idea of space, is far from 
 being implied in the idea of space. The objects which 
 we contemplate are considered as existing in space, and 
 by that means become invested with certain mutual rela- 
 tions of position ; but when we consider them as existing 
 without us, we make the additional step of supposing 
 ourselves and the objects to exist in one common space. 
 The question respecting the Ideal Theory of Berkeley has 
 been mixed up with the recognition of this condition of 
 the externality of objects. That philosopher maintained, 
 
OF THE IDEA OF A MEDIUM. 281 
 
 as is well known, that the perceptible qualities of bodies 
 have no existence except in a perceiving mind. This 
 system has often been understood as if he had imagined 
 the world to be a kind of optical illusion, like the images 
 which we see when we shut our eyes, appearing to be 
 without us, though they are only in our organs; and 
 thus this Ideal System has been opposed to a belief in 
 an external world. In truth, however, no such opposi- 
 tion exists. The Ideal System is an attempt to explain 
 the mental process of perception, and to get over the 
 difficulty of mind being affected by matter. But the 
 author of that system did not deny that objects were 
 perceived under the conditions of space and mechanical 
 causation ; that they were external and material so far 
 as those words describe perceptible qualities. Berkeley's 
 system, however visionary or erroneous, did not prevent 
 his entertaining views as just, concerning optics or acous- 
 tics, as if he had held any other doctrine of the nature 
 of perception. 
 
 But when Berkeley's theory was understood as a 
 denial of the existence of objects without us, how was it 
 answered ? If we examine the answers which are given 
 by Reid and other philosophers to this hypothesis, it will 
 be found that they amount to this : that objects are 
 without us, since we perceive that they are so ; that we 
 perceive them to be external, by the same act by which 
 we perceive them to be objects. And thus, in this stage 
 of philosophical inquiry, the externality of objects is re- 
 cognized as one of the inevitable conditions of our per- 
 ception of them ; and hence the Idea of Externality is 
 adopted as one of the necessary foundations of all rea- 
 soning concerning all objects whatever. 
 
 3. Sensation by a Medium. Objects, as we have just 
 seen, are necessarily apprehended as without us ; and in 
 general, as removed from us by a great or small distance. 
 
282 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 Yet they affect our bodily senses ; and this leads us ir- 
 resistibly to the conviction that they are perceived by 
 means of something intermediate. Vision, or hearing, 
 or smell, or the warmth of a fire, must be communicated 
 to us by some medium of sensation. This unavoidable 
 belief appears in all attempts, the earliest and the latest 
 alike, to speculate upon such subjects. Thus, for in- 
 stance, Aristotle says *, " Seeing takes place in virtue of 
 some action which the sentient organ suffers : now it 
 cannot suffer action from the colour of the object di- 
 rectly : the only remaining possible case then is, that it 
 is acted upon by an intervening Medium ; there must 
 then be an intervening Medium." " And the same may 
 be said," he adds, " concerning sounding and odorous 
 bodies ; for these do not produce sensation by touching 
 the sentient organ, but the intervening Medium is acted 
 on by the sound or the smell, and the proper organ, by 
 the Medium.. ..In sound the Medium is air; in smell we 
 have no name for it." In the sense of taste, the neces- 
 sity of a Medium is not at first so obviously seen, because 
 the object tasted is brought into contact with the organ ; 
 but a little attention convinces us that the taste of a 
 solid body can only be perceived when it is conveyed 
 in some liquid vehicle. Till the fruit is crushed, and 
 till its juices are pressed out, we do not distinguish its 
 flavour. In the case of heat, it is still more clear that 
 we are compelled to suppose some invisible fluid, or 
 other means of communication, between the distant body 
 which warms us and ourselves. 
 
 It may appear to some persons that the assumption 
 of an intermedium between the object perceived and the 
 sentient organ results from the principles which form 
 the basis of our mechanical reasonings, that every 
 change must have a cause, and that bodies can act upon 
 
 IL 7- 
 
OF THE IDEA OF A MEDIUM. 283 
 
 each other only by contact. It cannot be denied that 
 this principle does offer itself very naturally as the 
 ground of our belief in media of sensation ; and it appears 
 to be referred to for this purpose by Aristotle in the 
 passage quoted above. But yet we cannot but ask, 
 Does the principle, that matter produces its effect by 
 contact only, manifestly apply here ? When we so apply 
 it, we include sensation among the effects which material 
 contact produces ; a case so different from any merely 
 mechanical effect, that the principle, so employed, ap- 
 pears to acquire a new signification. May we not, then, 
 rather say that we have here a new axiom, That sensa- 
 tion implies a material cause immediately acting on the 
 organ, than a new application of our former proposi- 
 tion, That all mechanical change implies contact ? 
 
 The solution of this doubt is not of any material con- 
 sequence to our reasonings ; for whatever be the ground 
 of the assumption, it is certain that we do assume the 
 existence of media by which the sensations of sight, 
 hearing, and the like, are produced ; and it will be seen 
 shortly that principles inseparably connected with this 
 assumption are the basis of the sciences now before us. 
 
 This assumption makes its appearance in the physical 
 doctrines of all the schools of philosophy. It is ex- 
 hibited perhaps most prominently in the tenets of the 
 Epicureans, who were materialists, and extended to all 
 kinds of causation the axiom of the existence of a cor- 
 poreal mechanism by which alone the effect is produced. 
 Thus, according to them, vision is produced by certain 
 images or material films which flow from the object, 
 strike upon the eyes, and so become sensible. This 
 opinion is urged with great detail and earnestness by 
 Lucretius, the poetical expositor of the Epicurean creed 
 among the Romans. His fundamental conviction of the 
 necessity of a material medium is obviously the basis of 
 
284 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 his reasoning, though he attempts to show the existence 
 of such a medium by facts. Thus he argues *, that by 
 shouting loud we make the throat sore ; which shows, 
 he says, that the voice must be material, so that it can 
 hurt the passage in coming out. 
 
 Hand igitur dubium est quin voces verbaque constent 
 Corporeis e principiis ut laedere possint. 
 
 4. The Process of Perception of Secondary Quali- 
 ties. The likenesses or representatives of objects by 
 which they affect our senses were called by some writers 
 species, or sensible species, a term which continued in 
 use till the revival of science. It may be observed that 
 the conception of these species as films cast off from the 
 object, and retaining its shape, was different, as we have 
 seen, from the view which Aristotle took, though it has 
 sometimes been called the Peripatetic doctrine f. We 
 may add that the expression was latterly applied to 
 express the supposition of an emanation of any kind, and 
 implied little more than that supposition of a medium 
 of which we are now speaking. Thus Bacon, after re- 
 viewing the phenomena of sound, says \, " Videntur 
 motus soni fieri per species spirituals : ita enim loquen- 
 dum donee certius quippiam inveniatur." 
 
 Though the fundamental principles of several sciences 
 depend upon the assumption of a medium of perception, 
 these principles do not at all depend upon any special 
 view of the process of our perceptions. The mechanism 
 of that process is a curious subject of consideration ; but 
 it belongs to physiology, more properly than either to 
 metaphysics, or to those branches of physics of which we 
 are now speaking. The general nature of the process is 
 the same for all the senses. The object affects the ap- 
 propriate intermedium ; the medium, through the proper 
 
 * Lib. iv. 529 t Brown, Vol. n. p. 98. 
 
 $ Hist. Son. el And., Vol. ix. p. 87. 
 
OF THE IDEA OF A MEDIUM. 285 
 
 organ, the eye, the ear, the nose, affects the nerves of 
 the particular sense ; and, by these, in some way, the 
 sensation is conveyed to the mind. But to treat the 
 impression upon the nerves as the act of sensation which 
 we have to consider, would be to mistake our object, 
 which is not the constitution of the human body, but of 
 the human mind. It would be to mistake one link for 
 the power which holds the end of the chain. No anato- 
 mical analysis of the corporeal conditions of vision, or 
 hearing, or feeling warm, is necessary to the sciences of 
 Optics, or Acoustics, or Thermotics. 
 
 Not only is this physiological research an extraneous 
 part of our subject, but a partial pursuit of such a 
 research may mislead the inquirer. We perceive objects 
 by means of certain media, and by means of certain 
 impressions on the nerves : but we cannot with pro- 
 priety say that we perceive either the media or the 
 impressions on the nerves. What person in the act of 
 seeing is conscious of the little coloured spaces on the 
 retina? or of the motions of the bones of the auditory 
 apparatus whilst he is hearing? Surely, no one. This 
 may appear obvious enough, and yet a writer of no 
 common acuteness, Dr. Brown, has put forth several 
 very strange opinions, all resting upon the doctrine that 
 the coloured spaces on the retina are the objects which 
 we perceive; and there are some supposed difficulties 
 and paradoxes on the same subject which have become 
 quite celebrated (as upright vision with inverted images), 
 arising from the same confusion of thought. 
 
 As the consideration of the difficulties which have 
 arisen respecting the philosophy of perception may serve 
 still further to illustrate the principles on which we 
 necessarily reason respecting the secondary qualities of 
 bodies, I shall here devote a few pages to that subject. 
 
286 
 
 CHAPTER II. 
 
 ON PECULIARITIES IN THE PERCEPTIONS OF 
 THE DIFFERENT SENSES. 
 
 1. WE cannot doubt that we perceive all secondary 
 qualities by means of immediate impressions made, 
 through the proper medium of sensation, upon our 
 organs. Hence all the senses are sometimes vaguely 
 spoken of as modifications of the sense of feeling. It 
 will, however, be seen, on reflection, that this mode of 
 speaking identifies in words things which in our concep- 
 tions have nothing in common. No impression on the 
 organs of touch can be conceived as having any resem- 
 blance to colour or smell. No effort, no ingenuity, can 
 enable us to describe the impressions of one sense in 
 terms borrowed from another. 
 
 The senses have, however, each its peculiar powers, 
 and these powers may be in some respects compared, so 
 as to show their leading resemblances and differences, 
 and the characteristic privileges and laws of each. This 
 is what we shall do as briefly as possible. 
 
 SECT. I. Prerogatives of Sight. 
 
 THE sight distinguishes colours, as the hearing distin- 
 guishes tones ; the sight estimates degrees of brightness, 
 the ear, degrees of loudness ; but with several resem- 
 blances, there are most remarkable differences between 
 these two senses. 
 
 2. Position. The sight has this peculiar prerogative, 
 that it apprehends the place of its objects directly and 
 primarily. We see where an object is at the same in- 
 stant that we see what it is. If we see two objects, we 
 see their relative position. We cannot help perceiving 
 
PECULIARITIES OF THE PERCEPTIONS. 287 
 
 that one is above or below, to the right or to the left of 
 the other, if we perceive them at all. 
 
 There is nothing corresponding to this in sound. 
 When we hear a noise, we do not necessarily assign a 
 place to it. It may easily happen that we cannot tell 
 from which side a thunder-clap comes. And though we 
 often can judge in what direction a voice is heard, this is 
 a matter of secondary impression, and of inference from 
 concomitant circumstances, not a primary fact of sensa- 
 tion. The judgments which we form concerning the 
 position of sounding bodies are obtained by the con- 
 scious or unconscious comparison of the impressions 
 made on the two ears, and on the bones of the head in 
 general ; they are not inseparable conditions of hearing. 
 We may hear sounds, and be uncertain whether they are 
 " above, around, or underneath !" but the moment any 
 thing visible appears, however unexpected, we can say, 
 " see where it comes !" 
 
 Since we can see the relative position of things, we 
 can see figure, which is but the relative position of the 
 different parts of the boundary of the object. And thus 
 the whole visible world exhibits to us a scene of various 
 shapes, coloured and shaded according to their form and 
 position, but each having relations of position to all the 
 rest ; and altogether, entirely filling up the whole range 
 which the eye can command. 
 
 3. Distance. The distance of objects from us is no 
 matter of immediate perception, but is a judgment and 
 inference formed from our sensations, in the same way 
 as our judgment of position by the ear. That this is so, 
 was most distinctly shown by Berkeley, in his New 
 Theory of Vision. The elements on which we form our 
 judgment are, the effort by which we fix both eyes on 
 the same object, the effort by which we adjust each eye 
 to distinct vision, and the known forms, colours, and 
 
288 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 parts of objects, as compared with their appearance. 
 The right interpretation of the information which these 
 circumstances give us respecting the true distances and 
 forms of things, is gradually learnt by experience, the 
 lesson being begun in our earliest infancy, and incul- 
 cated upon us every hour during which we use our eyes. 
 The completeness with which the lesson is learnt is 
 truly admirable ; for we forget that our conclusion is 
 obtained indirectly, and mistake a judgment on evidence 
 for an intuitive perception. This, however, is not more 
 surprizing than the rapidity and unconsciousness of effort 
 with which we understand the meaning of the speech 
 that we hear, or the book that we read. In both cases, 
 the habit of interpretation is become as familiar as the 
 act of perception. And this is the case with regard to 
 vision. We see the breadth of the street as clearly and 
 readily as we see the house on the other side of it. We 
 see the house to be square, however obliquely it be pre- 
 sented to us. Indeed the difficulty is, to recover the 
 consciousness of our real and original sensations; to 
 discover what is the apparent relation of the lines which 
 appear before us. As we have already said, in the com- 
 mon process of vision we suppose ourselves to see that 
 which cannot be seen ; and when we would make a 
 picture of an object, the difficulty is to represent what is 
 visible and no more. 
 
 But perfect as is our habit of interpreting what we 
 perceive, we could not interpret if we did not perceive. 
 If the eye did not apprehend visible position, it could 
 not infer actual position, which is collected from visible 
 position as a consequence : if we did not see apparent 
 figure, we could not arrive at any opinion concerning 
 real form. The perception of place, which is the prero- 
 gative of the eye, is the basis of all its other superiority. 
 
 The precision with which the eye can judge of appa- 
 
PECULIARITIES OF THE PERCEPTIONS. 289 
 
 rent position is remarkable. If we had before us two 
 stars distant from each other by one-twentieth of the 
 moon's diameter, we could easily decide the apparent 
 direction of the one from the other, as above or below, 
 to the right or left. Yet eight millions of stars might be 
 placed in the visible hemisphere of the sky at such dis- 
 tances from each other ; and thus the eye would recog- 
 nize the relative position in a portion of its range not 
 greater than one eight-millionth of the whole. Such is 
 the accuracy of the sense of vision in this respect ; and, 
 indeed, we might with truth have stated it much higher. 
 Our judgment of the position of distant objects in a 
 landscape depends upon features far more minute than 
 the magnitude we have here described. 
 
 As our object is to point out principally the differ- 
 ences of the senses, we do not dwell upon the delicacy 
 with which we distinguish tints and shades, but proceed 
 to another sense. 
 
 SECT. II. Prerogatives of Hearing. 
 
 THE sense of hearing has two remarkable prerogatives ; 
 it can perceive a definite and peculiar relation between 
 certain tones, and it can clearly perceive two tones to- 
 gether; in both these circumstances it is distinguished 
 from vision, and from the other senses. 
 
 4. Musical Intervals. We perceive that two tones 
 have, or have not, certain definite relations to each 
 other, which we call Concords : one sound is a Fifth, an 
 Octave, &c., above the other. And when this is the case, 
 our perception of the relation is extremely precise. It 
 is easy to perceive when a fifth is out of tune by one- 
 twentieth of a tone ; that is, by one-seventieth of itself. 
 To this there is nothing analogous in vision. Colours 
 have certain vague relations to one another ; they look 
 well together, by contrast or by resemblance ; but this 
 VOL. i. \v. P. U 
 
290 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 is an indefinite, and in most cases a casual and variable 
 feeling. The relation of complementary colours to one 
 another, as of red to green, is somewhat more definite ; 
 but still, has nothing of the exactness and peculiarity 
 which belongs to a musical concord. In the case of the 
 two sounds, there is an exact point at which the relation 
 obtains ; when by altering one note we pass this point, 
 the concord does not gradually fade away, but instantly 
 becomes a discord ; and if we go further still, we obtain 
 another concord of quite a different character. 
 
 We learn from the theory of sound that concords 
 occur when the times of vibration of the notes have 
 exact simple ratios; an octave has these times as 1 to 2; 
 a fifth, as 2 to 3. According to the undulatory theory 
 of light, such ratios occur in colours, yet the eye is not 
 affected by them in any peculiar way. The times of the 
 undulations of certain red and certain violet rays are 
 as 2 to 3, but we do not perceive any peculiar harmony 
 or connexion between those colours. 
 
 5. Chords. Again, the ear has this prerogative, that 
 it can apprehend two notes together, yet distinct. If 
 two notes, distant by a fifth from each other, are sounded 
 on two wind instruments, both they and their musical 
 relation are clearly perceived. There is not a mixture, 
 but a concord, an interval. In colours, the case is other- 
 wise. If blue and yellow fall on the same spot, they 
 form green ; the colour is simple to the eye ; it can no 
 more be decomposed by the vision than if it were the 
 simple green of the prismatic spectrum : it is impossible 
 for us, by sight, to tell whether it is so or not. 
 
 These are very remarkable differences of the two 
 senses : two colours can be compounded into an appa- 
 rently simple one ; two sounds cannot : colours pass into 
 each other by gradations and intermediate tints ; sounds 
 pass from one concord to another by no gradations : the 
 
PECULIARITIES OF THE PERCEPTIONS. 291 
 
 most intolerable discord is that which is near a concord. 
 We shall hereafter see how these differences affect the 
 scales of sound and of colour. 
 
 6. Rhythm. We might remark, that as we see ob- 
 jects in space, we hear sounds in time ; and that we thus 
 introduce an arrangement among sounds which has 
 several analogies with the arrangement of objects in 
 space. But the conception of time does not seem to be 
 peculiarly connected with the sense of hearing; a faculty 
 of apprehending tone and time, or in musical phrase- 
 ology tune and rhythm, are certainly very distinct. I 
 shall not, therefore, here dwell upon such analogies. 
 
 The other Senses have not any peculiar prerogatives, 
 at least none which beat on the formation of science. I 
 may, however, notice, in the feeling of heat, this cir- 
 cumstance ; that it presents us with two opposites, heat 
 and cold, which graduate into each other. This is not 
 quite peculiar, for vision also exhibits to us white and 
 black, which are clearly opposites, and which pass into 
 each other by the shades of gray. 
 
 SECT. III. The Paradoxes of Vision. 
 
 7. First Paradox of Vision. Upright Vision. 
 All our senses appear to have this in common ; That 
 they act by means of organs, in which a bundle of nerves 
 receives the impression of the appropriate medium of 
 the sense. In the construction of these organs there are 
 great differences and peculiarities, corresponding, in part 
 at least, to the differences in the information given. 
 Moreover, in some cases, as we have noted in the case of 
 audible position and visible distance, that which seems 
 to be a perception is really a judgment founded on per- 
 ceptions of which we are not directly aware. It will be 
 seen, therefore, that with respect to the peculiar powers 
 of each sense, it may be asked ; whether they can be 
 
 U2 
 
292 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 explained by the construction of the peculiar organ ; 
 whether they are acquired judgments and not direct 
 perceptions ; or whether they are inexplicable in either 
 of these ways, and cannot, at present at least, be re- 
 solved into anything but conditions of the intellectual 
 act of perception. 
 
 Two of these questions with regard to vision, have 
 been much discussed by psychological writers: the cause 
 of our seeing objects upright by inverted images on 
 the retina; and of our seeing single with two such 
 images. 
 
 Physiologists have very completely explained the 
 exquisitely beautiful mechanism of the eye, considered 
 as analogous to an optical instrument; and it is in- 
 disputable that by means of certain transparent lenses 
 and humours, an inverted image of the objects which 
 are looked at is formed upon the retina, or fine net- 
 work of nerve, with which the back of the eye is lined. 
 We cannot doubt that the impression thus produced on 
 these nerves is essential to the act of vision ; and so far 
 as we consider the nerves themselves to feel or perceive 
 by contact, we may say that they perceive this image, 
 or the affections of light which it indicates. But we 
 cannot with any propriety say that we perceive, or that 
 our mind perceives, this image; for we are not conscious 
 of it, and none but anatomists are aware of its existence: 
 we perceive ~by means of it. 
 
 A difficulty has been raised, and dwelt upon in a 
 most unaccountable manner, arising from the neglect of 
 this obvious distinction. It has been asked, how is it 
 that we see an object, a man for instance, upright, when 
 the immediate object of our sensation, the image of the 
 man on our retina, is inverted ? To this we must answer, 
 that we see him upright because the image is inverted ; 
 that the inverted image is the necessary means of seeing 
 
PECULIARITIES OF THE PERCEPTIONS. 293 
 
 an upright object. This is granted, and where then is 
 the difficulty ? Perhaps it may be put thus : How is it 
 that we do not judge the man to be inverted, since the 
 sensible image is so? To this we may reply, that we 
 have no notion of upright or inverted, except that which 
 is founded on experience, and that all our experience, 
 without exception, must have taught us that such a 
 sensible image belongs to a man who is in an upright 
 position. Indeed, the contrary judgment is not con- 
 ceivable ; a man is upright whose head is upwards and 
 his feet downwards. But what are the sensible images 
 of upwards and downwards f Whatever be our standard 
 of up and down, the sensible representation of up will be 
 an image moving on the retina towards the lower side, 
 and the sensible representation of down will be a motion 
 towards the upper side. The head of the man's image is 
 towards the image of the sky, its feet are towards the 
 image of the ground ; how then should it appear other- 
 wise than upright ? Do we expect that the whole world 
 should appear inverted ? Be it so : but if the whole be 
 inverted, how is the relation of the parts altered ? Do 
 we expect that we should think our own persons in par- 
 ticular inverted ? This cannot be, for we look at them 
 as we do at other objects. Do we expect that things 
 should appear to fall upwards ? Surely not. For what 
 do we know of upwards, except that it is the direction 
 in which bodies do not fall? In short, the whole of 
 this difficulty, though it has in no small degree embar- 
 rassed metaphysicians, appears to result from a very 
 palpable confusion of ideas; from an attempt at com- 
 parison of what we see, with that which the retina feels, 
 as if they were separately presentable. It is a sufficient 
 explanation to say, that we do not see the image on the 
 retina, but see by means of it. The perplexity does not 
 require much more skill to disentangle, than it does 
 
294 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 to see that a word written in black ink, may signify 
 white*. 
 
 8. Second Paradox of Vision. Single Vision. 
 (1.) Small or Distant Objects. The other difficulty, why 
 with two images on the retina we see only one object, 
 is of a much more real and important kind. This effect 
 is manifestly limited by certain circumstances of a very 
 precise nature ; for if we direct our eyes at an object 
 which is very near the eye, we see all other objects 
 double. The fact is not, therefore, that we are incapable 
 of receiving two impressions from the two images, but 
 that, under certain conditions, the two impressions form 
 one. A little attention shows us that these conditions 
 are, that with both eyes we should look at the same 
 object ; and again, we find that to look at an object with 
 either eye, is to direct the eye so that the image falls 
 
 * The explanation of our seeing objects erect when the image is 
 inverted has been put very simply, by saying, " We call that the lower 
 end of an object which is next the ground." The observer cannot look 
 into his own eye ; he knows by experience what kind of image cor- 
 responds to a man in an upright position. The anatomist tells him that 
 this image is inverted : but this does not disturb the process of judging 
 by experience. It does not appear why any one should be perplexed at 
 the notion of seeing objects erect by means of inverted images, rather 
 than at the notion of seeing objects large by means of small images ; or 
 cubical and pyramidal, by means of images on a spherical surface ; or 
 green and red, by means of images on a black surface. Indeed some 
 persons have contrived to perplex themselves with these latter questions, 
 as well as the first. 
 
 The above explanation is not at all affected, as to its substance, if we 
 adopt Sir David Brewster's expression, and say that the line of visible 
 direction is a line passing through the center of the spherical surface of 
 the retina, and therefore of course perpendicular to the surface. In 
 speaking of " the inverted image," it has always been supposed to be 
 determined by such lines ; and though the point where they intersect 
 may not have been ascertained with exactness by previous physiologists, 
 the philosophical view of the matter was not in any degree vitiated 
 by this imperfection. 
 
PECULIARITIES OF THE PERCEPTIONS. 295 
 
 on or near a particular point about the middle of the 
 retina. Thus these middle points in the two retinas 
 correspond, and we see an image single when the two 
 images fall on the corresponding points. 
 
 Again, as each eye judges of position, and as the two 
 eyes judge similarly, an object will be seen in the same 
 place by one eye and by the other, when the two images 
 which it produces are similarly situated with regard to 
 the corresponding points of the retina*. 
 
 This is the Law of Single Vision, at least so far as 
 regards small objects; namely, objects so small that in 
 contemplating them we consider their position only, and 
 not their solid dimensions. Single vision in such cases 
 is a result of the law of vision simply : and it is a 
 mistake to call in, as some have done, the influence of 
 
 * The explanation of single vision with two eyes may be put in 
 another form. Each eye judges immediately of the relative position of 
 all objects within the field of its direct vision. Therefore when we look 
 with both eyes at a distant prospect (so distant that the distance 
 between the eyes is small in comparison) the two prospects, being simi- 
 lar collections of forms, will coincide altogether, if a corresponding point 
 in one and in the other coincide. If this be the case, the two images 
 of every object will fall upon corresponding points of the retina, and 
 will appear single. 
 
 If the two prospects seen by the two eyes do not exactly coincide, 
 in consequence of nearness of the objects, or distortion of the eyes, but 
 if they nearly coincide, the stronger image of an object absorbs the 
 weaker, and the object is seen single ; yet modified by the combination, 
 as will be seen when we speak of the siagle vision of near objects. 
 When the two images of an object are considerably apart, we see it 
 double. 
 
 This explanation is not different in substance from the one given in 
 the text ; but perhaps it is better to avoid the assertion that the law of 
 corresponding points is " a distinct and original principle of our consti- 
 tution," as I had stated in the first edition. The simpler mode of 
 stating the law of our constitution appears to be to say, that each eye 
 determines similarly the position of objects ; and that when the positions 
 of an object, as seen by the two eyes, coincide (or nearly coincide) the 
 object is seen single. 
 
296 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 habit and of acquired judgments, in order to determine 
 the result in such cases. 
 
 To ascribe the apparent singleness of objects to the 
 impressions of vision corrected by the experience of 
 touch "*, would be to assert that a person who had not 
 been in the habit of handling what he saw, would see all 
 objects double ; and also, to assert that a person begin- 
 ning with the double world which vision thus offers to 
 him, would, by the continued habit of handling objects, 
 gradually and at last learn to see them single. But 
 all the facts of the case show such suppositions to be 
 utterly fantastical. No one can, in this case, go back 
 from the habitual judgment of the singleness of objects, 
 to the original and direct perception of their doubleness, 
 as the draughtsman goes back from judgments to per- 
 reption, in representing solid distances and forms by 
 means of perspective pictures. No one can point out 
 any case in which the habit is imperfectly formed ; even 
 children of the most tender age look at an object with 
 both eyes, and see it as one. 
 
 In cases when the eyes are distorted (in squinting)^ 
 one eye only is used, or if both are employed, there is 
 double vision ; and thus any derangement of the corre- 
 spondence of motion in the two eyes will produce double- 
 sightedness. 
 
 Brown is one of those f who assert that two images 
 suggest a single object because we have always found 
 two images to belong to a single object. He urges as 
 an illustration, that the two words "he conquered," 
 by custom excite exactly the same notion as the one 
 Latin word "vicit;" and thus that two visual images, 
 by the effect of habit, produce the same belief of a 
 single object as one tactual impression. But in order 
 to make this pretended illustration of any value, it ought 
 
 * See Brown, Vol. u. p. 81. t Lectures, Vol. n. p. 81. 
 
PECULIARITIES OF THE PERCEPTIONS. 297 
 
 to be true that when a person has thoroughly learnt 
 the Latin language, he can no longer distinguish any 
 separate meaning in " he" and in " conquered." We can 
 by no effort perceive the double sensation, when we 
 look at the object with the two eyes. Those who squint, 
 learn by habit to see objects single: but the habit which 
 they acquire is that of attending to the impressions of 
 one eye only at once, not of combining the two impres- 
 sions. It is obvious, that if each eye spreads before us 
 the same visible scene, with the same objects and the 
 same relations of place, then, if one object in each scene 
 coincide, the whole of the two visible impressions will be 
 coincident. And here the remarkable circumstance is, 
 that not only each eye judges for itself of the relations 
 of position which come within its field of view; but that 
 there is a superior and more comprehensive faculty 
 which combines and compares the two fields of view ; 
 which asserts or denies their coincidence; which con- 
 templates, as in a relative position to one another, these 
 two visible worlds, in which all other relative position is 
 given. This power of confronting two sets of visible 
 images and figured spaces before a purely intellectual 
 tribunal, is one of the most remarkable circumstances in 
 the sense of vision. 
 
 9. (2.) Near Objects. We have hitherto spoken 
 of the singleness of objects whose images occupy corre- 
 sponding positions on the retina of the two eyes. But 
 here occurs a difficulty. If an object of moderate size, a 
 small thick book for example, be held at a little dis- 
 tance from the eyes, it produces an image on the retina 
 of each eye ; and these two images are perspective 
 representations of the book from different points of view, 
 (the positions of the two eyes,) and are therefore of dif- 
 ferent forms. Hence the two images cannot occupy cor- 
 responding points of the retina throughout their whole 
 
298 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 extent. If the central parts of the two images occupy 
 corresponding points, the boundaries of the two will 
 not correspond. How is it then consistent with the 
 law above stated, that in this case the object appears 
 single ? 
 
 It may be observed, that the two images in such a case 
 will differ most widely when the object is not a mere sur- 
 face, but a solid. If a book, for example, be held with 
 one of its upright edges towards the face, the right eye 
 will see one side more directly than the left eye, and 
 the left eye will see another side more directly, and the 
 outline of the two images upon the two retinas will ex- 
 hibit this difference. And it may be further observed, 
 that this difference in the images received by the two 
 eyes, is a plain and demonstrative evidence of the solidity 
 of the object seen ; since nothing but a solid object 
 could (without some special contrivance) produce these 
 different forms of the images in the two eyes. 
 
 Hence the absence of exact coincidence in the two 
 images on the retina is the necessary condition of the 
 solidity of the object seen, and must be one of the indi- 
 cations by means of which our vision apprehends an 
 object as solid. And that this is so, Mr. Wheatstone 
 has proved experimentally, by means of some most 
 ingenious and striking contrivances. He has devised* 
 an instrument by which two images (drawn in outline) 
 differing exactly as much as the two images of a solid 
 body seen near the face would differ, are conveyed, 
 one to one eye, and the other to the other. And it is 
 found that when this is effected, the object which the 
 images represent is not only seen single, but is appre- 
 hended as solid with a clearness and reality of conviction 
 quite distinct from any impression which a mere per- 
 spective representation can give. 
 
 * Phil, Trans., 1839. - 
 
PECULIARITIES OF THE PERCEPTIONS. 299 
 
 At the same time it is found that the object is then 
 only apprehended as single when the two images are 
 such as are capable of being excited by one single object 
 placed in solid space, and seen by the two eyes. If 
 the images differ more or otherwise than this condition 
 allows, the result is, that both are seen, their lines cross- 
 ing and interfering with one another. 
 
 It may be observed, too, that if an object be of such 
 large size as not to be taken in by a single glance of the 
 eyes, it is no longer apprehended as single by a direct 
 act of perception ; but its parts are looked at separately 
 and successively, and the impressions thus obtained are 
 put together by a succeeding act of the mind. Hence 
 the objects which are directly seen as solid, will be of 
 moderate size ; in which case it is not difficult to show 
 that the outlines of the two images will differ from each 
 other only slightly. 
 
 Hence we are led to the following, as the Law of 
 Single Vision for near objects : When the two images 
 in the two eyes are situated (part for part) nearly, but 
 not exactly, upon corresponding points, the object is ap- 
 prehended as single, if the two images are such as are 
 or would be given by a single solid object seen by the 
 two eyes separately : and in this case the object is neces- 
 sarily apprehended as solid. 
 
 This law of vision does not contradict that stated 
 above for distant objects : for when an object is removed 
 to a considerable distance, the images in the two eyes 
 coincide exactly, and the object is seen as single, though 
 without any direct apprehension of its solidity. The 
 first law is a special case of the second. Under the con- 
 dition of exactly corresponding points, we have the per- 
 ception of singleness, but no evidence of solidity. Under 
 the condition of nearly corresponding points, we may 
 have the perception of singleness, and with it, of solidity. 
 
300 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 We have before noted it as an important feature in 
 our visual perception, that while we have two distinct 
 impressions upon the sense, which we can contemplate 
 separately and alternately, (the impressions on the two 
 eyes,) we have a higher perceptive faculty which can 
 recognize these two impressions, exactly similar to each 
 other, as only two images of one and the same assem- 
 blage of objects. But we now see that the faculty by 
 which we perceive visible objects can do much more 
 than this : it can not only unite two impressions, and 
 recognize them as belonging to one object in virtue of 
 their coincidence, but it can also unite and identify them, 
 even when they do not exactly coincide. It can correct 
 and adjust their small difference, so that they are both 
 apprehended as representations of the same figure. It 
 can infer from them a real form, not agreeing with 
 either of them ; and a solid space, which they are quite 
 incapable of exemplifying. The visual faculty decides 
 whether or not the two ocular images can be pictures of 
 the same solid object, and if they can, it undoubtingly 
 and necessarily accepts them as being so. This faculty 
 operates as if it had the power of calling before it all 
 possible solid figures, and of ascertaining by trial whether 
 any of those will, at the same time, fit both the outlines 
 which are given by the sense. It assumes the reality 
 of solid space, and, if it be possible, reconciles the appear- 
 ances with that reality. And thus an activity of the 
 mind of a very remarkable and peculiar kind is exer- 
 cised in the most common act of seeing. 
 
 10. It may be said that this doctrine, of such a visual 
 faculty as has been described, is very vague and obscure, 
 since we are not told what are its limits. It adjusts and 
 corrects figures which nearly coincide, so as to identify 
 them. But how nearly, it may be asked, must the 
 figures approach each other, in order that this adjust- 
 
PECULIARITIES OF THE PERCEPTIONS. 301 
 
 ment may be possible? What discrepance renders im- 
 possible the reconcilement of which we speak ? Is it 
 not impossible to give a definite answer to these ques- 
 tions, and therefore impossible to lay down definitely 
 such laws of vision as we have stated ? To this I reply, 
 that the indefiniteness thus objected to us, is no new 
 difficulty, but one with which philosophers are familiar, 
 and to which they are already reconciled. It is, in fact, 
 no other than the indefiniteness of the limits of distinct 
 vision. How near to the face must an object be brought, 
 so that we shall cease to see it distinctly ? The distance, 
 it will be answered, is indefinite : it is different for 
 different persons; and for the same person, it varies 
 with the degree of effort, attention, and habit. But this 
 indefiniteness is only the indefiniteness, in another form, 
 of the deviation of the two ocular images from one 
 another : and in reply to the question concerning them 
 we must still say, as before, that in doubtful cases, the 
 power of apprehending an object as single, when this 
 can be done, will vary with effort, attention, and habit. 
 The assumption that the apparent object exists as a real 
 figure, in real space, is to be verified, if possible ; but, 
 in extreme cases, from the unfitness of the point of view, 
 or from any other cause of visual confusion or deception, 
 the existence of a real object corresponding to the ap- 
 pearance may be doubtful ; as in any other kind of per- 
 ception it may be doubtful whether our senses, under 
 disadvantageous circumstances, give us true information. 
 The vagueness of the limits, then, within which this 
 visual faculty can be successfully exercised, is no valid 
 argument against the existence of the faculty, or the 
 truth of the law which we have stated concerning its 
 action. 
 
302 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES, 
 
 SECT. IV. The Perception of Visible Figure. 
 
 11. Visible Figure. There is one tenet on the 
 subject of vision which appears to me so extravagant 
 and unphilosophical, that I should not have thought it 
 necessary to notice it, if it had not been recently pro- 
 mulgated by a writer of great acuteness in a book which 
 has obtained, for a metaphysical work, considerable cir- 
 culation. I speak of Brown's opinion* that we have no 
 immediate perception of visible figure. I confess myself 
 unable to comprehend fully the doctrine which he would 
 substitute in the place of the one commonly received. 
 He states it thus f: "When the simple aifection of sight 
 is blended with the ideas of suggestion [those arising 
 from touch, &c.] in what are termed the acquired per- 
 ceptions of vision, as, for example, in the perception of 
 a sphere, it is colour only which is blended with the 
 large convexity, and not a small coloured plane." The 
 doctrine which Brown asserts in this and similar pas- 
 sages, appears to be, that we do not by vision perceive 
 loth colour and figure ; but that the colour which we see 
 is blended with the figure which we learn the existence 
 of by other means, as by touch. But if this were pos- 
 sible when we can call in other perceptions, how is it 
 possible when we cannot or do not touch the object? 
 Why does the moon appear round, gibbous, or horned ? 
 What sense besides vision suggests to us the idea of her 
 figure ? And even in objects which we can reach, what 
 is that circumstance in the sense of vision which suggests 
 to us that the colour belongs to the sphere, except that 
 we see the colour where we see the sphere ? If we do 
 not see figure, we do not see position ; for figure is the 
 relative position of the parts of a boundary. If we do 
 not see position, why do we ascribe the yellow colour to 
 
 * Lectures, Vol. n. p. 82. t II). Vol. n. p. 90. 
 
PECULIARITIES OF THE PERCEPTIONS. 303 
 
 the sphere on our left, rather than to the cube on our 
 right? We associate the colour with the object, says 
 Dr. Brown ; but if his opinion were true, we could not 
 associate two colours with two objects, for we could 
 not apprehend the colours as occupying two different 
 places. 
 
 The whole of Brown's reasoning on this subject is so 
 irreconcileable with the first facts of vision, that it is 
 difficult to conceive how it could proceed from a person 
 who has reasoned with great acuteness concerning touch. 
 In order to prove his assertion, he undertakes to ex- 
 amine the only reasons which, he says*, he can imagine 
 for believing the immediate perception of visible figure : 
 
 (1) That it is absolutely impossible, in our present sen- 
 sations of sight, to separate colour from extension ; and 
 
 (2) That there are, in fact, figures on the retina corre- 
 sponding to the apparent figures of objects. 
 
 On the subject of the first reason, he says, that the 
 figure which we perceive as associated with colour, is the 
 real, and not the apparent figure. " Is there," he asks, 
 " the slightest consciousness of a perception of visible 
 figure, corresponding to the aifected portion of the 
 retina?" To which, though he seems to think an affir- 
 mative answer impossible, we cannot hesitate to reply, 
 that there is undoubtedly such a consciousness; that 
 though obscured by being made the ground of habitual 
 inference as to the real figure, this consciousness is con- 
 stantly referred to by the draughtsman, and easily re- 
 called by any one. We may separate colour, he says 
 again-)-, from the figures on the retina, as we may sepa- 
 rate it from length, breadth, and thickness, which we do 
 not see. But this is altogether false : we cannot separate 
 colour from length, breadth, and thickness, in any other 
 way, than by transferring it to the visible figure which 
 
 * Lectures, Vol. n. p. 83. t Ib. p. 84. 
 
304 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 we do see. He cannot, he allows, separate the colour 
 from the visible form of the trunk of a large oak ; but 
 just as little, he thinks, can he separate it from the con- 
 vex mass of the trunk, which (it is allowed on all hands) 
 he does not immediately see. But in this he is mis- 
 taken : for if he were to make a picture of the oak, he 
 would separate the colour from the convex shape, which 
 he does not imitate, but he could not separate it from 
 the visible figure, which he does imitate ; and he would 
 then perceive that the fact that he has not an imme- 
 diate perception of the convex form, is necessarily con- 
 nected with the fact that he has an immediate percep- 
 tion of the apparent figure ; so far is the rejection of 
 immediate perception in the former case from being a 
 reason for rejecting it in the latter. 
 
 Again, with regard to the second argument. It does 
 not, he says, follow, that because a certain figured por- 
 tion of the retina is affected by light, we should see such 
 a figure ; for if a certain figured portion of the olfactory 
 organ were affected by odours, we should not acquire by 
 smell any perception of such figure *. This is merely to 
 say, that because we do not perceive position and figure 
 by one sense, we cannot do SQ by another. But this 
 again is altogether erroneous. It is an office of our 
 sight to inform us of position, and consequently of 
 figure; for this purpose, the organ is so constructed 
 that the position of the object determines the position 
 of the point of the retina affected. There is nothing of 
 this kind in the organ of smell ; objects in different posi- 
 tions and of different forms do not affect different parts 
 of the olfactory nerve, or portions of different shape. 
 Different objects, remote from each other, if perceived 
 by smell, affect the same part of the olfactory organs. 
 This is all quite intelligible ; for it is not the office of 
 * Lectures, Vol. u. p. 87. 
 
PECULIARITIES OF THE PERCEPTIONS. 305 
 
 smell to inform us of position. Of what use or meaning 
 would be the curious and complex structure of the eye, 
 if it gave us only such vague and wandering notions of 
 the colours and forms of the flowers in a garden, as we 
 receive from their odours when we walk among them 
 blindfold? It is, as we have said, the prerogative of 
 vision to apprehend position : the places of objects on 
 the retina give this information. . We do not suppose 
 that the affection of a certain shape of nervous expanse 
 will necessarily and in all cases give us the impression 
 of figure ; but we know that in vision it does ; and it is 
 clear that if we did not acquire our acquaintance with 
 visible figure in this way, we could not acquire it in 
 any way*. 
 
 The whole of this strange mistake of Brown's appears 
 to arise from the fault already noticed ; that of consi- 
 dering the image on the retina as the object instead of 
 the m,eans of vision. This indeed is what he says : " the 
 true object of vision is not the distant body itself, but 
 the light that has reached the expansive termination of 
 the optic nerve f." Even if this were so, we do not see 
 why we should not perceive the position of the impres- 
 sion on this expanded nerve. But as we have already 
 said, the impression on the nerve is the means of vision, 
 and enables us to assign a place, or at least a direction, 
 to the object from which the light proceeds, and thus 
 makes vision possible. Brown, indeed, pursues his own 
 peculiar view till he involves the subject in utter confu- 
 sion. Thus he says J, " According to the common theory 
 
 * When Brown says further (p. 87,) that we can indeed show the 
 image in the dissected eye ; but that " it is not in the dissected eye 
 that vision takes place ;" it is difficult to see what his drift is. Does 
 he doubt that there is an image formed in the living as completely as 
 in the dissected eye ? 
 
 * Lectures, Vol. IT. p. 57. t Ib., Vol. u. p. 89. 
 VOL. I. W. P. X 
 
306 PHILOSPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 [that figure can be perceived by the eye,] a visible 
 sphere is at once to my perception convex and plane; 
 and if the sphere be a large one, it is perceived at once 
 to be a sphere of many feet in diameter, and a plane 
 circular surface of the diameter of a quarter of an inch." 
 It is easy to deduce these and greater absurdities, if we 
 proceed on his strange and baseless supposition that the 
 object and the image on the retina are both perceived. 
 But who is conscious of the image on the retina in any 
 other way than as he sees the object by means of it? 
 
 Brown seems to have imagined that he was ana- 
 lyzing the perception of figure in the same manner in 
 which Berkeley had analyzed the perception of distance. 
 He ought to have recollected that such an undertaking, 
 to be successful, required him to show what elements he 
 analyzed it into. Berkeley analyzed the perception of 
 real figure into the interpretation of visible figure accord- 
 ing to certain rules which he distinctly stated. Brown 
 analyzes the perception of visible figure into no ele- 
 ments. Berkeley says, that we do not directly perceive 
 distance, but that we perceive something else, from 
 which we infer distance, namely, visible figure and colour, 
 and our own efforts in seeing ; Brown says, that we do 
 not see figure, but infer it ; what then do we see, which 
 we infer it from ? To this he offers no answer. He 
 asserts the seeming perception of visible figure to be a 
 result of " association ;" of " suggestion." But what 
 meaning can we attach to this? Suggestion requires 
 something which suggests ; and not a hint is given what 
 it is which suggests position. Association implies two 
 things associated ; what is the sensation which we asso- 
 ciate with form ? What is that visual perception which 
 is not figure, and which we mistake for figure ? What 
 perception is it that suggests a square to the eye ? What 
 impressions are those which have been associated with 
 
PECULIARITIES OF THE PERCEPTIONS. 307 
 
 a visible triangle, so that the revival of the impressions 
 revives the notion of the triangle ? Brown has nowhere 
 pointed out such perceptions and impressions; nor indeed 
 was it possible for him to do so ; for the only visual 
 perceptions which he allows to remain, those of colour, 
 most assuredly do not suggest visible figures by their 
 differences ; red is not associated with square rather than 
 with round, or with round rather than square. On the 
 contrary, the eye, constructed in a very complex and 
 wonderful manner in order that it may give to us directly 
 the perception of position as well as of colour, has it for 
 one of its prerogatives to give us this information ; and 
 the perception of the relative position of each part of 
 the visible boundary of an object constitutes the percep- 
 tion of its apparent figure ; which faculty we cannot 
 deny to the eye without rejecting the plain and constant 
 evidence of our senses, making the mechanism of the 
 eye unmeaning, confounding the object with the means 
 of vision, and rendering the mental process of vision 
 utterly unintelligible. 
 
 Having sufficiently discussed the processes of per- 
 ception, I now return to the consideration of the Ideas 
 which these processes assume. 
 
 CHAPTER III. 
 
 SUCCESSIVE ATTEMPTS AT THE SCIENTIFIC 
 
 APPLICATION OF THE IDEA OF A 
 
 MEDIUM. 
 
 1 . IN what precedes, we have shown by various con- 
 siderations that we necessarily and universally assume 
 the perception of secondary qualities to take place by 
 means of a medium interjacent between the object and 
 the person perceiving. Perception is affected by various 
 
 X2 
 
308 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 peculiarities, according to the nature of the quality per- 
 ceived : but in all cases a medium is equally essential to 
 the process. 
 
 This principle, which, as we have seen, is accepted as 
 evident by the common understanding of mankind, is 
 confirmed by all additional reflection and discipline of 
 the mind, and is the foundation of all the theories which 
 have been proposed concerning the processes by which 
 the perception takes place, and concerning the modifi- 
 cations of the qualities thus perceived. The medium, and 
 the mode in which the impression is conveyed through 
 the medium, seem to be different for different qualities ; 
 but the existence of the medium leads to certain neces- 
 sary conditions or alternatives, which have successively 
 made their appearance in science, in the course of the 
 attempts of men to theorize concerning the principal 
 secondary qualities, sound, light, and heat. We must 
 now point out some of the ways, at first imperfect and 
 erroneous, in which the consequences of the fundamental 
 assumption were traced. 
 
 2. Sound. In all cases the medium of sensation, 
 whatever it is, is supposed to produce the effect of con- 
 veying secondary qualities to our perception by means 
 of its primary qualities. It was conceived to operate by 
 the size, form, and motion of its parts. This is a funda- 
 mental principle of the class of sciences of which we 
 have at present to speak. 
 
 It was assumed from the first, as we have seen in the 
 passage lately quoted from Aristotle*, that in the con- 
 veyance of sound, the medium of communication was 
 the air. But although the first theorists were right 
 so far, that circumstance did not prevent their going 
 entirely wrong when they had further to determine the 
 nature of the process. It was conceived by Aristotle 
 * Supr., p. 282. 
 
SCIENTIFIC APPLICATION OF THE IDEA OF A MEDIUM. 309 
 
 that the air acted after the manner of a rigid body ; 
 like a staff, which, receiving an impulse at one end, trans- 
 mits it to the other. Now this is altogether an erro- 
 neous view of the manner in which the air conveys the 
 impulse by which sound is perceived. An approach was 
 made to the true view of this process, by assimilating it 
 to the diffusion of the little circular waves which are 
 produced on the surface of still water when a stone is 
 dropt into it. These little waves begin from the point 
 thus disturbed, and run outwards, expanding on every 
 side, in concentric circles, till they are lost. The propa- 
 gation of sound through the air from the point where it 
 is produced, was compared by Vitruvius to this diffu- 
 sion of circular waves in water ; and thus the notion of 
 a propagation of impulse by the waves of a fluid was 
 introduced, in the place of the former notion of the 
 impulse of an unyielding body. 
 
 But though, taking an enlarged view of the nature 
 of the progress of a wave, this is a just representation 
 of the motion of air in conveying sound, we cannot sup- 
 pose that the process was, at the period of which we 
 speak, rightly understood. For the waves of water were 
 contemplated only as affecting the surface of the water ; 
 and as the air has no surface, the communication must 
 take place by means of an internal motion, which can 
 bear only a remote and obscure resemblance to the waves 
 which we see. And even with regard to the waves of 
 water, the mechanism by which they are produced and 
 transferred was not at all understood ; so that the com- 
 parison employed by Vitruvius must be considered rather 
 as a loose analogy than as an exact scientific explanation. 
 
 No correct account of such motions was given, till 
 the formation of the science of Mechanics in modern 
 times had enabled philosophers to understand more dis- 
 tinctly the mode in which motion is propagated through 
 
310 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 a fluid, and to discern the forces which the process calls 
 into play, so as to continue the motion once begun. 
 Newton introduced into this subject the exact and rigor- 
 ous conception of an undulation, which is the true key to 
 the explanation of impulses conveyed through a fluid. 
 
 Even at the present day, the right apprehension of 
 the nature of an undulation transmitted through a fluid 
 is found to be very difficult for all persons except those 
 whose minds have been duly disciplined by mathematical 
 studies. When we see a wave run along the surface of 
 water, we are apt to imagine at first that a portion of 
 the fluid is transferred bodily from one place to another. 
 But with a little consideration we may easily satisfy 
 ourselves that this is not so : for if we look at a field of 
 standing corn, when a breeze blows over it, we see waves 
 like those of water run along its surface. Yet it is clear 
 that in this case the separate stalks of corn only bend 
 backwards and forwards, and no portion of the grain is 
 really conveyed from one part of the field to the other. 
 This is obvious even to popular apprehension. The poet 
 speaks of 
 
 The rye, 
 
 That stoops its head when whirlwinds rave 
 And springs again in eddying wave 
 As each wild gust sweeps by. 
 
 Each particle of the mass in succession has a small 
 motion backwards and forwards ; and by this means a 
 large ridge made by many such particles runs along the 
 mass to any distance. This is the true conception of 
 an undulation in general. 
 
 Thus, when an undulation is propagated in a fluid, 
 it is not matter, but form, which is transmitted from one 
 place to another. The particles along the line of each 
 wave assume a certain arrangement, and this arrange- 
 ment passes from one part to another, the particles 
 
SCIENTIFIC APPLICATION OF THE IDEA OF A MEDIUM. 311 
 
 changing their places only within narrow limits, so as to 
 lend themselves successively to the arrangements by 
 which the successive waves, and the intervals between 
 the waves, are formed. 
 
 When such an undulation is propagated through 
 air, the wave is composed, not, as in water, of particles 
 which are higher than the rest, but of particles which 
 are closer to each other than the rest. The wave is not 
 a ridge of elevation, but a line of condensation ; and as 
 in water we have alternately elevated and depressed 
 lines, we have in air lines alternately condensed and 
 rarefied. And the motion of the particles is not, as in 
 water, up and down, in a direction transverse to that of 
 the wave which runs forwards; in the motion of an 
 undulation through air the motion of each particle is 
 alternately forwards and backwards, while the motion 
 of the undulation is constantly forwards. 
 
 This precise and detailed account of the undulatory 
 motion of air by which sound is transmitted was first 
 given by Newton. He further attempted to determine 
 the motions of the separate particles, and to point out 
 the force by which each particle affects the next, so as 
 to continue the progress of the undulation once begun. 
 The motions of each particle must be oscillatory; he 
 assumed the oscillations to be governed by the simplest 
 law of oscillation which had come under the notice of 
 mathematicians, (that of small vibrations of a pendulum;) 
 and he proved that in this manner the forces which are 
 called into play by the contraction and expansion of the 
 parts of the elastic fluid are such as the continuance of 
 the motion requires. 
 
 Newton's proof of the exact law of oscillatory motion 
 of the aerial particles was not considered satisfactory by 
 succeeding mathematicians; for it was found that the 
 same result, the development of forces adequate to con- 
 
 
312 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 tiiiue the motion, would follow if any other law of the 
 motion were assumed. Cramer proved this by a sort of 
 parody of Newton's proof, in which, by the alteration of 
 a few phrases in this formula of demonstration, it was 
 made to establish an entirely different conclusion. 
 
 But the general conception of an undulation as pre- 
 sented by Newton was, as from its manifest mechanical 
 truth it could not fail to be, accepted by all mathemati- 
 cians ; and in proportion as the methods of calculating 
 the motions of fluids were further improved, the neces- 
 sary consequences of this conception, in the communica- 
 tion of sound through air, were traced by unexceptionable 
 reasoning. This was especially done by Euler and 
 Lagrange, whose memoirs on such motions of fluids are 
 some of the most admirable examples which exist, of 
 refined mathematical methods applied to the solution of 
 difficult mechanical problems. 
 
 But the great step in the formation of the theory of 
 sound was undoubtedly that which we have noticed, the 
 introduction of the Conception of an Undulation such as 
 we have attempted to describe it: a state, condition, or 
 arrangement of the particles of a fluid, which is trans- 
 ferred from one part of space to another by means of 
 small motions of the particles, altogether distinct from 
 the movement of the undulation itself. This is a con- 
 ception which is not obvious to common apprehension. 
 It appears paradoxical at first sight to speak of a large 
 wave (as the tide-wave) running up a river at the rate of 
 twenty miles an hour, while the stream of the river is 
 all the while flowing downwards. Yet this is a very 
 common fact. And the conception of such a motion 
 must be fully mastered by all who would reason rightly 
 concerning the transmission of impressions through a 
 medium. 
 
 We have described the motion of sound as produced 
 
SCIENTIFIC APPLICATION OF THE IDEA OF A MEDIUM. 313 
 
 by small motions of the particle forwards and backwards, 
 while the waves, or condensed and rarefied lines, move 
 constantly forwards. It may be asked what right we 
 have to suppose the motion to be of this kind, since 
 when sound is heard, no such motions of the particles of 
 air can be observed, even by refined methods of observa- 
 tion. Thus Bacon declares himself against the hypothesis 
 of such a vibration, since, as he remarks, it cannot be 
 perceived in any visible impression upon the flame of a 
 candle. And to this we reply, that the supposition of 
 this vibration is made in virtue of a principle which 
 is involved in the original assumption of a medium ; 
 namely, That a medium, in conveying secondary quali- 
 ties, operates ly means of its primary qualities, the 
 bulk, figure, motion, and other mechanical properties of 
 its parts. This is an Axiom belonging to the Idea of a 
 Medium. In virtue of this axiom it is demonstrable that 
 the motion of the air, when any how disturbed, must be 
 such as is supposed in our acoustical reasonings. For 
 the elasticity of the parts of the air, called into play by 
 its expansion and contraction, lead, by a mechanical 
 necessity, to such a motion as we have described. We 
 may add that, by proper contrivances, this motion may 
 be made perceptible in its visible effects. Thus the 
 theory of sound, as an impression conveyed through air, 
 is established upon evident general principles, although 
 the mathematical calculations which are requisite to 
 investigate its consequences are, some of them, of a very 
 recondite kind. 
 
 3. Light. The early attempts to explain vision 
 represented it as performed by means of material rays 
 proceeding from the eye, by the help of which the eye 
 felt out the form and other visible qualities of an object, 
 as a blind man might do with his staff. But this opi- 
 nion could not keep its ground long : for it did not even 
 
314 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 explain the fact that light is necessary to vision. Light as 
 a peculiar medium was next assumed as the machinery 
 of vision ; but the mode in which the impression was 
 conveyed through the medium was left undetermined, 
 and no advance was made towards sound theory, on that 
 subject, by the ancients. 
 
 In modern times, when the prevalent philosophy 
 began to assume a mechanical turn (as in the theories 
 of Descartes), light was conceived to be a material sub- 
 stance which is emitted from luminous bodies, and which 
 is also conveyed from all bodies to the eye, so as to 
 render them visible. The various changes of direction 
 by which the rays of light are affected, (reflexion, refrac- 
 tion, &c.,) Descartes explained, by considering the par- 
 ticles of light as small globules, which change their 
 direction when they impinge upon other bodies, accord- 
 ing to the laws of mechanics. Newton, with a much 
 more profound knowledge of mechanics than Descartes 
 possessed, adopted, in the most mature of his specula- 
 tions, nearly the same view of the nature of light ; and 
 endeavoured to show that reflexion, refraction, and other 
 properties of light, might be explained as the effects 
 which certain forces, emanating from the particles of 
 bodies, produce upon the luminiferous globules. 
 
 But though some of the properties of light could thus 
 be accounted for by the assumption of particles emitted 
 from luminous bodies, and reflected or refracted by forces, 
 other properties came into view which would not admit 
 of the same explanation. The phenomena of diffraction 
 (the fringes which accompany shadows) could never be 
 truly represented by such an hypothesis, in spite of many 
 attempts which were made. And the colours of thin 
 plates, which show the rays of light to be affected by an 
 alternation of two different conditions at small intervals 
 along their length, led Newton himsejf to incline, often 
 
SCIENTIFIC APPLICATION OF THE IDEA OF A MEDIUM. 315 
 
 and strongly, to some hypothesis of undulation. The 
 double refraction of Iceland spar, a phenomenon in itself 
 very complex, could, it was found by Huyghens, be 
 expressed with great simplicity by a certain hypothesis 
 of undulations. 
 
 Two hypotheses of the nature of the luminiferous 
 medium were thus brought under consideration ; the one 
 representing Light as Matter emitted from the luminous 
 object, the other, as Undulations propagated through a 
 fluid. These two hypotheses remained in presence of 
 each other during the whole of the last century, neither 
 of them gaining any material advantage over the other, 
 though the greater part of mathematicians, following 
 Newton, embraced the emission theory. But at the 
 beginning of the present century, an additional class of 
 phenomena, those of the interference of two rays of 
 light, were brought under consideration by Dr. Young ; 
 and these phenomena were strongly in favour of the 
 undulatory theory, while they were irreconcilable with 
 the hypothesis of emission. If it had not been for the 
 original bias of Newton and his school to the other side, 
 there can be little doubt that from this period light as 
 well as sound would have been supposed to be pro- 
 pagated by undulations; although in this case it was 
 necessary to assume as the vehicle of such undulations 
 a special medium or ether. Several points of the phe- 
 nomena of vision no doubt remained unexplained by the 
 undulatory theory, as absorption, and the natural colours 
 of bodies ; but such facts, though they did not confirm, 
 did not evidently contradict the theory of a luminiferous 
 ether ; and the facts which such a theory did explain, it 
 explained with singular happiness and accuracy. 
 
 But before this undulatory theory could be generally 
 accepted, it was presented in an entirely new point of 
 view by being combined with the facts of polarization. 
 
316 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 The general idea of polarization must be illustrated here- 
 after ; but we may here remark that Young and Fresnel, 
 who had adopted the undulatory theory, after being 
 embarrassed for some time by the new facts which were 
 thus presented to their notice, at last saw that these 
 facts might be explained by conceiving the vibrations to 
 be transverse to the ray, the motions of the particles 
 being not backwards and forwards in the line in which 
 the impulse travels, but to the right and left of that 
 line. This conception of transverse vibrations, though 
 quite unforeseen, had nothing in it which was at all diffi- 
 cult to reconcile with the general notion of an undula- 
 tion. We have described an undulation, or wave, as a 
 certain condition or arrangement of the particles of the 
 fluid successively transferred from one part of space to 
 another : and it is easily conceivable that this arrange- 
 ment or wave may be produced by a lateral transfer of 
 the particles from their quiescent positions. This con- 
 ception of transverse vibrations being accepted, it was 
 found that the explanation of the phenomena of polari- 
 zation and of those of interference led to the same 
 theory with a correspondence truly wonderful ; and this 
 coincidence in the views, collected from two quite dis- 
 tinct classes of phenomena, was justly considered as an 
 almost demonstrative evidence of the truth of this undu- 
 latory theory. 
 
 It remained to be considered whether the doctrine 
 of transverse vibrations in a fluid could be reconciled 
 with the principles of mechanics. And it was found 
 that by making certain suppositions, in which no in- 
 herent improbability existed, the hypothesis of trans- 
 verse vibrations would explain the laws, both of inter- 
 ference and of polarization of light, in air and in crystals 
 of all kinds, with a surprizing fertility and fidelity. 
 
 Thus the undulatory theory of light, like the undu- 
 
SCIENTIFIC APPLICATION OF THE IDEA OF A MEDIUM. 317 
 
 latory theory of sound, is recommended by its conformity 
 to the fundamental principle of the Secondary Mecha- 
 nical Sciences, that the medium must be supposed to 
 transmit its peculiar impulses according to the laws of 
 mechanics. Although no one had previously dreamt of 
 qualities being conveyed through a medium by such a 
 process, yet when it is once suggested as the only mode 
 of explaining some of the phenomena, there is nothing 
 to prevent our accepting it entirely, as a satisfactory 
 theory for all the known laws of light. 
 
 4. Heat. With regard to heat as with regard to 
 light, a fluid medium was necessarily assumed as the 
 vehicle of the property. During the last century, this 
 medium was supposed to be an emitted fluid. And 
 many of the ascertained Laws of Heat, those which 
 prevail with regard to its radiation more especially, were 
 well explained by this hypothesis"''*. Other effects of 
 heat, however, as for instance latent heat^, and the 
 change of consistence of bodies;];, were not satisfactorily 
 brought into connexion with the hypothesis ; while con- 
 duction, which at first did not appear to result from 
 the fundamental assumption, was to a certain extent 
 explained as internal radiation. 
 
 But it was by no means clear that an undulatory 
 theory of heat might not be made to explain these 
 phenomena equally well. Several philosophers inclined 
 to such a theory ; and finally, Ampere showed that the 
 doctrine that the heat of a body consists in the undula- 
 tions of its particles propagated by means of the undula- 
 tions of a medium, might be so adjusted as to explain all 
 which the theory of emission could explain, and more- 
 over to account for facts and laws which were out of 
 
 * See the Account of the Theory of Exchanges, Hist. Ind. Sci.^ 
 B. x. c. i. sect, 2. t 76., c. ii. sect. 3. 
 
 J 76., c. ii. sect. 2. 76., c. i. sect. 7. 
 
318 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 the reach of that theory. About the same time it was 
 discovered by Prof. Forbes and M. Nobili that radiant 
 heat is, under certain circumstances, polarized. Now 
 polarization had been most satisfactorily explained by 
 means of transverse undulations in the case of light ; 
 while all attempts to modify the emission theory so as to 
 include polarization in it, had been found ineffectual. 
 Hence this discovery was justly considered as lending 
 great countenance to the opinion that heat consists in 
 the vibrations of its proper medium. 
 
 But what is this medium ? Is it the same by which 
 the impressions of light are conveyed ? This is a difficult 
 question ; or rather it is one which we cannot at present 
 hope to answer with certainty. No doubt the con- 
 nexion between light and heat is so intimate and con- 
 stant, that we can hardly refrain from considering them 
 as affections of the same medium. But instead of 
 attempting to erect our systems on such loose and 
 general views of connexion, it is rather the business of 
 the philosophers of the present day to determine the 
 laws of the operation of heat, and its real relation to 
 light, in order that we may afterwards be able to con- 
 nect the theories of the two qualities. Perhaps in a 
 more advanced state of our knowledge we may be able 
 to state it as an axiom, that two secondary qualities, 
 which are intimately connected in their causes and 
 effects, must be affections of the same medium. But at 
 present it does not appear safe to proceed upon such a 
 principle, although many writers, in their speculations 
 both concerning light and heat, and concerning other 
 properties, have not hesitated to do so. 
 
 Some other consequences follow from the Idea of a 
 Medium which must be the subject of another chapter. 
 
319 
 
 CHAPTER IV. 
 OF THE MEASURE OF SECONDARY QUALITIES. 
 
 SECT. I. Scales of Qualities in general 
 
 THE ultimate object of our investigation in each of the 
 Secondary Mechanical Sciences, is the nature of the pro- 
 cesses by which the special impressions of sound, light, 
 and heat, are conveyed, and the modifications of which 
 these processes are susceptible. And of this investiga- 
 tion, as we have seen, the necessary basis is the principle, 
 that these impressions are transmitted by means of a 
 medium. But before we arrive at this ultimate object, 
 we may find it necessary to occupy ourselves with seve- 
 ral intermediate objects : before we discover the cause, 
 it may be necessary to determine the lares of the phe- 
 nomena. Even if we cannot immediately ascertain the 
 mechanism of light or heat, it may still be interesting 
 and important to arrange and measure the effects which 
 we observe. 
 
 The idea of a medium affects our proceeding in this 
 research also. We cannot measure secondary qualities 
 in the same manner in which we measure primary quali- 
 ties, by a mere addition of parts. There is this leading 
 and remarkable difference, that while both classes of 
 qualities are susceptible of changes of magnitude, primary 
 qualities increase by addition of extension, secondary, by 
 augmentation of intensity. A space is doubled when 
 another equal space is placed by its side; one weight 
 joined to another makes up the sum of the two. But 
 when one degree of warmth is combined with another, 
 or one shade of red colour with another, we cannot in 
 like manner talk of the sum. The component parts do 
 not evidently retain their separate existence ; we cannot 
 
320 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 separate a strong green colour into two weaker ones, as 
 we can separate a large force into two smaller. The 
 increase is absorbed into the previous amount, and is no 
 longer in evidence as a part of the whole. And this is 
 the difference which has given birth to the two words 
 extended, and intense. That is extended which has 
 "partes extra partes," parts outside of parts: that is 
 intense which becomes stronger by some indirect and 
 unapparent increase of agency, like the stretching of the 
 internal springs of a machine, as the term intense im- 
 plies. Extended magnitudes can at will be resolved 
 into the parts of which they were originally composed, 
 or any other which the nature of their extension admits ; 
 their proportion is apparent ; they are directly and at 
 once subject to the relations of number. Intensive 
 magnitudes cannot be resolved into smaller magnitudes ; 
 we can see that they differ, but we cannot tell in what 
 proportion; we have no direct measure of their quan- 
 tity. How many times hotter than blood is boiling 
 water? The answer cannot be given by the aid of our 
 feelings of heat alone. 
 
 The difference, as we have said, is connected with 
 the fundamental principle that we do not perceive 
 secondary qualities directly, but through a medium. We 
 have no natural apprehension of light, or sound, or heat, 
 as they exist in the bodies from which they proceed, but 
 only as they affect our organs. We can only measure 
 them, therefore, by some Scale supplied by their effects. 
 And thus while extended magnitudes, as space, time, are 
 measurable directly and of themselves; intensive mag- 
 nitudes, as brightness, loudness, heat, are measurable 
 only by artificial means and conventional scales. Space, 
 time, measure themselves: the repetition of a smaller 
 space, or time, while it composes a larger one, measures 
 it. But for light and heat we must have Photometers 
 
MEASURE OF SECONDARY QUALITIES. 321 
 
 and Thermometers, which measure something which is 
 assumed to be an indication of the quality in question. 
 In one case, the mode of applying the measure, and 
 the meaning of the number resulting, are seen by intui- 
 tion ; in the other, they are consequences of assumption 
 and reasoning. In the one case, they are Units, of 
 which the extension is made up ; in the other, they are 
 Degrees by which the intensity ascends. 
 
 2. When we discover any property in a sensible 
 quality, which at once refers us to number or space, we 
 readily take this property as a measure; and thus we 
 make a transition from quality to quantity. Thus Pto- 
 lemy in the third chapter of the First Book of his Har- 
 monics begins thus : " As to the differences which exist 
 in sounds both in quality and in quantity, if we consider 
 that difference which refers to the acuteness and grave- 
 ness, we cannot" at once tell to which of the above two 
 classes it belongs, till we have considered the causes of 
 such symptoms." But at the end of the chapter, having 
 satisfied himself that grave sounds result from the mag- 
 nitude of the string or pipe, other things being equal, 
 he infers, " Thus the difference of acute and grave ap- 
 pears to be a difference of quantity" 
 
 In the same manner, in order to form Secondary 
 Mechanical Sciences respecting any of the other pro- 
 perties of bodies, we must reduce these properties to a 
 dependence upon quantity, and thus make them subject 
 to measurement. We cannot obtain any sciential truths 
 respecting the comparison of sensible qualities, till we 
 have discovered measures and scales of the qualities 
 which we have to consider; and accordingly, some of 
 the most important steps in such sciences have been the 
 establishment of such measures and scales, and the inven- 
 tion of the requisite instruments. 
 
 The formation of the mathematical sciences which 
 VOL. i. w. P. Y 
 
322 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 rest upon the measures, of the intensity of sensible qua- 
 lities took place mainly in the course of the last century. 
 Perhaps we may consider Lambert, a mathematician 
 who resided in Switzerland, and published about 1750, 
 as the person who first clearly felt the importance of 
 establishing such sciences. His Photometry, Pyrometry, 
 Hygrometry, are examples of the systematic reduction 
 of sensible qualities (light, heat, moisture) to modes of 
 numerical measurement. 
 
 We now proceed to speak of such modes of measure- 
 ment with regard to the most obvious properties of 
 bodies. 
 
 SECT. II The Musical Scale. 
 
 3. THE establishment of the Harmonic Canon, that 
 is, of a Scale and Measure of the musical place of notes, 
 in the relation of high and low, was the 'first step in the 
 science of Harmonics. The perception of the differences 
 and relations of musical sounds is the office of the sense 
 of hearing ; but these relations are fixed, and rendered 
 accurately recognizable by artificial means. "Indeed, 
 in all the senses," as Ptolemy truly says in the opening 
 of his Harmonics, " the sense discovers what is approxi- 
 mately true, and receives accuracy from another quarter: 
 the reason receives the approximately-true from another 
 quarter, and discovers the accurate truth." We can 
 have no measures of sensible qualities which do not 
 ultimately refer to the sense ; whether they do this 
 immediately, as when we refer Colours to an assumed 
 Standard; or mediately, as when we measure Heat by 
 Expansion, having previously found by an appeal to 
 sense that the expansion increases with the heat. Such 
 relations of sensible qualities cannot be described in 
 words, and can only be apprehended by their appropriate 
 faculty. The faculty by which the relations of sounds 
 
MEASURE OF SECONDARY QUALITIES. 323 
 
 are apprehended is a musical ear in the largest accep- 
 tation of the term. In this signification the faculty is 
 nearly universal among men; for all persons have musical 
 ears sufficiently delicate to understand and to imitate 
 the modulations corresponding to various emotions in 
 speaking; which modulations depend upon the succes- 
 sion of acuter and graver tones. These are the relations 
 now spoken of, and these are plainly perceived by per- 
 sons who have very imperfect musical ears, according to 
 the common use of the phrase. But the relations of 
 tones which occur in speaking are somewhat indefinite ; 
 and in forming that musical scale which is the basis of 
 our science upon the subject, we take the most definite 
 and marked of such relations of notes ; such as occur, 
 not in speaking but in singing. Those musical relations 
 of two sounds which we call the octave, the fifth, the 
 fourth, the third, are recognized after a short familiarity 
 with them. These chords or intervals are perceived to 
 have each a peculiar character, which separates them 
 from the relations of two sounds taken at random, and 
 makes it easy to know them when sung or played on 
 an instrument ; and for most persons, not difficult to 
 sing the sounds in succession exactly, or nearly correct. 
 These musical relations, or concords, then, are the ground- 
 work of our musical standard. But how are we to name 
 these indescribable sensible characters? how to refer, 
 with unerring accuracy, to a type which exists only in 
 our own perceptions? We must have for this purpose 
 a Scale and a Standard. 
 
 The Musical Scale is a series of eight notes, ascend- 
 ing by certain steps from the first or key-note to the 
 octave above it, each of the notes being fixed by such 
 distinguishable musical relations as we have spoken of 
 above. We may call these notes c, D, E, F, G, A, B, c ; 
 and we may then say that G is determined by its being a 
 
324 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 fifth above c ; D by its being a fourth below G ; E by its 
 being a third above c ; and similarly of the rest. It 
 will be recollected that the terms a fifth, a fourth, a 
 third, have hitherto been introduced as expressing cer- 
 tain simple and indescribable musical relations among 
 sounds, which might have been indicated by any other 
 names. Thus we might call the fifth the dominant, and 
 the fourth the subdominant, as is done in one part of 
 musical science. But the names we have used, which 
 are the common ones, are in fact derived from the num- 
 ber of notes which these intervals include in the scale 
 obtained in the above manner. The notes c, D, E, F, G, 
 being five, the interval from c to G is a fifth, and so of 
 the rest. The fixation of this scale gave the means of 
 describing exactly any note which occurs in the scale, 
 and the method is easily applicable to notes above and 
 below this range ; for in a series of sounds higher or 
 lower by an octave than this standard series, the ear 
 discovers a recurrence of the same relations so exact, 
 that a person may sometimes imagine he is producing 
 the same notes as another when he is singing the same 
 air an octave higher. Hence the next eight notes may 
 be conveniently denoted by a repetition of the same 
 letters, as the first ; thus, c, D, E, F, G, A, B, c, d, e,f, g, 
 a, b; and it is easy to devise a continuation of such 
 cycles. And other admissible notes are designated by a 
 further modification of the standard ones, as by making 
 each note flat or sharp; which modification it is not 
 necessary here to consider, since our object is only to 
 show how a standard is attainable, and how it serves the 
 ends of science. 
 
 We may observe, however, that the above is not an 
 exact account of the first, or early Greek scale ; for this 
 scale was founded on a primary division of the interval 
 of two octaves (the extreme range which it admitted) 
 
MEASURE OF SECONDARY QUALITIES. 325 
 
 into five tetrachords, each tetrachord including the in- 
 terval of a fourth. All the notes of this series had 
 different names borrowed from this division"'" ; thus mese 
 was the middle or key-note; the note below it was 
 lichanos meson, the next below was parypate mes6n, the 
 next lower, hypate meson. The fifth above mese was 
 nete diazeugmenbn, the octave was nete hyperbolcedn. 
 
 4. But supposing a complete system of such denomi- 
 nations established, how could it be with certainty and 
 rigour applied ? The human ear is fallible, the organs 
 of voice imperfectly obedient; if this were not so, there 
 would be no such thing as a good ear or a good voice. 
 What means can be devised of finding at will a perfect 
 concord, a fifth or a fourth? Or supposing such con- 
 cords fixed by an acknowledged authority, how can they 
 be referred to, and the authority adduced? How can 
 we enact a Standard of sounds ? 
 
 A Standard was discovered in the Monochord. A 
 musical string properly stretched, may be made to pro- 
 duce different notes, in proportion as we intercept a 
 longer or shorter portion, and make this portion vibrate. 
 The relation of the length of the strings which thus 
 sound the two notes G and c is fixed and constant, and 
 the same is true of all other notes. Hence the musical 
 interval of any notes of which we know the places in 
 the musical scale, may be reproduced by measuring the 
 lengths of string which are known to give them. If c 
 be of the length 180, D is 169, E is 144, F is 135, G is 
 120 ; and thus the musical relations are reduced to 
 numerical relations, and the monochord is a complete 
 and perfect Tonometer. 
 
 We have here taken the length of the string as the 
 measure of the tone : but we may observe that there is 
 in us a necessary tendency to assume that the ground 
 
 * Barney's History of Music, Vol. i. p. 28. 
 
326 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 of this measure is to be sought in some ulterior cause ; 
 and when we consider the matter further, we find this 
 cause in the frequency of these vibrations of the string. 
 The truth that the same note must result from the same 
 frequency of vibration is readily assented to on a slight 
 suggestion of experience. Thus Mersenne"*, when he 
 undertakes to determine the frequency of vibrations of a 
 given sound, says "Supponendum est quoscunque nervos 
 et quaslibet chordas unisonum facientes eundem efficere 
 numerum recursuum eodem vel equali tempore, quod 
 perpetua constat experientia." And he proceeds to 
 apply it to cases where experience could not verify this 
 assertion, or at least had not verified it, as to that of 
 pipes. 
 
 The pursuit of these numerical relations of tones 
 forms the science of Harmonics ; of which here we do 
 not pretend to give an account, but only to show, how 
 the invention of a Scale and Nomenclature, a Standard 
 and Measure of the tone of sounds, is its necessary basis. 
 We will therefore now proceed to speak of another sub- 
 ject; colour. 
 
 SECT. III. Scales of Colour. 
 
 5. The Prismatic Scale of Colour. A SCALE of 
 Colour must depend originally upon differences discern- 
 ible by the eye, as a scale of notes depends on differences 
 perceived by the ear. In one respect the difficulty is 
 greater in the case of the visible qualities, for there are 
 no relations of colour which the eye peculiarly singles 
 out and distinguishes, as the ear selects and distinguishes 
 an octave or a fifth. Hence we are compelled to take 
 an arbitrary scale ; and we have to find one which is 
 fixed, and which includes a proper collection of colours. 
 The prismatic spectrum, or coloured image produced 
 
 * Harmonici, Lib. u. Prop. 1.9. 
 
MEASURE OF SECONDARY QUALITIES. 327 
 
 when a small beam of light passes obliquely through 
 any transparent surface (as the surface of a prism of 
 glass,) offers an obvious Standard as far as it is appli- 
 cable. Accordingly colours have, for various purposes, 
 been designated by their place in the spectrum ever 
 since the time of Newton ; and we have thus a means of 
 referring to such colours as are included in the series 
 red, orange, yellow, green, blue, violet, indigo, and the 
 intermediate tints. 
 
 But this scale is not capable of numerical precision. 
 If the spectrum could be exactly denned as to its ex- 
 tremities, and if these colours occupied always the same 
 proportional part of it, we might describe any colour in 
 the above series by the measure of its position. But 
 the fact is otherwise. The spectrum is too indefinite in 
 its boundaries to afford any distinct point from which 
 we may commence our measures; and moreover the 
 spectra produced by different transparent bodies differ 
 from each other. Newton had supposed that the spec- 
 trum and its parts were the same, so long as the refrac- 
 tion was the same ; but his successors discovered that, 
 with the same amount of refraction in different kinds of 
 glass, there are different magnitudes of the spectrum ; 
 and what is still worse with reference to our present 
 purpose, that the spectra from different glasses have 
 the colours distributed in different proportions. In order, 
 therefore, to make the spectrum the scale of colour, we 
 must assume some fixed substance ; for instance, we may 
 take water, and thus a series approaching to the colours 
 of the rainbow will be our standard. But we should 
 still have an extreme difficulty in applying such a rule. 
 The distinctions of colour which the terms of common 
 language express, are not used with perfect unanimity 
 or with rigorous precision. What one person calls bluish 
 green another calls greenish blue. Nobody can say 
 
328 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 what is the precise boundary between red and orange. 
 Thus the prismatic scale of colour was incapable of 
 mathematical exactness, and this inconvenience was felt 
 up to our own times. 
 
 But this difficulty was removed by a curious dis- 
 covery of Wollaston and Fraunhofer ; who found that 
 there are, in the solar spectrum, certain fine black Lines 
 which occupy a definite place in the series of colours, 
 and can be observed with perfect precision. We have 
 now no uncertainty as to what coloured light we are 
 speaking of, when we describe it as that part of the 
 spectrum in which Fraunhofer's Line c or D occurs. 
 And thus, by this discovery, the prismatic spectrum of 
 sunlight became, for certain purposes, an exact Chroma- 
 tometer. 
 
 6. Newton s Scale of Colours. Still, such a standard, 
 though definite, is arbitrary and seemingly anomalous. 
 The lines A, B, c, D, &c., of Fraunhofer's spectrum are 
 distributed without any apparent order or law ; and we 
 do not, in this way, obtain numerical measures, which is 
 what, in all cases, we desire to have. Another discovery 
 of Newton, however, gives us a spectrum containing the 
 same colours as the prismatic spectrum, but produced in 
 another way, so that the colours have a numerical rela- 
 tion. I speak of the laws of the colours of thin plates. 
 The little rainbows which we sometimes see in the cracks 
 of broken glass are governed by fixed and simple laws. 
 The kind of colour produced at any point depends on 
 the thickness of the thin plate of air included in the fis- 
 sure. If the thickness be eight-millionths of an inch, 
 the colour is orange, if fifteen-millionths of an inch, we 
 have green, and so on ; and thus these numbers which 
 succeed each other in a regular order from red to indigo, 
 give a numerical measure of each colour ; which mea- 
 sure, when we pursue the subject, we find is one of the 
 
MEASURE OF SECONDARY QUALITIES. 329 
 
 bases of all optical theory. The series of colours ob- 
 tained from plates of air of gradually increasing thick- 
 ness is called Newton s Scale of Colours ; but we may 
 observe that this is not precisely what we are here speak- 
 ing of, a scale of simple colours ; it is a series produced 
 by certain combinations, resulting from the repetition of 
 the first spectrum, and is mainly useful as a standard for 
 similar phenomena, and not for colour in general. The 
 real scale of colour is to be found, as we have said, in 
 the numbers which express the thickness of the pro- 
 ducing film; in the length of &jit in Newton's phrase- 
 ology, or the length of an undulation in the modern 
 theory. 
 
 7. Scales of Impure Colours. The standards just 
 spoken of include (mainly at least) only pure and simple 
 colours ; and however complete they may be for certain 
 objects of the science of optics, they are insufficient for 
 other purposes. They do not enable us to put in their 
 place mixed and impure colours. And there is, in the 
 case of colour, a difficulty already noticed, which does 
 not occur in the case of sound ; two notes, when sounded 
 together, are not necessarily heard as one; they are 
 recognized as still two, and as forming a concord or a 
 discord. But two colours form a single colour ; and the 
 eye cannot, in any way, distinguish between a green 
 compounded of blue and yellow, and the simple, unde- 
 composable green of the spectrum. By composition of 
 three or more colours, innumerable new colours may be 
 generated which form no part of the prismatic series ; 
 and by such compositions is woven the infinitely varied 
 web of colour which forms the clothing of nature. How 
 are we to classify and arrange all the possible colours 
 of objects, so that each shall have a place and name? 
 How shall we find a chromatometer for impure as well 
 as for pure colour ? 
 
330 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 Though no optical investigations have depended on a 
 scale of impure colours, such a scale has been wanted 
 and invented for other purposes ; for instance, in order 
 to identify and describe objects of natural history. Not 
 to speak of earlier essays, we may notice Werner's No- 
 menclature of Colours, devised for the purpose of de- 
 scribing minerals. This scale of colour was far superior 
 to any which had previously been promulgated. It was, 
 indeed, arbitrary in the selection of its degrees, and in 
 a great measure in their arrangement ; and the colours 
 were described by the usual terms, though generally 
 with some added distinction ; as blackish green, bluish 
 green, apple-green, emerald-green. But the great merit 
 of the scale was its giving a fioced conventional meaning 
 to these terms, so that they lost much of their usual 
 vagueness. Thus apple-green did not mean the colour 
 of any green apple casually taken ; but a certain definite 
 colour which the student was to bear in mind, whether or 
 not he had ever seen an apple of that exact hue. The 
 words were not a description, but a record of the colour : 
 the memory was to retain a sensation, not a name. 
 
 The imperfection of the system (arising from its ar- 
 bitrary form) was its incompleteness : however well it 
 served for the reference of the colours which it did con- 
 tain, it was applicable to no others; and thus, though 
 Werner's enumeration extended to more than a hundred 
 colours, there occur in nature a still greater number 
 which cannot be exactly described by means of it. 
 
 In such cases the unclassed colour is, by the Werne- 
 rians, defined by stating it as intermediate between two 
 others: thus we have an object described as between 
 emerald-green and grass-green. The eye is capable of 
 perceiving a gradation from one colour to another ; such 
 as may be produced by a gradual mixture in various 
 ways. And if we image to ourselves such a mixture, we 
 
MEASURE OF SECONDARY QUALITIES. 331 
 
 can compare with it a given colour. But in employing 
 this method we have nothing to tell us in what part of 
 the scale we must seek for an approximation to our un- 
 classed colour. We have no rule for discovering where 
 we are to look for the boundaries of the definition of a 
 colour which the Wernerian series does not supply. 
 For it is not always between contiguous members of the 
 series that the undescribed colour is found. If we place 
 emerald-green between apple-green and grass-green, we 
 may yet have a colour intermediate between emerald- 
 green and leek-green ; and, in fact, the Wernerian series 
 of colours is destitute of a principle of self-arrangement 
 and gradation ; and is thus necessarily and incurably 
 imperfect. 
 
 8. We should have a complete Scale of Colours, if 
 we could form a series including all colours, and arranged 
 so that each colour was intermediate in its tint between 
 the adjacent terms of the series; for then, whether we 
 took many or few of the steps of the series for our 
 standard terms, the rest could be supplied by the law of 
 continuity; and any given colour would either cor- 
 respond to one of the steps of our scale or fall between 
 two intermediate ones. The invention of a Chroma- 
 tometer for Impure Colours, therefore, requires that we 
 should be able to form all possible colours by such inter- 
 mediation in a systematic manner ; that is, by the mix- 
 ture or combination of certain elementary colours ac- 
 cording to a simple rule : and we are led to ask whether 
 such a process has been shown to be possible. 
 
 The colours of the prismatic spectrum obviously do 
 form a continuous series ; green is intermediate between 
 its neighbours yellow and blue, orange between red and 
 yellow ; and if we suppose the two ends of the spectrum 
 bent round to meet each other, so that the arrangement 
 of the colours may be circular, the violet and indigo will 
 
332 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 find their appropriate place between the blue and red. 
 And all the interjacent tints of the spectrum, as well as 
 the ones thus named, will result from such an arrange- 
 ment. Thus all the pure colours are produced by com- 
 binations two and two of three primary colours, red, 
 yellow, and blue; and the question suggests itself 
 whether these three are not really the only primary 
 colours, and whether all the impure colours do not arise 
 from mixtures of the three in various proportions. 
 There are various modes in which this suggestion may 
 be applied to the construction of a scale of colours ; but 
 the simplest, and the one which appears really to verify 
 the conjecture that all possible colours may be so ex- 
 hibited, is the following. A certain combination of red, 
 yellow, and blue, will produce black, or pure grey, and 
 when diluted, will give all the shades of grey which 
 intervene between black and white. By adding various 
 shades of grey, then, to pure colours, we may obtain all 
 the possible ternary combinations of red, yellow, and 
 blue ; and in this way it is found that we exhaust the 
 range of colours. Thus the circle of pure colours of 
 which we have spoken may be accompanied by several 
 other circles, in which these colours are tinged with a 
 less or greater shade of grey ; and in this manner it is 
 found that we have a perfect chromatometer ; every 
 possible colour being exhibited either exactly or by 
 means of approximate and contiguous limits. The ar- 
 rangement of colours has been brought into this final 
 and complete form by M. Merimee, whose Chromatic 
 Scale is published by M. Mirbel in his Elements of Bo- 
 tany. We may observe that such a standard affords us 
 a numerical exponent for every colour by means of the 
 proportions of the three primary colours which compose 
 it ; or, expressing the same result otherwise, by means 
 of the pure colour which is involved, and the proportion 
 
MEASURE OF SECONDARY QUALITIES. 333 
 
 of grey by which it is rendered impure. In such a 
 scale the fundamental elements would be the precise 
 tints of red, yellow, and blue which are found or as- 
 sumed to be primary ; the numerical exponents of each 
 colour would depend upon the arbitrary number of de- 
 grees which we interpose between each two primary 
 colours; and between each pure colour and absolute 
 blackness. No such numerical scale has, however, as yet, 
 obtained general acceptation*. 
 
 SECT. IV. Scales of Light. 
 
 9. Photometer. ANOTHER instrument much needed 
 in optical researches is a Photometer, a measure of the 
 intensity of light. Jn this case, also, the organ of sense, 
 the eye, is the ultimate judge; nor has any effect of 
 light, as light, yet been discovered which we can sub- 
 stitute for such a judgment. All instruments, such as 
 that of Leslie, which employ the heating effect of light, 
 or at least all that have hitherto been proposed, are in- 
 admissible as photometers. But though the eye can 
 
 * The reference to Fraunhofers Lines, as a means of determining 
 the place of a colour in the prismatic series, has been objected to, 
 because, as is asserted, the colours which are in the neighbourhood of 
 each line vary with the position of the sun, state of the atmosphere 
 and the like. It is very evident that coloured light refracted by the 
 prism will not give the same spectrum as white light. The spectrum 
 given by white light is of course the one here meant. It is an usual 
 practice of optical experimenters to refer to the colours of such a 
 spectrum, denning them by Fraunhofer's Lines. 
 
 I do not know whether it needs explanation that the " first spec- 
 trum" in Newton's rings is a ring of the prismatic colours. 
 
 I have not had an opportunity of consulting Lambert's Photometria^ 
 sive de mensura et gradibus luminis, colorum, et umbrce^ published in 
 1760, nor Mayer's Commentatio de Affinitate Colorum, (1758,) in 
 which, I believe, he describes a chromatometer. The present work is 
 not intended to be complete as a history ; and I hope I have given 
 sufficient historical detail to answer its philosophical purpose. 
 
334 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 judge of two surfaces illuminated by light of the same 
 colour, and can determine when they are equally bright, 
 or which is the brighter, the eye can by no means decide 
 at sight the proportion of illumination. How much in 
 such judgments we are affected by contrast, is easily seen 
 when we consider how different is the apparent bright- 
 ness of the moon at mid-day and at midnight, though 
 the light which we receive from her is, in fact, the same 
 at both periods. In order to apply a scale in this case, 
 we must take advantage of the known numerical rela- 
 tions of light. We are certain that if all other illumi- 
 nation be excluded, two equal luminaries, under the 
 same circumstances, will produce an illumination twice 
 as great as one does ; and we can easily prove, from ma- 
 thematical considerations, that if light be not enfeebled 
 by the medium through which it passes, the illumination 
 on a given surface will diminish as the square of the 
 distance of the luminary increases. If, therefore, we 
 can by taking a fraction thus known of the illuminating 
 effect of one luminary, make it equal to the total effect 
 of another, of which equality the eye is a competent 
 judge, we compare the effects of the two luminaries. In 
 order to make this comparison we may, with Rumford, 
 look at the shadows of the same object made by the two 
 lights, or with Ritchie, we may view the brightness pro- 
 duced on two contiguous surfaces, framing an apparatus 
 so that the equality may be brought about by proper 
 adjustment; and thus a measure will become practica- 
 ble. Or we may employ other methods as was done by 
 Wollaston *, who reduced the light of the sun by observ- 
 ing it as reflected from a bright globule, and thus found 
 the light of the sun to be 10,000,000,000 times that of 
 Sirius, the brightest fixed star. All these methods are 
 inaccurate, even as methods of comparison ; and do not 
 * Phil. Trans., 1829, p. 19. 
 
MEASURE OF SECONDARY QUALITIES. 335 
 
 offer any fixed or convenient numerical standard; but 
 none better have yet been devised'-. 
 
 10. Cyanometer. As we thus measure the brightness 
 of a colourless light, we may measure the intensity of 
 any particular colour in the same way; that is, by apply- 
 ing a standard exhibiting the gradations of the colour in 
 question till we find a shade which is seen to agree with 
 the proposed object. Such an instrument we have in 
 the Cyanometer, which was invented by Saussure for the 
 purpose of measuring the intensity of the blue colour of 
 the sky. We may introduce into such an instrument a 
 numerical scale, but the numbers in such a scale will be 
 altogether arbitrary. 
 
 SECT.' V. Scales of Heat. 
 
 11. Thermometers. WHEN we proceed to the sensa- 
 tion of heat, and seek a measure of that quality, we find, 
 at first sight, new difficulties. Our sensations of this 
 kind are more fluctuating than those of vision ; for we 
 know that the same object may feel warm to one hand 
 and cold to another at the same instant, if the hands 
 have been previously cooled and warmed respectively. 
 Nor can we obtain here, as in the case of light, self-evi- 
 dent numerical relations of the heat communicated in 
 given circumstances ; for we know that the effect so pro- 
 duced will depend on the warmth of the body to be 
 heated, as well as on that of the source of heat; the 
 summer sun, which warms our bodies, will not augment 
 the heat of a red-hot iron. The cause of the differ- 
 ence of these cases is, that bodies do not receive the 
 whole of their heat, as they receive the whole of their 
 light, from the immediate influence of obvious external 
 
 * Improved Photometers have been devised by Professor Wheat- 
 stone, Professor Potter, and Professor Steinheil ; but they depend upon 
 principles similar to those mentioned in the text. 
 
336 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 agents. There is no readily-discovered absolute cold, 
 corresponding to the absolute darkness which we can 
 easily produce or imagine. Hence we should be greatly 
 at a loss to devise a Thermometer, if we did not find an 
 indirect effect of heat sufficiently constant and measurable 
 to answer this purpose. We discover, however, such an 
 effect in the expansion of bodies by the effect of heat. 
 
 12. Many obvious phenomena show that air, under 
 given circumstances, expands by the effect of heat ; the 
 same is seen to be true of liquids, as of water, and spirit 
 of wine ; and the property is found to belong also to the 
 metallic fluid, quicksilver. A more careful examination 
 showed that the increase of bulk in some of these bodies 
 by increase of heat was a fact of a nature sufficiently 
 constant and regular to afford a means of measuring that 
 previously intangible quality ; and the Thermometer was 
 invented. There were, however, many difficulties to 
 overcome, and many points to settle, before this instru- 
 ment was fit for the purposes of science. 
 
 An explanation of the way in which this was done 
 necessarily includes an important chapter of the history 
 of Thermotics. We must now, therefore, briefly notice 
 historically the progress of the Thermometer. The lead- 
 ing steps of this progress, after the first invention of the 
 instrument, were The establishment of fixed points in 
 the thermometric scale The comparison of the scales 
 of different substances And the reconcilement of these 
 differences by some method of interpreting them as indi- 
 cations of the absolute quantity of heat. 
 
 13. It would occupy too much space to give in detail 
 the history of the successive attempts by which these 
 steps were effected. A thermometer is described by 
 Bacon under the title Vitrum Calendare ; this was an 
 air thermometer. Newton used a thermometer of linseed 
 oil, and he perceived that the first step requisite to give 
 
MEASURE OF SECONDARY QUALITIES. 337 
 
 value to such an instrument was to fix its scale ; accord- 
 ingly he proposed his Scala Graduum Caloris*. But 
 when thermometers of different liquids were compared, 
 it appeared, from their discrepancies, that this fixation 
 of the scale of heat was more difficult than had been 
 supposed. It was, however, effected. Newton had taken 
 freezing water, or rather thawing snow, as the zero of 
 his scale, which is really a fixed point; Halley and Amon- 
 tons discovered (in 1693 and 1702) that the heat of 
 boiling water is another fixed point ; and Daniel Gabriel 
 Fahrenheit, of Dantzig, by carefully applying these two 
 standard points, produced, about 1714, thermometers, 
 which were constantly consistent with each other. This 
 result was much admired at the time, and was, in fact, 
 the solution of the problem just stated, the fixation of 
 the scale of heat. 
 
 14. But the scale thus obtained is a conventional 
 not a natural scale. It depends upon the fluid employed 
 for the thermometer. The progress of expansion from 
 the heat of freezing to that of boiling water is different 
 for mercury, oil, water, spirit of wine, air. A degree of 
 heat which is half-way between these two standard 
 points according to a mercurial thermometer, will be 
 below the half-way point in a spirit thermometer, and 
 above it in an air thermometer. Each liquid has its 
 own march in the course of its expansion. Deluc and 
 others compared the marches of various liquids, and 
 thus made what we may call a concordance of thermo- 
 meters of various kinds. 
 
 15. Here the question further occurs : Is there not 
 some natural measure of the degrees of heat ? It ap- 
 pears certain that there must be such a measure, and 
 that by means of it all the scales of different liquids 
 must be reconciled. Yet this does not seem to have 
 
 * Phil Trans., 1701. 
 VOL. I. W. P. Z 
 
338 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 occurred at once to men's minds. Deluc, in speaking 
 of the researches which we have just mentioned, says*, 
 "When I undertook these experiments, it never once 
 came into my thoughts that they could conduct me with 
 any probability to a table of real degrees of heat. But 
 hope grows with success, and desire with hope." Accord- 
 ingly he pursued this inquiry for a long course of years. 
 What are the principles by which we are to be 
 guided to the true measure of heat ? Here, as in all the 
 sciences of this class, we have the general principle, that 
 the secondary quality, heat, must be supposed to be per- 
 ceived in some way by a material medium or fluid. If 
 we take that which is, perhaps, the simplest form of this 
 hypothesis, that the heat depends upon the quantity of 
 this fluid, or caloric, which is present, we shall find that 
 we are led to propositions which may serve as a foun- 
 dation for a natural measure of heat. The Method of 
 Mixtures is one example of such a result. If we mix 
 together two pints of water, one hot and one cold, is it 
 not manifest that the temperature of the mixture must 
 be midway between the two? Each of the two portions 
 brings with it its own heat. The whole heat, or caloric, 
 of the mixture is the sum of the two ; and the heat of 
 each half must be the half of this sum, and therefore its 
 temperature must be intermediate between the tempe- 
 ratures of the equal portions which were mixed. Deluc 
 made experiments founded upon this principle, and was 
 led by them to conclude that "the dilatations of mer- 
 cury follow an accelerated march for successive equal 
 augmentations of heat." 
 
 But there are various circumstances which prevent 
 this method of mixtures from being so satisfactory as 
 at first sight it seems to promise to be. The different 
 capacities for heat of different substances, and even of 
 
 * Modif. de I'Atmosph., 1782, p. 303. 
 
MEASURE OF SECONDARY QUALITIES. 339 
 
 the same substance at different temperatures, introduce 
 much difficulty into the experiments; and this path of 
 inquiry has not yet led to a satisfactory result. 
 
 16. Another mode of inquiring into the natural 
 measure of heat is to seek it by researches on the law 
 of cooling of hot bodies. If we assume that the process 
 of cooling of hot bodies consists in a certain material 
 heat flying off, we may, by means of certain probable 
 hypotheses, determine mathematically the law according 
 to which the temperature decreases as time goes on ; and 
 we may assume that to be the true measure of tempe- 
 rature which gives to the experimental law of cooling 
 the most simple and probable form. 
 
 It appears evident from the most obvious conceptions 
 which we can form of the manner in which a body parts 
 with its superabundant heat, that the hotter a body is, 
 the faster it cools ; though it is not clear without expe- 
 riment, by what law the rate of cooling will depend upon 
 the heat of the body. Newton took for granted the 
 most simple and seemingly natural law of this depend- 
 ence : he supposed the rate of cooling to be proportional 
 to the temperature, and from this supposition he could 
 deduce the temperature of a hot iron, calculating from 
 the original temperature and the time during which it 
 had been cooling. By calculation founded on such a 
 basis, he graduated his thermometer. 
 
 17. But a little further consideration showed that 
 the rate of cooling of hot bodies depended upon the 
 temperature of the surrounding bodies, as well as upon 
 its own temperature. Prevost's Theory of Exchanges* 
 was propounded with a view of explaining this depend- 
 ence, and was generally accepted. According to this 
 theory, all bodies radiate heat to one another, and are 
 thus constantly giving and receiving heat; and a body 
 
 * Eecherches sur la Chaleur^ 1791. Hist. Ind. Sci., B. x. c. i. sect. 2. 
 
 Z2 
 
340 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 which is hotter than surrounding bodies, cools itself, 
 and warms the surrounding bodies, by an exchange of 
 heat for heat, in which they are the gainers. Hence if 
 be the temperature of the bodies, or of the space, by 
 which the hot body is surrounded, and + t the tempe- 
 rature of the hot body, the rate of cooling will depend 
 upon the excess of the radiation for a temperature 9 + t, 
 above the radiation for a temperature 0. 
 
 Accordingly, in the admirable researches of MM. 
 Dulong and Petit upon the cooling of bodies, it was 
 assumed that the rate of cooling of the hot body was 
 represented by the excess of F (0 + t) above F (6) ; where 
 F represented some mathematical function, that is, some 
 expression obtained by arithmetical operations from the 
 temperatures + t and 9; although what these operations 
 are to be, was left undecided, and was in fact determined 
 by the experiments. And the result of their investiga- 
 tions was, that the function is of this kind : when the 
 temperature increases by equal intervals, the function 
 increases in a continued geometric proportion*. This 
 was, in fact, the same law which had been assumed by 
 Newton and others, with this difference, that they had 
 neglected the term which depends upon the temperature 
 of the surrounding space. 
 
 18. This law falls in so well with the best concep- 
 tions we can form of the mechanism of cooling upon the 
 supposition of a radiant fluid caloric, that it gives great 
 probability to the scale of temperature on which the 
 simplicity of the result depends. Now the temperatures 
 in the formulae just referred to were expressed by means 
 of the air thermometer. Hence MM. Dulong and Petit 
 justly state that while all different substances employed 
 
 * The formula for the rate of cooling is ma e+t ma e , where the 
 quantity m depends upon the nature of the body, the state of its sur- 
 face, and other circumstances. Ann. Chim. vn. 150. 
 
MEASURE OF SECONDARY QUALITIES. 341 
 
 as thermometers give different laws of thermotical phe- 
 nomena, their own success in obtaining simple and 
 general laws by means of the air thermometer, is a strong 
 recommendation of that as the natural scale of heat. 
 They add*"", " The well-known uniformity of the principal 
 physical properties of all gases, and especially the per- 
 fect identity of their laws of dilatation by heat, [a very 
 important discovery of Dalton and Gay Lussacf,] make 
 it very probable that in this class of bodies the disturb- 
 ing causes have not the same influence as in solids and 
 liquids ; and consequently that the changes of bulk pro- 
 duced by the action of heat are here in a more imme- 
 diate dependence on the force which produces them." 
 
 19. Still we cannot consider this point as settled 
 till we obtain a more complete theoretical insight into 
 the nature of heat itself. If it be true that heat con- 
 sists in the vibrations of a fluid, then, although, as 
 Ampere has shown \, the laws of radiation will, on 
 mathematical grounds, be the same as they are on the 
 hypothesis of emission, we cannot consider the natural 
 scale of heat as determined, till we have discovered some 
 means of measuring the caloriferous vibrations as" we 
 measure luminiferous vibrations. We shall only know 
 what the quantity of heat is when we know what heat 
 itself is ; when we have obtained a theory which satis- 
 factorily explains the manner in which the substance or 
 medium of heat produces it effects. When we see how 
 radiation and conduction, dilatation and liquefaction, are 
 all produced by mechanical changes of the same fluid, 
 we shall then see what the nature of that change is 
 which dilatation really measures, and what relation it 
 bears to any more proper standard of heat. 
 
 We may add, that while our thermotical theory is 
 
 * Annalesde Chimie, vn. 153. t Hist. Ind. Sci., B. x. c. ii. sect. 1. 
 
 } /A., c. iv. 
 
342 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 still so imperfect as it is, all attempts to divine the true 
 nature of the relation between light and heat are pre- 
 mature, and must be in the highest degree insecure 
 and visionary. Speculations in which, from the general 
 assumption of a caloriferous and luminiferous medium, 
 and from a few facts arbitrarily selected and loosely 
 analyzed, a general theory of light and heat is asserted, 
 are entirely foreign to the course of inductive science, 
 and cannot lead to any stable and substantial truth. 
 
 20. Other Instruments for measuring Heat. It 
 does not belong to our present purpose to speak of 
 instruments of which the object is to measure, not sen- 
 sible qualities, but some effect or modification of the 
 cause by which such qualities are produced : such, for 
 instance, are the Calorimeter, employed by Lavoisier 
 and Laplace, in order to compare the specific heat of 
 different substances; and the Actinometer, invented by 
 Sir John Herschel, in order to determine the effect of 
 the suris rays by means of the heat which they commu- 
 nicate in a given time ; which effect is, as may readily 
 be supposed, very different under different circumstances 
 of atmosphere and position. The laws of such effects 
 may be valuable contributions to our knowledge of heat, 
 but the interpretation of them must depend on a pre- 
 vious knowledge of the relations which temperature bears 
 to heat, according to the views just explained. 
 
 SECT. VI. Scales of other Qualities. 
 
 21. BEFORE quitting the subject of the measures of 
 sensible qualities, we may observe that there are several 
 other such qualities for which it would be necessary to 
 have scales and means of measuring, in order to make 
 any approach to science on such subjects. This is true, 
 for instance, of tastes and smells. Indeed some attempts 
 have been made towards a classification of the tastes of 
 
MEASURE OF SECONDARY QUALITIES. 343 
 
 sapid substances, but these have not yet assumed any 
 satisfactory or systematic character ; and I am not aware 
 that any instruments has been suggested for measuring 
 either the flavour or the odour of bodies which possess 
 such qualities. 
 
 22. Quality of Sounds. The same is true of that 
 kind of difference in sounds which is peculiarly termed 
 their quality ; that character by which, for instance, the 
 sound of a flute differs from that of a hautbois, when the 
 note is the same ; or a woman's voice from a boy's. 
 
 23. Articulate Sounds. There is also in sounds 
 another difference, of which the nature is still obscure, 
 but in reducing which to rule, and consequently to mea- 
 sure, some progress has nevertheless been made. I 
 speak of the differences of sound considered as articulate. 
 Classifications of the sounds of the usual alphabets have 
 been frequently proposed; for instance, that which ar- 
 ranges the consonants in the following groups : 
 
 Sharp. 
 
 Flat. Sharp Aspirate. 
 
 Flat Aspirate. 
 
 Nasal. 
 
 P 
 
 b 
 
 Ph (/) 
 
 bh () 
 
 m 
 
 k 
 
 g (hard) 
 
 kh 
 
 gh 
 
 g 
 
 t 
 
 d 
 
 th (sharp) 
 
 th (flat) 
 
 n 
 
 s 
 
 z 
 
 sh 
 
 zh 
 
 
 It is easily perceived that the relations of the sounds in 
 each of these horizontal lines are analogous ; and accord- 
 ingly the rules of derivation and modification of words 
 in several languages proceed upon such analogies. In 
 the same manner the vowels may be arranged in an order 
 depending on their sound. But to make such arrange- 
 ments fixed and indisputable, we ought to know the 
 mechanism by which such modifications are caused. In- 
 struments have been invented by which some of these 
 sounds can be imitated ; and if such instruments could 
 be made to produce the above series of articulate sounds, 
 by connected and regular processes, we should find, in 
 
344 PHILOSOPHY OF SECONDARY MECHANICAL SCIENCES. 
 
 the process, a measure of the sound produced. This 
 has been in a great degree effected for the Vowels by 
 Professor Willis's artificial mode of imitating them. For 
 he finds that if a musical reed be made to sound through 
 a cylindrical pipe, we obtain by gradually lengthening 
 the cylindrical pipe, the series of vowels I, E, A, o, u, 
 with intermediate sounds'". In this instrument, then, 
 the length of the pipe would determine the vowel, and 
 might be used numerically to express it. Such an in- 
 strument so employed would be a measure of vowel 
 quality, and might be called a Phthongometer. 
 
 Our business at present, however, is not with instru- 
 ments which might be devised for measuring sensible 
 qualities, but with those which have been so used, and 
 have thus been the basis of the sciences in which such 
 qualities are treated of; and this we have now done suf- 
 ficiently for our present purpose. 
 
 24. There is another Idea which, though hitherto 
 very vaguely entertained, has had considerable influence 
 in the formation, both of the sciences spoken of in the 
 present Book, and on others which will hereafter come 
 under our notice : namely, the Idea of Polarity. This 
 Idea will be the subject of the ensuing Book. And 
 although this Idea forms a part of the basis of various 
 other extensive portions of science, as Optics and Che- 
 mistry, it occupies so peculiarly conspicuous a place in 
 speculations belonging to what I have termed the Mecha- 
 nico-Chemical Sciences, (Magnetism arid Electricity,) 
 that I shall designate the discussion of the Idea of 
 Polarity as the Philosophy of those Sciences. 
 
 * Camb. Trans., Vol. m. p. 239. 
 
345 
 
 BOOK V. 
 
 OF THE PHILOSOPHY OF THE MECHANICO- 
 CHEMICAL SCIENCES. 
 
 CHAPTER I. 
 
 ATTEMPTS AT THE SCIENTIFIC APPLICATION 
 
 OF THE IDEA OF POLARITY. 
 
 / 
 
 1. IN some of the mechanical sciences, as Magnetism 
 and Optics, the phenomena are found to depend upon 
 position (the position of the magnet, or of the ray of 
 light,) in a peculiar alternate manner. This dependence, 
 as it was first apprehended, was represented by means 
 of certain conceptions of space and force, as for instance 
 by considering the two poles of a magnet. But in all 
 such modes of representing these alternations by the 
 conceptions borrowed from other ideas, a closer exami- 
 nation detected something superfluous and something 
 defective; and in proportion as the view which philo- 
 sophers took of this relation was gradually purified from 
 these incongruous elements, and was rendered more 
 general and abstract by the discovery of analogous pro- 
 perties in new cases, it was perceived that the relation 
 could not be adequately apprehended without consider- 
 ing it as involving a peculiar and independent Idea, 
 which we may designate by the term Polarity. 
 
 We shall trace some of the forms in which this Idea 
 has manifested itself in the history of science. In doing 
 so we shall not begin, as in other Books of this work 
 
346 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 we have done, by speaking of the notion as it is em- 
 ployed in common use : for the relation of polarity is of 
 so abstract and technical a nature, that it is not employed, 
 at least in any distinct and obvious manner, on any 
 ordinary or practical occasions. The idea belongs pecu- 
 liarly to the region of speculation : in persons of com- 
 mon habits of thought it is probably almost or quite 
 undeveloped ; and even most of those whose minds have 
 been long occupied by science, find a difficulty in appre- 
 hending it in its full generality and abstraction, and 
 stript of all irrelevant hypothesis. 
 
 2. Magnetism. The name and the notion of Poles 
 were first adopted in the case of a magnet. If we have 
 two magnets, their extremities attract and repel each 
 other alternatively. If the first end of the one attract 
 the first end of the other, it repels the second end, and 
 conversely. In order to express this rule conveniently, 
 the two ends of each magnet are called the north pole 
 and the south pole respectively, the denominations being 
 borrowed from the poles of the earth and heaven^. 
 "These poles," as Gilbert says'", " regulate the motions 
 of the celestial spheres and of the earth. In like manner 
 the magnet has its poles, a northern and a southern one ; 
 certain and determined points constituted by nature in 
 the stone, the primary terms of its motions and effects, 
 the limits and governors of many actions and virtues." 
 
 The nature of the opposition of properties of which 
 we speak may be stated thus. 
 
 The North pole of one magnet attracts the South 
 pole of another magnet. 
 
 The North pole of one magnet repels the North pole 
 of another magnet. 
 
 The South pole of one magnet repels the South pole 
 of another magnet. 
 
 * De Magn., Lib. i. c. iii. 
 
APPLICATION OF THE IDEA OF POLARITY. 347 
 
 The South pole of one magnet attracts the North 
 pole of another magnet. 
 
 It will be observed that the contrariety of position 
 which is indicated by putting the South pole for the 
 North pole in either magnet, is accompanied by the 
 opposition of mechanical effect which is expressed by 
 changing attraction into repulsion and repulsion into 
 attraction: and thus we have the general feature of 
 polarity : A contrast of properties corresponding to a 
 contrast of positions. 
 
 3. Electricity. When the phenomena of electricity 
 came to be studied, it appeared that they involved rela- 
 tions in some respects analogous to those of magnetism. 
 
 Two kinds of electricity were distinguished, the 
 positive and the negative ; and it appeared that two 
 bodies electrized positively or two electrized negatively, 
 repelled each other, like two north or two south magnetic 
 poles ; while a positively and a negatively electrized body 
 attracted each other, like the north and south poles of 
 two magnets. In conductors of an oblong form, the 
 electricity could easily be made to distribute itself so 
 that one end should be positively and one end negatively 
 electrized ; and then such conductors acted on each other 
 exactly as magnets would do. 
 
 But in conductors, however electrized, there is no 
 peculiar point which can permanently be considered as 
 the pole. The distribution of electricity in the conduc- 
 tor depends upon external circumstances : and thus, 
 although the phenomena offer the general character of 
 polarity alternative results corresponding to alternative 
 positions, they cannot be referred to poles. Some other 
 mode of representing the forces must be adopted than 
 that which makes them emanate from permanent points 
 as in a magnet. 
 
 The phenomena of attraction and repulsion in elec- 
 
348 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 trized bodies were conveniently represented by means of 
 the hypothesis of two electric fluids, a positive and a 
 negative one, which were supposed to be distributed in 
 the bodies. Of these fluids, it was supposed that each 
 repelled its own parts and attracted those of the opposite 
 fluid : and it was found that this hypothesis explained all 
 the obvious laws of electric action. Here then we have 
 the phenomena of polarization explained by a new kind 
 of machinery : two opposite fluids distributed in bodies, 
 and supplying them, so to speak, with their polar forces. 
 This hypothesis not only explains electrical attraction, 
 but also the electrical spark : when two bodies, of which 
 the neighbouring surfaces are charged with the two 
 opposite fluids, approach near to each other, the mutual 
 attraction of the fluids becomes more and more intense, 
 till at last the excess of fluid on the one body breaks 
 through the air and rushes to the other body, in a form 
 accompanied by light and noise. When this transfer has 
 taken place, the attraction ceases, the positive and the 
 negative fluid having neutralized each other. Their 
 effort was to unite ; and this union being effected, there 
 is no longer any force in action. Bodies in their natural 
 unexcited condition may be considered as occupied by a 
 combination of the two fluids : and hence we see how 
 the production of either kind of electricity is necessarily 
 accompanied with the production of an equivalent amount 
 of the opposite kind. 
 
 4. Voltaic Electricity. Such is the case in Franklinic 
 electricity, that which is excited by the common elec- 
 trical machine. In studying Voltaic electricity, we are 
 led to the conviction that the fluid which is in a condi- 
 tion of momentary equilibrium in electrized conductors, 
 exists in the state of current in the voltaic circuit. And 
 here we find polar relations of a new kind existing among 
 the forces. Two voltaic currents attract each other when 
 
APPLICATION OF THE IDEA OF POLARITY. 349 
 
 they are moving in the same, and repel each other when 
 they are moving in opposite, directions. 
 
 But we find, in addition to these, other polar rela- 
 tions of a more abstruse kind, and which the supposition 
 of two fluids does not so readily explain. For instance, 
 if such fluids existed, distinct from each other, it might 
 be expected that it would be possible to exhibit one 
 of them separate from the other. Yet in all the phe- 
 nomena of electromotive currents, we attempt in vain 
 to obtain one kind of electricity separately. "I have 
 not," says Mr. Faraday"", "been able to find a single 
 fact which could be adduced to prove the theory of 
 two electricities rather than one, in electric currents; 
 or, admitting the hypothesis of two electricities, have 
 I been able to perceive the slightest grounds that one 
 electricity can be more powerful than the other, or 
 that it can be present without the other, or that it 
 can be varied or in the slightest degree affected without 
 a corresponding variation in the other." "Thus," he 
 adds, " the polar character of the powers is rigorous and 
 complete." Thus, we too may remark, all the super- 
 fluous and precarious parts gradually drop off from the 
 hypothesis which we devise in order to represent polar 
 phenomena; and the abstract notion of polarity of equal 
 and opposite powers called into existence by a com- 
 mon condition remains unincumbered with extraneous 
 machinery. 
 
 5. Light. Another very important example of the 
 application of the idea of polarity is that supplied by the 
 discovery of the polarization of light. A ray of light 
 may, by various processes, be modified, so that it has dif- 
 ferent properties according to its different sides, although 
 this difference is not perceptible by any common effects. 
 If, for instance, a ray thus modified, pass perpendicularly 
 
 * Researches, 516. 
 
350 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 through a circular glass, and fall upon the eye, we may 
 turn the glass round and round its frame, and we shall 
 made no difference in the brightness of the spot which 
 we see. But if, instead of a glass, we look through a 
 longitudinal slice of tourmaline, the spot is alternately 
 dark and bright as we turn the crystal through successive 
 quadrants. Here we have a contrast of properties (dark 
 and bright) corresponding to a contrast of positions, (the 
 position of a line east and west being contrasted with 
 the position north and south,) which, as we have said, is 
 the general character of polarity. It was with a view of 
 expressing this character that the term polarization was 
 originally introduced. Malus was forced by his disco- 
 veries into the use of this expression. " We find," he 
 says, in 1811, "that light acquires properties which are 
 relative only to the sides of the ray, which are the same 
 for the north and south sides of the ray, (using the 
 points of the compass for description's sake only,) and 
 which are different when we go from the north and south 
 to the east or to the west sides of the ray. I shall give 
 the name of poles to these sides of the ray, and shall call 
 polarization the modification which gives to light these 
 properties relative to these poles. I have put off hitherto 
 the admission of this term into the description of the 
 physical phenomena with which we have to do : I did 
 not dare to introduce it into the Memoirs in which I 
 published my last observations : but the variety of forms 
 in which this new phenomenon appears, and the difficulty 
 of describing them, compel me to admit this new expres- 
 sion ; which signifies simply the modification which light 
 has undergone in acquiring new properties which are not 
 relative to the direction of the ray, but only to its sides 
 considered at right angles to each other, and in a plane 
 perpendicular to its direction." 
 
 The theory which represents light as an emission of 
 
APPLICATION OF THE IDEA OF POLARITY. 351 
 
 particles was in vogue at the time when Mains published 
 his discoveries ; and some of his followers in optical 
 research conceived that the phenomena which he thus 
 described rendered it necessary to ascribe poles and an 
 axis to each particle of light. On this hypothesis, light 
 would be polarized when the axes of all the particles 
 were in the same direction : and, making such a suppo- 
 sition, it may easily be conceived capable of transmission 
 through a crystal whose axis is parallel to that of the 
 luminous particles, and intransmissible when the axis of 
 the crystal is in a position transverse to that of the par- 
 ticles. 
 
 The hypothesis of particles possessing poles is a rude 
 and arbitrary assumption, in this as in other cases ; but 
 it serves to convey the general notion of polarity, which 
 is the essential feature of the phenomena. The term 
 "polarization of light" has sometimes been complained 
 of in modern times as hypothetical and obscure. But the 
 real cause of obscurity was, that the Idea of Polarity was, 
 till lately, very imperfectly developed in men's minds. 
 As we have seen, the general notion of polarity, oppo- 
 site properties in opposite directions, exactly describes 
 the character of the optical phenomena to which the 
 term is applied. 
 
 It is to be recollected that in optics we never speak 
 of the poles, but of the plane of polarization of a ray. The 
 word sides, which Newton and Malus have used, neither 
 of them appears to have been satisfied with ; Newton, in 
 employing it, had recourse to the strange Gallicism of 
 speaking of the coast of usual and of unusual refraction 
 of a crystal. 
 
 The modern theory of optics represents the plane of 
 polarization of light as depending, not on the position in 
 which the axes of the luminiferous particles lie, but on 
 the direction of those transverse vibrations in which light 
 
352 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 consists. This theory is, as we have stated in the His- 
 tory, recommended by an extraordinary series of suc- 
 cesses in accounting for the phenomena. And this 
 hypothesis of transverse vibrations shows us another 
 mechanical mode, (besides the hypothesis of particles 
 with axes,) by which we may represent the polarity of a 
 ray. But we may remark that the general notion of 
 polarity, as applied to light in such cases, would subsist, 
 even if the undulatory theory were rejected. The idea 
 is, as we have before said, independent of all hypothetical 
 machinery. 
 
 I need not here refer to the various ways in which 
 light may be polarized, as, for instance, by being reflected 
 from the surface of water or of glass at certain angles, by 
 being transmitted through crystals, and in other ways. 
 In all cases the modification produced, the polarization, 
 is identically the same property. Nor need I mention 
 the various kinds of phenomena which appear as contrasts 
 in the result ; for these are not merely light and dark, or 
 white and black, but red and green, and generally, a 
 colour and its complementary colour, exhibited in many 
 complex and varied configurations. These multiplied 
 modes in which polarized light presents itself add nothing 
 to the original conception of polarization : and I shall 
 therefore pass on to another subject. 
 
 6. Crystallization. Bodies which are perfectly crys- 
 tallized exhibit the most complete regularity and sym- 
 metry of form ; and this regularity not only appears in 
 their outward shape, but pervades their whole texture, 
 and manifests itself in their cleavage, their transparency, 
 and in the uniform and determinate optical properties 
 which exist in every part, even the smallest fragment of 
 the mass. If we conceive crystals as composed of par- 
 ticles, we must suppose these particles to be arranged in 
 the most regular manner ; for example, if we suppose 
 
APPLICATION OF THE IDEA OF POLARITY. 353 
 
 each particle to have an axis, we must suppose all these 
 axes to be parallel ; for the direction of the axis of the 
 particles is indicated by the physical and optical pro- 
 perties of the crystal, and therefore this direction must 
 be the same for every portion of the crystal. This 
 parallelism of the axes of the particles may be con- 
 ceived to result from the circumstance of each particle 
 having poles, the opposite poles attracting each other. 
 In virtue of forces acting as this hypothesis assumes, a 
 collection of small magnetic particles would arrange 
 themselves in parallel positions ; and such a collection of 
 magnetic particles offers a sort of image of a crystal. 
 Thus we are led to conceive the particles of crystals as 
 polarized, and as determined in their crystalline positions 
 by polar forces. This mode of apprehending the consti- 
 tution of crystals has been adopted by some of our most" 
 eminent philosophers. Thus Berzelius says *, " It is de- 
 monstrated, that the regular forms of bodies presuppose 
 an effort of their atoms to touch each other by preference 
 in certain points ; that is, they are founded upon a Pola- 
 rity ;" he adds, " a polarity which can be no other than 
 an electric or magnetic polarity."' In this latter clause 
 we have the identity of different kinds of polarity 
 asserted ; a principle which we shall speak of in the 
 next chapter. But we may remark, that even without 
 dwelling upon this connexion, any notion which we can 
 form of the structure of crystals necessarily involves the 
 idea of polarity. Whether this polarity necessarily re- 
 quires us to believe crystals to be composed of atoms 
 which exert an effort to touch each other in certain points 
 by preference, is another question. And, in agreement 
 with what has been said respecting other kinds of polarity, 
 we shall probably find, on a more profound examination 
 of the subject, that while the idea of polarity is essential, 
 
 * Essay on the Theory of Chemical Proper lies, 1820, p. 113. 
 VOL. I. W. P. A A 
 
354 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 the machinery by which it is thus expressed is precarious 
 and superfluous. 
 
 7. Chemical Affinity. We shall have, in the next 
 Book, to speak of Chemical Affinity at some length ; but 
 since the ultimate views to which philosophers have been 
 led, induce them to consider the forces of affinity as 
 polar forces, we must enumerate these among the exam- 
 ples of polarity. In chemical processes, opposites tend 
 to unite, and to neutralize each other by their union. 
 Thus an acid or an alkali combine with vehemence, and 
 form a compound, a neutral salt, which is neither acid 
 nor alkaline. 
 
 This conception of contrariety and mutual neutraliza- 
 tion, involves the idea of polarity. In the conception, as 
 entertained by the earlier chemists, the idea enters very 
 obscurely : but in the attempts which have more recently 
 been made to connect this relation (of acid and base,) with 
 other relations, the chemical elements have been conceived 
 as composed of particles which possess poles ; like poles 
 repelling, and unlike attracting each other, as they do in 
 magnetic and electric phenomena. This is, however, a 
 rude and arbitrary way of expressing polarity, and, as may 
 be easily shown, involves many difficulties which do not 
 belong to the idea itself. Mr. Faraday, who has been 
 led by his researches to a conviction of the polar nature 
 of the forces of chemical affinity, has expressed their 
 character in a more general manner, and without any of 
 the machinery of particles indued with poles. Accord- 
 ing to his view, chemical synthesis and analysis must 
 always be conceived as taking place in virtue of equal 
 and opposite forces, by which the particles are united or 
 separated. These forces, by the very circumstance of 
 their being polar, may be transferred from point to point. 
 For if we conceive a string of particles, and if the positive 
 force of the first particle be liberated and brought into 
 
APPLICATION OF THE IDEA OF POLARITY. 355 
 
 action, its negative force also must be set free : this 
 negative force neutralizes the positive force of the next 
 particle, and therefore the negative force of this particle 
 (before employed in neutralizing its positive force,) is set 
 free : this is in the same way transferred to the next 
 particle, and so on. And thus we have a positive force 
 active at one extremity of a line of particles, correspond- 
 ing to a negative force at the other extremity, all the 
 intermediate particles reciprocally neutralizing each 
 other's action. This conception of the transfer of chemi- 
 cal action was indeed at an earlier period introduced by 
 Grotthus"*, and confirmed by Davy. But in Mr. Fara- 
 day's hands we see it divested of all that is superfluous, 
 and spoken of, not as a line of particles, but as " an axis 
 of power, having [at every point,] contrary forces, ex- 
 actly equal, in opposite directions." 
 
 8. General Remarks. Thus, as we see, the notion 
 of polarity is applicable to many large classes of phe- 
 nomena. Yet the idea in a distinct and general form is 
 only of late growth among philosophers. It has gra- 
 dually been abstracted and refined from many extraneous 
 hypotheses which were at first, supposed to be essential 
 to it. We have noticed some of these hypotheses ; as 
 the poles of a body; the poles of the particles of a fluid ; 
 two opposite fluids ; a single fluid in excess and defect ; 
 transverse vibrations. To these others might be added. 
 Thus Dr. Proutf assumes that the polarity of molecules 
 results from their rotation on their axes, the opposite 
 motions of contiguous molecules being the cause of 
 opposite (positive and negative) polarities. 
 
 But none of these hypotheses can be proved by the 
 fact of polarity alone ; and they have been in succession 
 rejected when they had been assumed on that ground. 
 
 * DUMAS, Legons sur la Philosophic Chimique^ p. 401. 
 t Bridgewuter Treatise, p. 559. 
 
 AA2 
 
356 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 Thus Davy, in 1820, speaking of chemical forces says*, 
 " In assuming the idea of two ethereal, subtile, elastic 
 fluids, attractive of the particles of each other, and 
 repulsive as to their own particles, capable of combining 
 in different proportions with bodies, and according to 
 their proportions giving them their specific qualities and 
 rendering them equivalent masses, it would be natural 
 to refer the action of the poles to the repulsions of the 
 substances combined with the excess of one fluid, and 
 the attractions of those united to the excess of the other 
 fluid ; and a history of the phenomena, not unsatisfactory 
 to the reason, might in this way be made out. But as 
 it is possible likewise to take an entirely different view 
 of the subject, on the idea of the dependence of the 
 results upon the primary attractive powers of the parts 
 of the combination on a single subtile fluid, I shall not 
 enter into any discussion on this obscure part of the 
 theory." Which of these theories will best represent the 
 case, will depend upon the consideration of other facts, 
 in combination with the polar phenomena, as we see in 
 the history of optical theory. In like manner Mr. 
 Faraday proved by experiment f the errour of all theories 
 which ascribe electro-chemical decomposition to the 
 attraction of the poles of the voltaic battery. 
 
 In order that they may distinctly image to them- 
 selves the idea of polarity, men clothe it in some of 
 the forms of machinery above spoken of; yet every new 
 attempt shows them the unnecessary difficulties in which 
 they thus involve themselves. But on the other hand 
 it is difficult to apprehend this idea divested of all 
 machinery; and to entertain it in such a form that it 
 shall apply at the same time to magnetism and elec- 
 tricity, galvanism and chemistry, crystalline structure 
 and light. The Idea of Polarity becomes most pure and 
 
 Phil. Tr., 1826, p. 415. t Researches, p. 495, &c. 
 
APPLICATION OF TI1E IDEA OF POLARITY. 357 
 
 genuine, when we entirely reject the conception of Poles, 
 as Faraday has taught us to do in considering electro- 
 chemical decomposition ; but it is only by degrees and 
 by effort that we can reach this point of abstraction and 
 generality. 
 
 9. There is one other remark which we may here 
 make. It was a maxim commonly received in the ancient 
 schools of philosophy, that " like attracts like :" but as 
 we have seen, the universal maxim of polar phenomena 
 is, that like repels like, and attracts unlike. The north 
 pole attracts the south pole, the positive fluid attracts 
 the negative fluid ; opposite elements rush together ; 
 opposite motions reduce each other to rest. The per- 
 manent and stable course of things is that which results 
 from the balance and neutralization of contrary ten- 
 dencies. Nature is constantly labouring after repose by 
 the effect of such tendencies ; and so far as polar forces 
 enter into her economy, she seeks harmony by means of 
 discord, and unity by opposition. 
 
 Although the Idea of Polarity is as yet somewhat 
 vague and obscure, even in the minds of the cultivators 
 of physical science, it has nevertheless given birth to 
 some general principles which have been accepted as 
 evident, and have had great influence on the progress 
 of science. These we shall now consider. 
 
 CHAPTER II. 
 OF THE CONNEXION OF POLARITIES. 
 
 1. IT has appeared in the preceding chapter that in 
 cases in which the phenomena suggest to us the idea of 
 polarity, we are also led to assume some material ma- 
 chinery as the mode in which the polar forces are exerted. 
 
358 PHILOSOPHY OF THE MECHANICQ-CHEMICAL SCIENCES. 
 
 We assume, for instance, globular particles which possess 
 poles, or the vibrations of a fluid, or two fluids attract- 
 ing each other ; in every case, in short, some hypothesis 
 by which the existence and operation of the polarity is 
 embodied in geometrical and mechanical properties of a 
 medium ; nor is it possible for us to avoid proceeding 
 upon the conviction that some such hypothesis must be 
 true ; although the nature of the connexion between 
 the mechanism and the phenomena must still be inde- 
 finite and arbitrary. 
 
 But since each class of polar phenomena is thus 
 referred to an ulterior cause, of which we know no more 
 than that it has a polar character, it follows that different 
 polarities may result from the same cause manifesting 
 its polar character under different aspects. Taking, for 
 example, the hypothesis of globular particles, if elec- 
 tricity result from an action dependent upon the poles 
 of each globule, magnetism may depend upon an action 
 in the equator of each globule; or taking the supposition 
 of transverse vibrations, if polarized light result directly 
 from such vibrations, crystallization may have reference 
 to the axes of the elasticity of the medium by which the 
 vibrations are rendered transverse, so far as the polar 
 character only of the phenomena is to be accounted for. 
 I say this may be so, in so far only as the polar cha- 
 racter of the phenomena is concerned ; for whether the 
 relation of electricity to magnetism, or of crystalline 
 forces to light, can really be explained by such hypo- 
 theses, remains to be determined by the facts themselves. 
 But since the first necessary feature of the hypothesis 
 is, that it shall give polarity, and since an hypothesis 
 which does this, may, by its mathematical relations, give 
 polarities of different kinds and in different directions, 
 any two co-existent kinds of polarity may result from 
 the same cause, manifesting itself in various manners. 
 
OF THE CONNEXION OF POLARITIES. 359 
 
 The conclusion to which we are led by these general 
 considerations is, that two co-existing classes of polar 
 phenomena may be effects of the same cause. But those 
 who have studied such phenomena more deeply and 
 attentively have, in most or in all cases, arrived at the 
 conviction that the various kinds of polarity in such 
 cases must be connected and fundamentally identical. 
 As this conviction has exercised a great influence, both 
 upon the discoveries of new facts and upon the theore- 
 tical speculations of modern philosophers, and has been 
 put forward by some writers as a universal principle of 
 science, I will consider some of the cases in which it has 
 been thus applied. 
 
 2. Connexion of Magnetic and Electric Polarity. 
 The polar phenomena of electricity and magnetism are 
 clearly analogous in their laws : and obvious facts showed 
 at an early period that there was some connexion be- 
 tween the two agencies. Attempts were made to esta- 
 blish an evident and definite relation between the two 
 kinds of force, which attempts proceeded upon the prin- 
 ciple now under consideration; namely, that in such 
 cases, the two kinds of polarity must be connected. Pro- 
 fessor (Ersted, of Copenhagen, was one of those who 
 made many trials founded upon this conviction : yet all 
 these were long unsuccessful. At length, in 1820, he 
 discovered that a galvanic current, passing at right angles 
 near to a magnetic needle, exercises upon it a powerful 
 deflecting force. The connexion once detected between 
 magnetism and galvanism was soon recognized as con- 
 stant and universal. It was represented in different 
 hypothetical modes by different persons ; some consider- 
 ing the galvanic current as the primitive axis, and the 
 magnet as constituted of galvanic currents passing round 
 it at right angles to the magnetic axis; while others 
 conceived the magnetic axis as the primitive one, and 
 
360 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 the electric current as implying a magnetic current 
 round the wire. So far as many of the general relations 
 of these two kinds of force were concerned, either mode 
 of representation served to express them ; and thus the 
 assumption that the two polarities, the magnetic and 
 the electric, were fundamentally identical, was verified, 
 so far as the phenomena of magnetic attraction, and the 
 like, were concerned. 
 
 I need not here mention how this was further con- 
 firmed by the experiments in which, by means of the 
 forces thus brought into view, a galvanic wire was made 
 to revolve round a magnet, and a magnet round a gal- 
 vanic wire ; in which artificial magnets were constructed 
 of coils of galvanic wire ; and finally, in which the gal- 
 vanic spark was obtained from the magnet. The identity 
 which sagacious speculators had divined even before it 
 was discovered, and which they had seen to be universal 
 as soon as it was brought to light, was completely mani- 
 fested in every imaginable form. 
 
 The relation of the electric and magnetic polarities 
 was found to be, that they were transverse to each 
 other, and this relation exhibited under various condi- 
 tions of form and position of the apparatus, gave rise to 
 very curious and unexpected perplexities. The degree 
 of complication which this relation may occasion, may be 
 judged of from the number of constructions and modes 
 of conception offered by (Ersted, Wollaston, Faraday, 
 and others, for the purpose of framing a technical memory 
 of the results. The magnetic polarity gives us the north 
 and south poles of the needle; the electric polarity 
 makes the current positive and negative; and these pairs 
 of opposites are connected by relations of situation, as 
 above and below, right and left ; and give rise to the 
 resulting motion of the needle one way or the other. 
 
 3. Ampere, by framing his hypotheses of the action 
 
OF THE CONNEXION OF POLARITIES. 361 
 
 of voltaic currents and the constitution of magnets, 
 reduced all these technical rules to rigorous deductions 
 from one general principle. And thus the vague and 
 obscure persuasion that there must be some connexion 
 between electricity and magnetism, so long an idle and 
 barren conjecture, was unfolded into a complete theory, 
 according to which magnetic and electromotive actions 
 are only two different manifestations of the same forces; 
 and all the above-mentioned complex relations of pola- 
 rities are reduced to one single polarity, that of the 
 electro-dynamic current. 
 
 4. As the idea of polarity was thus firmly established 
 and clearly developed, it became an instrument of rea- 
 soning. Thus it led Ampere to maintain that the original 
 or elementary forces in electro-dynamic action could not 
 be as M. Biot thought they were, a statical couple, but 
 must be directly opposite to each other. The same idea 
 enabled Mr. Faraday to carry on with confidence such 
 reasonings as the following""" : " No other known power 
 has like direction with that exerted between an electric 
 current and a magnetic pole ; it is tangential, while all 
 other forces acting at a distance are direct. Hence if a 
 magnetic pole on one side of a revolving plate follow 
 its course by reason of its obedience to the tangential 
 force exerted upon it by the very current of electricity 
 which it has itself caused ; a similar pole on the other 
 side of the plate should immediately set it free from this 
 force ; for the currents which have to be formed by the 
 two poles are in contrary directions." And in Article 
 1114 of his Researches, the same eminent philosopher 
 infers that if electricity and magnetism are considered 
 as the results of a peculiar agent or condition, exerted 
 in determinate directions perpendicular to each other, 
 one must be by some means convertible into the other; 
 
 * Researches, 244. 
 
362 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 and this he was afterwards able to prove to be the case 
 in fact. 
 
 Thus the principle that the co-existent polarities of 
 magnetism and electricity are connected and fundamen- 
 tally identical, is not only true, but is far from being 
 either vague or barren. It has been a fertile source 
 both of theories which have, at present, a very great pro- 
 bability, and of the discovery of new and striking facts. 
 We proceed to consider other similar cases. 
 
 5. Connexion of Electrical and Chemical Polari- 
 ties. The doctrine that the chemical forces by which 
 the elements of bodies are held together or separated, 
 are identical with the polar forces of electricity, is a 
 great discovery of modern times ; so great and so recent, 
 indeed, that probably men of science in general have 
 hardly yet obtained a clear view and firm hold of this 
 truth. This doctrine is now, however, entirely esta- 
 blished in the minds of the most profound and philoso- 
 phical chemists of our time. The complete developement 
 and confirmation of this as of other great truths, was 
 preceded by more vague and confused opinions gradu- 
 ally tending to this point; arid the progress of thought 
 and of research was impelled and guided, in this as in 
 similar cases, by the persuasion that these co-existent 
 polarities could not fail to be closely connected with 
 each other. While the ultimate and exact theory to 
 which previous incomplete and transitory theories tended 
 is still so new and so unfamiliar, it must needs be a 
 matter of difficulty and responsibility for a common 
 reader to describe the steps by which truth has advanced 
 from point to point. I shall, therefore, in doing this, 
 guide myself mainly by the historical sketches of the 
 progress of this great theory, which, fortunately for us, 
 have been given us by the two philosophers who have 
 
OF THE CONNEXION OF POLARITIES. 363 
 
 played by far the most important parts in the discovery, 
 Davy and Faraday. 
 
 It will be observed that we are concerned here with 
 the progress of theory, and not of experiment, except so 
 far as it is confirmatory of theory. In Davy's Memoir'"* 
 of 1826, on the Relations of Electrical and Chemical 
 Changes, he gives the historical details to which I have 
 alluded. Already in 1802 he had conjectured that all 
 chemical decompositions might be polar. In 1806 he 
 attempted to confirm this conjecture, and succeeded, to 
 his own satisfaction, in establishing f that the combina- 
 tions and decompositions by electricity were referable 
 to the law of electrical attractions and repulsions ; and 
 advanced the hypothesis (as he calls it,) that chemical 
 and electrical attractions were produced by the same 
 cause, acting in one case on particles, in the other on 
 masses. This hypothesis was most strikingly confirmed 
 by the author's being able to use electrical agency as a 
 more powerful means of chemical decomposition than 
 any which had yet been applied. " Believing," he adds, 
 "that our philosophical systems are exceedingly im- 
 perfect, I never attached much importance to this hypo- 
 thesis; but having formed it after a copious induction 
 of facts, and having gained by the application of it a 
 number of practical results, and considering myself as 
 much the author of it as I was of the decomposition of 
 the alkalies, and having developed it in an elementary 
 work as far as the present state of chemistry seemed to 
 allow, I have never," he says "criticized or examined 
 the manner in which different authors have adopted or 
 explained it, contented, if in the hands of others, it 
 assisted the arrangements of chemistry or mineralogy, 
 or became an instrument of discovery." When the doc- 
 trine had found an extensive acceptance among chemists, 
 * Phil. Trans., 1826, p, 383. * Ibid., p. 389. 
 
364 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 attempts were made to show that it had been asserted 
 by earlier writers: and though Davy justly denies all 
 value to these pretended anticipations, they serve to 
 show, however dimly, the working of that conviction of 
 the connexion of co-existent properties which all along 
 presided in men's minds during this course of investi- 
 gation. " Ritter and Winterl have been quoted," Davy 
 says*, "among other persons, as having imagined or 
 anticipated the relation between electrical powers and 
 chemical affinities before the discovery of the pile of 
 Volta. But whoever will read with attention Hitter's 
 4 Evidence that Galvanic action exists in organized 
 nature,' and Winter's Prolusiones ad Chemiam sceculi 
 decimi noni, will find nothing to justify this opinion." 
 He then refers to the Queries of Newton at the end of 
 his Optics. " These," he says, " contain more grand and 
 speculative views that might be brought to bear upon 
 this question than any found in the works of modern 
 electricians ; but it is very unjust to the experimentalists 
 who by the laborious application of new instruments, 
 have discovered novel facts and analogies, to refer them 
 to any such suppositions as that all attractions, chemical, 
 electrical, magnetical, and gravitative, may depend upon 
 the same cause." It is perfectly true, that such vague 
 opinions, though arising from that tendency to generalize 
 which is the essence of science, are of no value except 
 so far as they are both rendered intelligible, and con- 
 firmed by experimental research. 
 
 The phenomena of chemical decomposition by means 
 of the voltaic pile, however, led other persons to views 
 very similar to those of Davy. Thus Grotthus in 1805f 
 published an hypothesis of the same kind. " The pile of 
 Volta," he says, " is an electrical magnet, of which each 
 element, that is, each pair of plates, has a positive and a 
 
 * Phil. Trans., 1826, p. 384. t Ann. Ckim., Lxviii. 54. 
 
OF THE CONNEXION OF POLARITIES. 365 
 
 negative pole. The consideration of this polarity sug- 
 gested to me the idea that a similar polarity may come 
 into play between the elementary particles of water 
 when acted upon by the same electrical agent ; and I 
 avow that this thought was for me a flash of light." 
 
 6. The thought, however, though thus brought into 
 being, was very far from being as yet freed from vague- 
 ness, superfluities, and errours. I have elsewhere noticed* 
 Faraday's remark on Davy's celebrated Memoir of 1806; 
 that " the mode of action by which the effects take place 
 is stated very generally, so generally, indeed, that pro- 
 bably a dozen precise schemes of electro-chemical action 
 might be drawn up, differing essentially from each other, 
 yet all agreeing with the statement there given." When 
 Davy and others proceeded to give a little more defi- 
 niteness and precision to the statement of their views, 
 they soon introduced into the theory features which it 
 was afterwards found necessary to abandon. Thusf 
 both Davy, Grotthus, Riffault, and Chompre, ascribed 
 electrical decomposition to the action of the poles, and 
 some of them even pretended to assign the proportion 
 in which the force of the pole diminishes as the distance 
 from it increases. Faraday, as I have already stated, 
 showed that the polarity must be considered as residing 
 not only in what had till then been called the poles, 
 but at every point of the circuit. He ascribed J electro- 
 chemical decomposition to internal forces, residing in 
 the particles of the matter under decomposition, not to 
 external forces, exerted by the poles. Hence he shortly 
 afterwards J proposed to reject the word poles altogether, 
 and to employ instead, the term electrode, meaning the 
 
 * Hist. Ind. Sci., B. xiv. c. ix. sect. 1. 
 
 t See Faraday's Historical Sketch, Researches, 481 492. 
 
 J Art 524. 
 
 In 1834. Eleventh Series of Researches. Art. 662. 
 
366 PHILOSOPHY 01' THE MECHA N l( O-CII KM ICAI, SCIIv\< 
 
 doors or passages (of whatever surface formed,) by which 
 the decomposed elements pass out. What have been 
 called the positive and negative poles he further termed 
 the anode and cathode ; and he introduced some other 
 changes in nomenclature connected with these. He 
 then, as I have related in the History*, invented the 
 Volta-electrometer, which enabled him to measure the 
 quantity of voltaic action, and this he found to be iden- 
 tical with the quantity of chemical affinity; and he wa^ 
 thus led to the clearest view of the truth towards which 
 he and his predecessors had so long been travelling, 
 that electrical and chemical forces are identical f. 
 
 7. It will, perhaps, be said that this beautiful train 
 of discovery was entirely due to experiment, and not to 
 any a priori conviction that co-existent polarities must 
 be connected. I trust I have sufficiently stated that 
 such an a priori principle could not be proved, nor even 
 understood, without a most laborious and enlightened 
 use of experiment ; but yet I think that the doctrine 
 when once fully unfolded, exhibited clearly, and estab- 
 lished as true, takes possession of the mind with a more 
 entire conviction of its certainty and universality, in 
 virtue of the principle we are now considering. When 
 the theory has assumed so simple a form, it appears to 
 derive immense probability (to say the least) from its 
 simplicity. Like the laws of motion, when stated in its 
 most general form, it appears to carry with it its own 
 evidence. And thus this great theory borrows some- 
 thing of its character from the Ideas which it involves. 
 as well as from the Experiments by which it was esta- 
 blished. 
 
 8. We may find in many of Mr. Faraday's subsequent 
 reasonings, clear evidence that this idea of the connex- 
 ion of polarities, as now developed, is not limited in its 
 
 * ///'A/. /,/,/. Sri., II. xiv. r. ix. sect 2. t Arts. IHfi, 
 
01 Till (ONM.XIOX OF POLARITIES. 367 
 
 application to facts already known experimentally, but, 
 like other ideas, determines the philosopher's researches 
 into the unknown, and gives us tlieform of knowledge 
 men before we possess the matter. Thus, he says, in 
 his Thirteenth Series*, "I have long sought, and still 
 seek, for an effect or condition which shall be to statical 
 electricity what magnetic force is to current electricity ; 
 for as the lines of discharge are associated with a cer- 
 tain transverse effect, so it appeared to me impossible 
 but that the lines of tension or of inductive action, 
 which of necessity precede the discharge, should also 
 have their correspondent transverse condition or effect." 
 Other similar passages mi^ht be found. 
 
 I will now consider another case to which we may 
 apply the principle of connected polarities. 
 
 9. Connexion qf Chemical and Crystalline Polari- 
 ties. The close connexion between the chemical affinity 
 and the crystalline attraction of elements eannot be 
 overlooked. Bodies never crystallize but when their 
 elements combine chemically; and solid bodies which 
 combine, when they do it most completely and exactly, 
 also (Tvstalli/o. The forces which hold together the elo- 
 
 V ~ 
 
 ments of a crystal of alum are the same forces which 
 make it a crystal. There is no distinguishing between 
 
 the \\\ o sets of forces. 
 
 Both chemical and crystalline forces are polar, as we 
 stated in the last chapter; but the polarity in the two 
 cases is of a different kind. The polarity of chemical 
 forces is then put in the most distinct form, when it is 
 identified with electrical polarity; the polarity of the 
 particles of crystals has reference to their geometrical 
 form. And it is clear that these two kinds of polarity 
 must be connected. Accordingly, Ber/olius expressly 
 asserts f the necessary identity of those two polarities. 
 
 * Art. K>f>8. f Ksxati on C/icniic.il /'/<>/>., 1 I.'V 
 
:3()8 1'IIII.OSOl'IIY OF' 1 TIIK M KCII A MC<>-< :il KM ICAL SCIKNCKS. 
 
 "The regular forms of bodies suppose a polarity which 
 can be no other than an electric or magnetic polarity." 
 This being so seemingly inevitable, we might expect to 
 find the electric forces manifesting some relation to the 
 definite directions of crystalline forms. Mr. Faraday 
 tried, but in vain, to detect some such relation. lie 
 attempted to ascertain* whether a cube of rock crystal 
 transmitted the electrical force of tension with different 
 intensity along and across the axis of the crystal. In 
 the first specimen there seemed to be some difference ; 
 but in other experiments, made both with rock crystal 
 arid with calc spar, this difference disappeared. Al- 
 though therefore we may venture to assert that there 
 must be some very close connexion between electrical 
 and crystalline forces, we are, as yet, quite ignorant 
 what the nature of the connexion is, and in what kind 
 of phenomena it will manifest itself. 
 
 10. Connexion of Crystalline and Optical Polarities. 
 Crystals present to us optical phenomena which have 
 a manifestly polar character. The double refraction, 
 both of uniaxal and of biaxal crystals, is always accom- 
 panied with opposite polari/ation of the two rays; and 
 in this and in other ways light is polari/ed in directions 
 dependent upon the axes of the crystalline form, that is, 
 on the directions of the polarities of the crystalline par- 
 ticles. The identity of these two kinds of polarity (cry- 
 stalline and optical) is too obvious to need insisting on ; 
 and it is not necessary for us here to decide by what 
 hypothesis this identity may most properly be repre- 
 sented. We may hereafter perhaps find ourselves jus- 
 tified in considering the crystalline forces as determining 
 the elasticity of the luminiferous ether to be different 
 in different directions within the crystal, and thus as 
 determining the refraction and polarization of the light 
 
 .v. Art. 
 
OF THE CONNEXION OF POLARITIES. 369 
 
 which the crystal transmits. But at present we merely 
 note this case as an additional example of the manifest 
 connexion and fundamental identity of two co-existent 
 polarities. 
 
 11. Connexion of Polarities in general. Thus we 
 find that the connexion of different kinds of polarities, 
 magnetic, electric, chemical, crystalline, and optical, is 
 certain as a truth of experimental science. We have 
 attempted to show further that in the minds of several 
 of the most eminent discoverers and philosophers, such 
 a conviction is something more than a mere empirical 
 result: it is a principle which has regulated their re- 
 searches while it was still but obscurely seen and imper- 
 fectly unfolded, and has given to their theories a charac- 
 ter of generality and self-evidence which experience 
 alone cannot bestow. 
 
 It will, perhaps, be said that these doctrines, that 
 scientific researches may usefiilly be directed by prin- 
 ciples in themselves vague and obscure; that theories 
 may have an evidence superior to and anterior to expe- 
 rience : are doctrines in the highest degree dangerous, 
 and utterly at variance with the soundest maxims of 
 modern times respecting the cultivation of science. 
 
 To the justice and wisdom of this caution I entirely 
 agree : and although I have shown that this principle of 
 the connexion of polarities, rightly interpreted and esta- 
 blished in each case by experiment, involves profound 
 and comprehensive truths ; I think it no less important 
 to remark that, at least in the present stage of our 
 knowledge, we can make no use of this principle with- 
 out taking care, at every step, to determine by clear and 
 decisive experiments, its proper meaning and applica- 
 tion. All endeavours to proceed otherwise have led, 
 and must lead, to ignorance and confusion. Attempts 
 to deduce from our bare idea of polarity, and our fun- 
 
 VOL I. W. P. B B 
 
370 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 damental convictions respecting the connexion of polari- 
 ties, theories concerning the forces which really exist in 
 nature, can hardly have any other result than to bewilder 
 men's minds, and to misdirect their efforts. 
 
 So far, indeed, as this persuasion of a connexion 
 among apparently different kinds of agencies, impels 
 men, engaged in the pursuit of knowledge, to collect 
 observations, to multiply, repeat, and vary experiments, 
 and to contemplate the result of these in all aspects 
 and relations, it may be an occasion of the most impor- 
 tant discoveries. Accordingly we find that the great 
 laws of phenomena which govern the motions of the 
 planets about the sun, were first discovered by Kepler, 
 in consequence of his scrutinizing the recorded observa- 
 tions with an intense conviction of the existence of geo- 
 metrical and arithmetical harmonies in the solar system. 
 Perhaps we may consider the discovery of the connexion 
 of magnetism and electricity by Professor (Ersted in 
 1820, as an example somewhat of the same kind; for 
 he also was a believer in certain comprehensive but un- 
 defined relations among the properties of bodies ; and 
 in consequence of such views entertained great admira- 
 tion for the Prologue to the Chemistry of the Nineteenth 
 Century, of Winterl, already mentioned. M. (Ersted, in 
 1803, published a summary of this work ; and in so do- 
 ing, praised the views of Winterl as far more profound 
 and comprehensive than those of Lavoisier. Soon after- 
 wards a Review of this publication appeared in France *, 
 in which it was spoken of as a work only fit for the 
 dark ages, and as the indication of a sect which had 
 for some time " ravaged Germany," and inundated that 
 country with extravagant and unintelligible mysticism. 
 It was, therefore, a kind of triumph to M. (Ersted to 
 be, after some years' labour, the author of one of the 
 
 * Ann. Chim., Tom. L. (1804), p. 191. 
 
OF THE CONNEXION OF POLARITIES. :J71 
 
 most remarkable and fertile physical discoveries of his 
 time. 
 
 12. It was not indeed without some reason that cer- 
 tain of the German philosophers were accused of dealing 
 in doctrines vast and profound in their aspect, but, in 
 reality, indefinite, ambiguous, and inapplicable. And 
 the most prominent of such doctrines had reference to 
 the principle now under our consideration ; they repre- 
 sented the properties of bodies as consisting in certain 
 polarities, and professed to deduce, from the very nature 
 of things, with little or no reference to experiment, the 
 existence and connexion of these polarities. Thus Schel- 
 ling, in his Ideas towards a Philosophy of Nature, pub- 
 lished in 1803, says*, "Magnetism is the universal act 
 of investing Multiplicity with Unity ; but the universal 
 form of the reduction of Multiplicity to Unity is the 
 Line, pure Longitudinal Extension : hence Magnetism 
 is determination of pure Longitudinal Extension ; and 
 as this manifests itself by absolute Cohesion, Magnetism 
 is the determination of absolute Cohesion." And as 
 Magnetism was, by such reasoning, conceived to be 
 proved as a universal property of matter, Schelling as- 
 serted it to be a confirmation of his views when it was 
 discovered that other bodies besides iron are magnetic. 
 In like manner he used such expressions as the follow- 
 ing f: "The threefold character of the Universal, the 
 Particular, and the Indifference of the two, as ex- 
 pressed in their Identity, is Magnetism, as expressed 
 in their Difference, is Electricity, and as expressed in 
 the Totality, is Chemical Process. Thus these forms 
 are only one form ; and the Chemical Process is a mere 
 transfer of the three Points of Magnetism into the Tri- 
 angle of Chemistry." 
 
 It was very natural that the chemists should refuse 
 * P. 223. t P. 486. 
 
 BB2 
 
372 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 to acknowledge, in this fanciful and vague language, 
 (delivered, however, it is to be recollected, in 1803,) an 
 anticipation of Davy's doctrine of the identity of electri- 
 cal and chemical forces, or of (Ersted's electro-magnetic 
 agency. Yet it was perhaps no less natural that the 
 author of such assertions should look upon every great 
 step in the electro-chemical theory as an illustration 
 of his own doctrines. Accordingly we find Schelling 
 welcoming, with a due sense of their importance, the 
 discoveries of Faraday. When he heard of the experi- 
 ment in which electricity was produced from common 
 magnetism, he fastened with enthusiasm upon the dis- 
 covery, even before he knew any of its details, and pro- 
 claimed it at a public meeting of a scientific body* as 
 one of the most important advances of modern science. 
 We have (he thus reasoned) three effects of polar forces ; 
 electro-chemical Decomposition, electrical Action, 
 Magnetism. Volta and Davy had confirmed experimen- 
 tally the identity of the two former agencies : (Ersted 
 showed that a closed voltaic circuit acquired magnetic 
 properties : but in order to exhibit the identity of elec- 
 tric and magnetic action it was requisite that electric 
 forces should be extricated from magnetic. This great 
 step Faraday, he remarked, had made, in producing the 
 electric spark by means of magnets. 
 
 13. Although conjectures and assertions of the kind 
 thus put forth by Schelling involve a persuasion of the 
 pervading influence and connexion of polarities, which 
 persuasion has already been confirmed in many instances, 
 they involve this principle in a manner so vague and 
 ambiguous that it can rarely, in such a form, be of 
 any use or value. Such views of polarity can never 
 teach us in what cases we are and in what we are not 
 to expect to find polar relations ; and indeed tend rather 
 
 * Ueber Faraday's Neueste Entdeckung. Munchen. 18.32. 
 
OF THE CONNEXION OF POLARITIES. 373 
 
 to diffuse error and confusion, than to promote know- 
 ledge. Accordingly we cannot be surprized to find such 
 doctrines put forward by their authors as an evidence of 
 the small value and small necessity of experimental 
 science. This is done by the celebrated metaphysician 
 Hegel, in his Encydopasdid*. "Since," says he, "the 
 plane of incidence and of reflection in simple reflection 
 is the same plane, when a second reflector is introduced 
 which further distributes the illumination reflected from 
 the first, the position of the first plane with respect to 
 the second plane, containing the direction of the first 
 reflection and of the second, has its influence upon the 
 position, illumination or darkening of the object as it 
 appears by the second reflection. This influence must 
 be the strongest when the two planes are what we must 
 call negatively related to each other: that is, when 
 they are at right angles." " But," he adds, " when men 
 infer (as Mai us has done) from the modification which 
 is produced by this situation, in the illumination of the 
 reflection, that the molecules of light in themselves, 
 that is, on their different sides, possess different physical 
 energies ; and when on this foundation, along with the 
 phenomena of entoptical colours therewith connected, a 
 wide labyrinth of the most complex theory is erected ; 
 we have then one of the most remarkable examples of 
 the inferences of physics from experiment." If Hegel's 
 reasoning prove anything, it must prove that polariza- 
 tion always accompanies reflection under such circum- 
 stances as he describes : yet all physical philosophers 
 know that in the case of metals, in which the reflection 
 is most complete, light is not completely polarized at 
 any angle ; and that in other substances the polarization 
 depends upon various circumstances which show how 
 idle and inapplicable is the account he thus gives of the 
 
 * Sec. 278. 
 
374 PHILOSOPHY OF THE MECHANICO-CHEMICAL SCIENCES. 
 
 property. His self-complacent remark about the infer- 
 ences of physics from experiment, is intended to recom- 
 mend by comparison his own method of considering the 
 nature of things in themselves ; a mode of obtaining 
 physical truth which had been more than exhausted by 
 Aristotle, and out of which no new attempts have ex- 
 tracted anything of value since his time. 
 
 14. Thus the general conclusion to which we are led 
 on this subject is, that the persuasion of the existence 
 and connexion or identity of various polarities in nature, 
 although very naturally admitted, and in many cases 
 interpreted and confirmed by observed facts, is of itself, 
 so far as we at present possess it, a very insecure guide 
 to scientific doctrines. When it is allowed to dictate 
 our theories, instead of animating and extending our 
 experimental researches, it leads only to errour, confusion, 
 obscurity, and mysticism. 
 
 This Fifth Book, on the subject of Polarities, is a 
 short one compared with most of the others. This 
 arises in a great measure from the circumstance that the 
 Idea of Polarity has only recently been apprehended and 
 applied, with any great degree of clearness, among phy- 
 sical philosophers ; and is even yet probably entertained 
 in an obscure and ambiguous manner by most experi- 
 mental inquirers. I have been desirous of not attempt- 
 ing to bring forward any doctrines upon the subject, 
 except such as have been fully illustrated and exemplified 
 by the acknowledged progress of the physical sciences. 
 If I had been willing to discuss the various speculations 
 which have been published respecting the universal pre- 
 valence of polarities in the universe, and their results in 
 every province of nature, I might easily have presented 
 this subject in a more extended form ; but this would 
 not have been consistent with my plan of tracing the 
 influence of scientific ideas only so far as they have really 
 
OF THE CONNEXION OF POLARITIES. 375 
 
 aided in disclosing and developing scientific truths. And 
 as the influence of this idea is clearly distinguishable 
 both from those which precede and those which follow in 
 the character of the sciences to which it gives rise, and 
 appears likely to be hereafter of great extent and conse- 
 quence, it seemed better to treat of it in a separate 
 Book, although of a brevity disproportioned to the 
 rest. 
 
376 
 
 BOOK VI. 
 
 THE PHILOSOPHY OF CHEMISTRY. 
 
 CHAPTER I. 
 
 ATTEMPTS TO CONCEIVE ELEMENTARY 
 COMPOSITION. 
 
 1. WE have now to bring into view, if possible, the 
 ideas and general principles which are involved in Che- 
 mistry, the science of the composition of bodies. For in 
 this as in other parts of human knowledge, we shall find 
 that there are certain ideas, deeply seated in the mind, 
 though shaped and unfolded by external observation, 
 which are necessary conditions of the existence of such 
 a science. These ideas it is, which impel man to such 
 a knowledge of the composition of bodies, which give 
 meaning to facts exhibiting this composition, and uni- 
 versality to special truths discovered by experience. 
 These are the Ideas of Element and of Substance. 
 
 Unlike the idea of polarity, of which we treated in 
 the last Book, these ideas have been current in men's 
 minds from very early times, and formed the subject of 
 some of the first speculations of philosophers. It hap- 
 pened however, as might have been expected, that in the 
 first attempts they were not clearly distinguished from 
 other notions, and were apprehended and applied in an 
 obscure and confused manner. We cannot better ex- 
 hibit the peculiar character and meaning of these ideas 
 than by tracing the form which they have assumed and 
 
CONCEPTION OF ELEMENTARY COMPOSITION. 377 
 
 the efficacy which they have exerted in these successive 
 essays. This, therefore, I shall endeavour to do, begin- 
 ning with the Idea of Element. 
 
 2. That bodies are composed or made up of certain 
 parts, elements, or principles, is a conception which has 
 existed in men's minds from the beginning of the first 
 attempts at speculative knowledge. The doctrine of the 
 Four Elements, earth, air, fire and water, of which all 
 things in the universe were supposed to be constituted, 
 is one of the earliest forms in which this conception was 
 systematized ; and this doctrine is stated by various 
 authors to have existed as early as the times of the 
 ancient Egyptians"''". The words usually employed by 
 Greek writers to express these elements are apxn> & prin- 
 ciple or beginning, and aToiyelov, which probably meant 
 a letter (of a word) before it meant an element of a 
 compound. For the resolution of a word into its letters 
 is undoubtedly a remarkable instance of a successful 
 analysis performed at an early stage of man's history ; 
 and might very naturally supply a metaphor to denote 
 the analysis of substances into their intimate parts, when 
 men began to contemplate such an analysis as a subject 
 of speculation. The Latin word elementum itself, though 
 by its form it appears to be a derivative abstract term, 
 comes from some root now obsolete ; probably f from a 
 word signifying to grow or spring up. 
 
 The mode in which elements form the compound 
 bodies and determine their properties was at first, as 
 might be expected, vaguely and variously conceived. It 
 will, I trust, hereafter be made clear to the reader that 
 
 * Gilbert's Phys., L. i. c. iii. 
 
 t Vossius in voce. " Conjecto esse ab antiqua voco eleo pro oleo, 
 id est cresco : a qua significatione proles^ suboles, adolescens : ut ab 
 juratum, juramentum ; ab adjutum, adj umenturn : sic ab eletum, 
 demenlum : quia inde omriia crescunt ac nascuntur." 
 
378 PHILOSOPHY OF CHEMISTRY. 
 
 the relation of the elements to the compound involves a 
 peculiar and appropriate Fundamental Idea, not suscept- 
 ible of being correctly represented by any comparison or 
 combination of other ideas, and guiding us to clear and 
 definite results only when it is illustrated and nourished 
 by an abundant supply of experimental facts. But at first 
 the peculiar and special notion which is required in a just 
 conception of the constitution of bodies was neither dis- 
 cerned nor suspected ; and up to a very late period in the 
 history of chemistry, men went on attempting to appre- 
 hend the constitution of bodies more clearly by substi- 
 tuting for this obscure and recondite idea of Elementary 
 Composition, some other idea more obvious, more lumi- 
 nous, and more familiar, such as the ideas of Resem- 
 blance, Position, and mechanical Force. We shall briefly 
 speak of some of these attempts, and of the errours which 
 were thus introduced into speculations on the relations 
 of elements and compounds. 
 
 3. Compounds assumed to resemble their Elements. 
 The first notion was that compounds derive their quali- 
 ties from their elements by resemblance : they are hot 
 in virtue of a hot element, heavy in virtue of a heavy 
 element, and so on. In this way the doctrine of the four 
 elements was framed; for every body is either hot or 
 cold, moist or dry ; and by combining these qualities in 
 all possible ways, men devised four elementary sub- 
 stances, as has been stated in the History*. 
 
 This assumption of the derivation of the qualities of 
 bodies from similar qualities in the elements was, as we 
 shall see, altogether baseless and unphilosophical, yet it 
 prevailed long and universally. It was the foundation of 
 medicine for a long period, both in Europe and Asia; 
 disorders being divided into hot, cold, and the like ; and 
 remedies being arranged according to similar distinctions. 
 
 * Hist. Ind Set., B. i. c. ii. sect. 2. 
 
CONCEPTION OF ELEMENTARY COMPOSITION. 379 
 
 Many readers will recollect, perhaps, the story* of the 
 indignation which the Persian physicians felt towards the 
 European, when he undertook to cure the ill effects of 
 cucumber upon the patient, by means of mercurial medi- 
 cine : for cucumber, which is cold, could not be coun- 
 teracted, they maintained, by mercury, which in their 
 classification is cold also. Similar views of the operation 
 of medicines might easily be traced in our own country. 
 A moment's reflection may convince us that when drugs 
 of any kind are subjected to the chemistry of the 
 human stomach and thus made to operate on the human 
 frame, it is utterly impossible to form the most remote 
 conjecture what the result will be from any such vague 
 notions of their qualities as the common use of our 
 senses can give. . And in like manner the common ope- 
 rations of chemistry give rise in almost every instance 
 to products which bear no resemblance to the materials 
 employed. The results of the furnace, the alembic, the 
 mixture, frequently have no visible likeness to the 
 ingredients operated upon. Iron becomes steel by the 
 addition of a little charcoal ; but what visible trace of 
 the charcoal is presented by the metal thus modified ? 
 The most beautiful colours are given to glass and 
 earthenware by minute portions of the ores of black or 
 dingy metals, as iron and manganese. The worker in 
 metal, the painter, the dyer, the vintner, the brewer, 
 all the artisans in short who deal with practical che- 
 mistry, are able to teach the speculative chemist that 
 it is an utter mistake to expect that the qualities of the 
 elements shall be still discoverable, in an unaltered form, 
 in the compound. This first rude notion of an element, 
 that it determines the properties of bodies by resem- 
 blance, must be utterly rejected and abandoned before 
 
 * See Hadji Baba. 
 
380 PHILOSOPHY OF CHEMISTRY. 
 
 we can make any advance towards a true apprehension 
 of the constitution of bodies. 
 
 4. This step accordingly was made, when the hypo- 
 thesis of the four elements was given up, and the doc- 
 trine of the three Principles, Salt, Sulphur and Mercury, 
 was substituted in its place. For in making this change, 
 as I have remarked in the History*, the real advance 
 was the acknowledgment of the changes produced by 
 the chemist's operations as results to be accounted for 
 by the union and separation of substantial elements, 
 however great the changes, and however unlike the 
 product might be to the materials. And this step once 
 made, chemists went on constantly advancing towards 
 a truer view of the nature of an element, and conse- 
 quently, towards a more satisfactory theory of chemical 
 operations. 
 
 5. Yet we may, I think, note one instance, even in 
 the works of eminent modern chemists, in which this 
 maxim, that we have no right to expect any resem- 
 blance between the elements and the compound, is lost 
 sight of. I speak of certain classifications of mineral 
 substances. Berzelius, in his System of Mineral Arrange- 
 ment, places sulphur next to the sulphurets. But surely 
 this is an errour, involving the ancient assumption of 
 the resemblance of elements and compounds ; as if we 
 were to expect the sulphurets to bear a resemblance to 
 sulphur. All classifications are intended to bring toge- 
 ther things resembling each other : the sulphurets of 
 metals have certain general resemblances to each other 
 which make them a tolerably distinct, well determined, 
 class of bodies. But sulphur has no resemblances with 
 these, and no analogies with them, either in physical 
 or even in chemical properties. It is a simple body; 
 
 * Hist. Ind. Scl, B. iv. c. i. 
 
CONCEPTION OF ELEMENTARY COMPOSITION. 381 
 
 and both its resemblances and its analogies direct us to 
 place it along with other simple bodies, (selenium, and 
 phosphorus,) which, united with metals, produce com- 
 pounds not very different from the sulphurets. Sulphur 
 cannot be, nor approach to being, a sulphuret ; we must 
 not confound what it is with what it makes. Sulphur 
 has its proper influence in determining the properties of 
 the compound into which it enters ; but it does not do 
 this according to resemblance of qualities, or according 
 to any principle which properly leads to propinquity in 
 classification. 
 
 6. Compounds assumed to be determined by the Figure 
 of Elements. I pass over the fanciful modes of represent- 
 ing chemical changes which were employed by the Alche- 
 mists; for these strange inventions did little in leading 
 men towards a juster view of the relations of elements to 
 compounds. I proceed for an instant to the attempt to 
 substitute another obvious conception for the still obscure 
 notion of elementary composition. It was imagined that 
 all the properties of bodies and their mutual operations 
 might be accounted for by supposing them constituted of 
 particles of various forms, round or angular, pointed or 
 hooked, straight or spiral. This is a very ancient hypo- 
 thesis, and a favourite one with many casual speculators 
 in all ages. Thus Lucretius undertakes to explain why 
 wine passes rapidly through a sieve and oil slowly, by 
 telling us that the latter substance has its particles either 
 larger than those of the other, or more hooked and inter- 
 woven together. And he accounts for the difference of 
 sweet and bitter by supposing the particles in the former 
 case to be round and smooth, in the latter sharp and 
 jagged*. Similar assumptions prevailed in modern times 
 on the revival of the mechanical philosophy, and consti- 
 tute a large part of the physical schemes of Descartes 
 
 * De Rerum Natura, u. 390 sqq. 
 
382 PHILOSOPHY OF CHEMISTRY. 
 
 and Gassendi. They were also adopted to a considerable 
 extent by the chemists. Acids were without hesitation 
 assumed to consist of sharp pointed particles ; which, " I 
 hope," Lemery says *, " no one will dispute, seeing every 
 one's experience does demonstrate it : he needs but taste 
 an acid to be satisfied of it, for it pricks the tongue like 
 anything keen and finely cut." Such an assumption is 
 not only altogether gratuitous and useless, but appears to 
 be founded in some degree upon a confusion in the meta- 
 phorical and literal use of such words as keen and sharp. 
 The assumption once made, it was easy to accommodate 
 it, in a manner equally arbitrary, to other facts. "A 
 demonstrative and convincing proof that an acid does 
 consist of pointed parts is, that not only all acid salts do 
 crystallize into edges, but all dissolutions of different 
 things, caused by acid liquors, do assume this figure in 
 their crystallization. These crystals consist of points 
 differing both in length and bigness one from another, 
 and this diversity must be attributed to the keener or 
 blunter edges of the different sorts of acids : and so like- 
 wise this difference of the points in subtilty is the cause 
 that one acid can penetrate and dissolve with one sort of 
 mixt, that another can't rarify at all : Thus vinegar dis- 
 solves lead, which aquafortis can't : aquafortis dissolves 
 quicksilver, which vinegar will not touch ; aqua regalis 
 dissolves gold, whenas aquafortis cannot meddle with it ; 
 on the contrary, aqua fortis dissolves silver, but can do 
 nothing with gold, and so of the rest." 
 
 The leading fact of the vehement combination and 
 complete union of acid and alkali readily suggested a fit 
 form for the particles of the latter class of substances. 
 " This effect," Lemery adds, " may make us reasonably 
 conjecture that an alkali is a terrestrious and solid mat- 
 ter whose forms are figured after such a manner that the 
 
 * Chemistry, p. 25. 
 
CONCEPTION OF ELEMENTARY COMPOSITION. 383 
 
 acid points entering in do strike and divide whatever 
 opposes their motion." And in a like spirit are the spe- 
 culations in Dr. Mead's Mechanical Account of Poisons 
 (1745). Thus he explains the poisonous effect of corro- 
 sive sublimate of mercury by saying* that the particles of 
 the salt are a kind of lamellae or blades to which the 
 mercury gives an additional weight. If resublimed with 
 three-fourths the quantity of mercury, it loses its corro- 
 siveness, (becoming calomel,} which arises from this, that 
 in sublimation " the crystalline blades are divided every 
 time more and more by the force of the fire ;" and " the 
 broken pieces of the crystals uniting into little masses of 
 differing figures from their former make, those cutting- 
 points are now so much smaller that they cannot make 
 wounds deep enough to be equally mischievous and 
 deadly : and therefore do only vellicate and twitch the 
 sensible membranes of the stomach." 
 
 7. Among all this very fanciful and gratuitous assump- 
 tion we may notice one true principle clearly introduced, 
 namely, that the suppositions which we make respecting 
 the forms of the elementary particles of bodies and their 
 mode of combination must be such as to explain the facts 
 of crystallization, as well as of mere chemical change. 
 This principle we shall hereafter have occasion to insist 
 upon further. 
 
 I now proceed to consider a more refined form of 
 assumption respecting the constitution of bodies, yet still 
 one in which a vain attempt is made to substitute for the 
 peculiar idea of chemical composition a more familiar 
 mechanical conception. 
 
 8. Compounds assumed to be determined by the Mecha- 
 nical Attraction of the Elements. When, in consequence 
 of the investigations and discoveries of Newton and his 
 predecessors, the conception of mechanical force had 
 
 * P. 199. 
 
384 PHILOSOPHY OF CHEMISTRY. 
 
 become clear and familiar, so far as the action of exter- 
 nal forces upon a body was concerned, it was very natural 
 that the mathematicians who had pursued this train of 
 speculation should attempt to apply the same conception 
 to that mutual action of the internal parts of a body by 
 which they are held together. Newton himself had 
 pointed the way to this attempt. In the Preface to the 
 Principle after speaking of what he has done in calcu- 
 lating the effects of forces upon the planets, satellites, 
 &c., he adds, " Would it were permitted us to deduce the 
 other phenomena of nature from mechanical principles 
 by the same kind of reasoning. For many things move 
 me to suspect that all these phenomena depend upon 
 certain forces, by which the particles of bodies, through 
 causes not yet known, are either urged towards each 
 other, and cohere according to regular figures, or are 
 repelled and recede from each other ; which forces being 
 unknown, philosophers have hitherto made their attempts 
 upon nature in vain." The same thought is at a later 
 period followed out further in one of the Queries at the 
 end of the Opticks*. "Have not the small particles of 
 bodies certain Powers, Virtues, or Forces, by which they 
 act at a distance, not only upon the rays of light for 
 reflecting, refracting and inflecting them, but also upon 
 one another for producing a great part of the phenomena 
 of nature?" And a little further on he proceeds to 
 apply this expressly to chemical changes. " When Salt 
 of Tartar runs per deliquium [or as we now express it, 
 deliquesces] is not this done by an attraction between 
 the particles of the Salt of Tartar and the particles of 
 the water which float in the air in the form of vapours ? 
 And why does not common salt, or saltpetre, or vitriol, 
 run per deliquium, but for want of such an attraction ? or 
 why does not Salt of Tartar draw more water out of the 
 
 * Query 31. 
 

 CONCEPTION OF ELEMENTARY COMPOSITION. 583 
 
 air than in a certain proportion to its quantity, but for 
 want of an attractive force after it is saturated with 
 water?" He goes on to put a great number of similar 
 cases, all tending to the same point, that chemical com- 
 binations cannot be conceived in any other way than as 
 an attraction of particles. 
 
 9. Succeeding speculators in his school attempted to 
 follow out this view. Dr. Frend, of Christ Church, in 
 1710, published his Prcelectiones Chymicce, in quibus 
 omnes fere Operationes Chymicce ad vera Principia 
 ex ipsius Naturce Legibus rediguntur. Oxonii habitat. 
 This book is dedicated to Newton, and in the dedication, 
 the promise of advantage to chemistry from the influence 
 of the Newtonian discoveries is spoken of somewhat 
 largely, much more largely, indeed, than has yet been 
 justified by the sequel. After declaring in strong terms 
 that the only prospect of improving science consists in 
 following the footsteps of Newton, the author adds, 
 " That force of attraction, of which you first so success- 
 fully traced the influence in the heavenly bodies, ope- 
 rates in the most minute corpuscles, as you long ago 
 hinted in your Principia, and have lately plainly shown 
 in your Opticks ; and this force we are only just begin- 
 ning to perceive and to study. Under these circum- 
 stances I have been desirous of trying what is the result 
 of this view in chemistry." The work opens formally 
 enough, with a statement of general mechanical prin- 
 ciples, of which the most peculiar are these : That 
 there exists an attractive force by which particles when 
 at very small distances from each other, are drawn to- 
 gether; that this force is different, according to the 
 different figure and density of the particles ; that the 
 force may be greater on one side of a particle than on 
 the other; that the force by which particles cohere 
 together arises from attraction, and is variously modi- 
 
 VOL. i. w. P. C c 
 
386 PHILOSOPHY OF CHEMISTRY. 
 
 fied according to the quantity of contacts." But these 
 principles are not applied in any definite manner to the 
 explanation of specific phenomena. He attempts, in- 
 deed, the question of special solvents*. Why does aqua 
 fortis dissolve silver and not gold, while aqua regia 
 dissolves gold and not silver? which, he says, is the 
 most difficult question in chemistry, and which is cer- 
 tainly a fundamental question in the formation of che- 
 mical theory. He solves it by certain assumptions 
 respecting the forces of attraction of the particles, and 
 also the diameter of the particles of the acids and the 
 pores of the metals, all which suppositions are gratuitous. 
 
 10. We may observe further, that by speaking, as I 
 have stated that he does, of the figure of particles, he 
 mixes together the assumption of the last section with 
 the one which we are considering in this. This com- 
 bination is very unphilosophical, or, to say the least, 
 very insufficient, since it makes a new hypothesis neces- 
 sary. If a body be composed of cubical particles, held 
 together by their mutual attraction, by what force are 
 the parts of each cube held together ? In order to un- 
 derstand their structure, we are obliged again to assume 
 a cohesive force of the second order, binding together 
 the particles of each particle. And therefore Newton 
 himself says f, very justly, "The parts of all homogeneal 
 hard bodies which fully touch each other, stick together 
 very strongly : and for explaning how this is, some have 
 invented hooked atoms, which is begging the question." 
 For (he means to imply,) how do the parts of the hook 
 stick together ? 
 
 The same remark is applicable to all hypotheses in 
 
 which particles of a complex structure are assumed as 
 
 the constituents of bodies : for while we suppose bodies 
 
 and their known properties to result from the mutual 
 
 * P. 54. t Opticks, p. 304. 
 
CONCEPTION OF ELEMENTARY COMPOSITION. 1J87 
 
 actions of these particles, we are compelled to suppose 
 the parts of each particle to be held together by forces 
 still more difficult to conceive, since they are disclosed 
 only by the properties of these particles, which as yet 
 are unknown. Yet Newton himself has not abstained 
 from such hypotheses : th^is he says *, " A particle of a 
 salt may be compared to a chaos, being dense, hard, dry, 
 and earthy in the center, and moist and watery in the 
 circumference." 
 
 Since Newton's time the use of the term attraction, 
 as expressing the cause of the union of the chemical 
 elements of bodies, has been familiarly continued ; and 
 has, no doubt, been accompanied in the minds of many 
 persons with an obscure notion that chemical attraction 
 is, in some way, a kind of mechanical attraction of the 
 particles of bodies. Yet the doctrine that chemical " at- 
 traction" and mechanical attraction are forces of the 
 same kind has never, so far as I am aware, been worked 
 out into a system of chemical theory ; nor even applied 
 with any distinctness as an explanation of any particular 
 chemical phenomena. Any such attenpt, indeed, could 
 only tend to bring more clearly into view the entire 
 inadequacy of such a mode of explanation. For the 
 leading phenomena of chemistry are all of such a nature 
 that no mechanical combination can serve to express 
 them, without an immense accumulation of additional 
 hypotheses. If we take as our problem the changes of 
 colour, transparency, texture, taste, odour, produced by 
 small changes in the ingredients, how can we expect to 
 give a mechanical account of these, till we can give 
 a mechanical account of colour, transparency, texture, 
 taste, odour, themselves ? And if our mechanical hypo- 
 thesis of the elementary constitution of bodies does not 
 explain such phenomena as those changes, what can it 
 
 * Opticlcs, p. 362. 
 
 CC2 
 
388 PHILOSOPHY OF CHEMISTRY. 
 
 explain, or what can be the value of it ? I do not here 
 insist upon a remark which will afterwards come before 
 us, that even crystalline form, a phenomenon of a far 
 more obviously mechanical nature than those just al- 
 luded to, has never yet been in any degree explained by 
 such assumptions as this, that bodies consist of elemen- 
 tary particles exerting forces of the same nature as the 
 central forces which we contemplate in Mechanics. 
 
 When therefore Newton asks, " When some stones, 
 as spar of lead, dissolved in proper menstruums, become 
 salts, do not these things show that salts are dry earth 
 and watery acid united by attraction f we may answer, 
 that this mode of expression appears to be intended to 
 identify chemical combination with mechanical attrac- 
 tion; that there would be no objection to any such 
 identification, if we could, in that way, explain, or even 
 classify well, a collection of chemical facts; but that 
 this has never yet been done by the help of such expres- 
 sions. Till some advance of this kind can be pointed 
 out, we must necessarily consider the power which pro- 
 duces chemical combination as a peculiar principle, a 
 special relation of the elements, not rightly expressed in 
 mechanical terms. And we now proceed to consider 
 this relation under the name by which it is most fami- 
 liarly known. 
 
 CHAPTER II. 
 
 ESTABLISHMENT AND DEVELOPMENT OF THE 
 IDEA OF CHEMICAL AFFINITY. 
 
 1. THE earlier chemists did not commonly involve 
 themselves in the confusion into which the mechanical 
 philosophers ran, of comparing chemical to mechanical 
 forces. Their attention was engaged, and their ideas 
 
IDEA OF CHEMICAL AFFINITY. 389 
 
 were moulded, by their own pursuits. They saw that 
 the connexion of elements and compounds with which 
 they had to deal, was a peculiar relation which must be 
 studied directly ; and which must be understood, if un- 
 derstood at all, in itself, and not by comparison with a 
 different class of relations. At different periods of the 
 progress of chemistry, the conception of this relation, 
 still vague and obscure, was expressed in various man- 
 ners; and at last this conception was clothed in tole- 
 rably consistent phraseology, and the principles which it 
 involved were, by the united force of thought and expe- 
 riment, brought into view. 
 
 2. The power by which the elements of bodies com- 
 bine chemically, being, as we have seen, a peculiar agency, 
 different from mere mechanical connexion or attraction, 
 it is desirable to have it designated by a distinct and 
 peculiar name ; and the term Affinity has been employed 
 for that purpose by most modern chemists. The word 
 " affinity" in common language means, sometimes resem- 
 blance, and sometimes relationship and ties of family. 
 It is from the latter sense that the metaphor is bor- 
 rowed when we speak of " chemical affinity." By the 
 employment of this term we do not indicate resem- 
 blance, but disposition to unite. Using the word in a 
 common unscientific manner, we might say that chlo- 
 rine, bromine, and iodine, have a great natural affinity 
 with each other, for there are considerable resemblances 
 and analogies among them ; but these bodies have very 
 little chemical affinity for each other. The use of the 
 word in the former sense, of resemblance, can be traced 
 in earlier chemists ; but it does not appear to have 
 acquired its peculiar chemical meaning till after Boer- 
 haave's time. Boerhaave, however, is the writer in 
 whom we first find a due apprehension of the peculiar- 
 ity and importance of the Idea which it now expresses. 
 
390 PHILOSOPHY OF CHEMISTRY. 
 
 When we make a chemical solution*, he says, not only 
 are the particles of the dissolved body separated from 
 each other, but they are closely united to the particles 
 of the solvent. When aqua regia dissolves gold, do you 
 not see, he says to his hearers, that there must be be- 
 tween each particle of the solvent and of the metal, a 
 mutual virtue by which each loves, unites with, and 
 holds the other (amat, unit, retinet) ? The opinion pre- 
 viously prevalent had been that the solvent merely 
 separates the parts of the body dissolved: and most 
 philosophers had conceived this separation as performed 
 by mechanical operations of the particles, resembling, 
 for instance, the operation of wedges breaking up a 
 block of timber. But Boerhaave forcibly and earnestly 
 points out the insufficiency of the conception. This, he 
 says, does not account for what we see. We have not 
 only a separation, but a new combination. There is a 
 force by which the particles of the solvent associate to 
 themselves the parts dissolved, not a force by which 
 they repel and dissever them. We are here to imagine 
 not mechanical action, not violent impulse, not antipathy, 
 but love, at least if love be the desire of uniting. (Non 
 igitur hie etiam actiones mechanicse, non propulsiones 
 violentse, non inimicitiae cogitandae, sed amicitia9, si amor 
 dicendus copulae cupido.) The novelty of this view is 
 evidenced by the mode in which he apologizes for intro- 
 ducing it. " Fateor, paradoxa haec assertio." To Boer- 
 haave, therefore, (especially considering his great influ- 
 ence as a teacher of chemistry,) we may assign the 
 merit of first diffusing a proper view of Chemical Affinity 
 as a peculiar force, the origin of almost all chemical 
 changes and operations. 
 
 3. To Boerhaave is usually assigned also the credit 
 of introducing the word "affinity" among chemists; but 
 * Elementa Chemice. Lugd. Bat. 1732, p. 677. 
 
IDEA OF CHEMICAL AFFINITY. 391 
 
 I do not find that the word is often used by him in this 
 sense ; perhaps not at all*. But however this may be, 
 the term is, on many accounts well worthy to be pre- 
 served, as I shall endeavour to show. Other terms were 
 used in the same sense during the early part of the 
 eighteenth century. Thus when Geoffrey, in 1718, laid 
 before the Academy of Paris his Tables of Affinities, 
 which perhaps did more than any other event to fix the 
 Idea of Affinity, he termed them " Tables of the Rela- 
 tions of Bodies ;" " Tables des Rapports :" speaking 
 however, also, of their " disposition to unite," and using 
 other phrases of the same import. 
 
 The term attraction, having been recommended by 
 Newton as a fit word to designate the force which pro- 
 duces chemical combination, continued in great favour 
 in England, where the Newtonian philosophy was looked 
 upon as applicable to every branch of science. In 
 France, on the contrary, where Descartes still reigned 
 triumphant, " attraction," the watch-word of the enemy, 
 was a sound never uttered but with dislike and suspi- 
 cion. In 1718 (in the notice of Geoffrey's Tables,) the 
 Secretary of the Academy, after pointing out some of 
 the peculiar circumstances of chemical combinations, says, 
 "Sympathies and attractions would suit well here, if 
 
 * See Dumas, Lemons de Phil. Chim., p. 364. Rees' Cyclopaedia, 
 Art. Chemistry. In the passage of Boerhaave to which I refer above, 
 affinitas is rather opposed to, than identified with, chemical combina- 
 tion. "When, he says, the parts of the body to be dissolved are disse- 
 vered by the solvent, why do they remain united to the particles of the 
 solvent, and why do not rather both the particles of the solvent and of 
 the dissolved body collect into homogeneous bodies by their affinity ? 
 " denuo se affinitate suse naturas colligant in corpora homogenea ?" And 
 the answer is, because they possess another force which counteracts 
 this affinity of homogeneous particles, and makes compounds of dif- 
 ferent elements. Affinity, in chemistry, now means the tendency of 
 different kinds of matter to unite : but it appears, as I have said, to 
 have acquired this sense since Boerhaave's time. 
 
392 PHILOSOPHY OF CHEMISTRY. 
 
 there were such things." " Les sympathies, les attrac- 
 tions conviendroient bien ici, si elles etaient quelque 
 chose." And at a later period, in 1731, having to write 
 the eloge of Geoffroy after his death, he says, "He gave, 
 in 1718, a singular system, and a Table of Affinities, or 
 Relations of the different substances in chemistry. These 
 affinities gave uneasiness to some persons, who feared 
 that they were attractions in disguise, and all the more 
 dangerous in consequence of the seductive forms which 
 clever people have contrived to give them. It was found 
 in the sequel that this scruple might be got over." 
 
 This is the earliest published instance, so far as I am 
 aware, in which the word "affinity" is distinctly used 
 for the cause of chemical composition ; and taking into 
 account the circumstances, the word appears to have 
 been adopted in France in order to avoid the word 
 attraction, which had the taint of Newtonianism. Ac- 
 cordingly we find the word affinite employed in the 
 works of French chemists from this time. Thus, in the 
 Transactions of the French Academy for 1746, in a 
 paper of Macquer's upon Arsenic, he says"*, "On peut 
 facilement rendre raison de ces phenomenes par le moyen 
 des affinites que les differens substances qui entrent 
 dans ces combinaisons, out les uns avec les autres :" and 
 he proceeds to explain the facts by reference to Geof- 
 froy's Table. And in Macquer's Elements of Chemistry, 
 which appeared a few years later, the " affinity of com-> 
 position" is treated of as a leading part of the subject, 
 much in the same way as has been practised in such 
 books up to the present time. From this period, the 
 word appears to have become familiar to all European 
 chemists in the sense of which we are now speaking. 
 Thus, in the year 1758, the Academy of Sciences at 
 Rouen offered a prize for the best dissertation on Affinity. 
 * A, P. 1746, P . 201. 
 
IDEA OF CHEMICAL AFFINITY. 393 
 
 The prize was shared between M. Limbourg of Theux, 
 near Liege, and M. Le Sage of Geneva*. About the 
 same time other persons (Manherrf, Nicolai J, and others) 
 wrote on the same subject, employing the same name. 
 
 Nevertheless, in 1775, the Swedish chemist Bergman, 
 pursuing still further this subject of Chemical Affinities, 
 and the expression of them by means of Tables, returned 
 again to the old Newtonian term; and designated the 
 disposition of a body to combine with one rather than 
 another of two others as elective attraction. And as his 
 work on Elective Attractions had great circulation and 
 great influence, this phrase has obtained a footing by the 
 side of Affinity, and both one and the other are now in 
 common use among chemists. 
 
 4. I have said above that the term Affinity is worthy 
 of being retained as a technical term. If we use the 
 word attraction in this case, we identify or compare 
 chemical with mechanical attraction ; from which iden- 
 tification and comparison, as I have already remarked, 
 no one has yet been able to extract the means of ex- 
 pressing any single scientific truth. If such an identi- 
 fication or comparison be not intended, the use of the 
 same word in two different senses can only lead to con- 
 fusion ; and the proper course, recommended by all the 
 best analogies of scientific history, is to adopt a peculiar 
 term for that peculiar relation on which chemical com- 
 position depends. The word affinity, even if it were 
 not rigorously proper according to its common meaning, 
 still, being simple, familiar, and well established in this 
 very usage, is much to be preferred before any other. 
 
 But further, there are some analogies drawn from 
 
 * Thomson's Chemistry, in. 10. Limbourg's Dissertation was 
 published at Liege, in 1761 ; and Le Sage's at Geneva, 
 t Dissertatio de Affinitate Corporum. Vindob. 1762. 
 ; Progr. I. II. de Affinitate Corporum Chimica. Jen. 177^ 
 
394 PHILOSOPHY OF CHEMISTRY. 
 
 the common meaning of this word, which appear to 
 recommend it as suitable for the office which it has to 
 discharge. For common mechanical attractions and re- 
 pulsions, the forces by which one body considered as a 
 whole acts upon another external to it, are, as we have 
 said, to be distinguished from those more intimate ties 
 by which the parts of each body are held together. Now 
 this difference is implied, if we compare the former 
 relations, the attractions and repulsions, to alliances and 
 wars between states, and the latter, the internal union 
 of particles, to those bonds of affinity which connect the 
 citizens of the same state with one another, and especially 
 to the ties of family. We have seen that Boerhaave 
 compares the union of two elements of a compound to 
 their marriage ; " we must allow," says an eminent 
 chemist of our own time*, "that there is some truth 
 in this poetical comparison." It contains this truth, 
 that the two become one to most intents and pur- 
 poses, and that the unit thus formed (the family) is not 
 a mere juxtaposition of the component parts. And 
 thus the Idea of Affinity as the peculiar principle of 
 chemical composition, is established among chemists, 
 and designated by a familiar and appropriate name. 
 
 5. Analysis is possible. We must, however, endea- 
 vour to obtain a further insight into this Idea, thus 
 fixed and named. We must endeavour to extricate, if 
 not from the Idea itself, from the processes by which it 
 has obtained acceptation and currency among chemists, 
 some principles which may define its application, some 
 additional specialities in the relations which it implies. 
 This we shall proceed to do. 
 
 The Idea of Affinity, as already explained, implies a 
 disposition to combine. But this combination is to be 
 understood as admitting also of a possibility of separa- 
 
 * Dumas, Lerons de P/iil.Chim., p.363. 
 
IDEA OF CHEMICAL AFFINITY. 395 
 
 tion. Synthesis implies Analysis as conceivable : or to 
 recur to the image which we have already used, Divorce 
 is possible when the Marriage has taken place. 
 
 That there is this possibility, is a conviction implied 
 in all the researches of chemists, ever since the true 
 notion of composition began to predominate in their 
 investigations. One of the first persons who clearly ex- 
 pressed this conviction was Mayow, an English physician, 
 who published his Medico-Physical Tracts in 1674. 
 The first of them De Sale-Nitro et Spiritu Nitro-Aerio, 
 contains a clear enunciation of this principle. After 
 showing how, in the combinations of opposite elements, 
 as acid and alkali, their properties entirely disappear, 
 and a new substance is formed not at all resembling 
 either of the ingredients, he adds*, "Although these 
 salts thus mixed appear to be destroyed, it is still pos- 
 sible for them to be separated from each other, with 
 their powers still entire." He proceeds to exemplify 
 this, and illustrates it by the same image which I have 
 already alluded to : " Salia acida a salibus volatilibus 
 disceduut, ut curn sale fixo tartari, tanquam sponso 
 magis idoneo, conjugium strictius ineunt." This idea of 
 a synthesis which left a complete analysis still possible, 
 was opposed to a notion previously current, that when 
 two heterogeneous bodies united together and formed a 
 third body, the two constituents were entirely destroyed, 
 and the result formed out of their ruins f. And this 
 conception of synthesis and analysis, as processes which 
 are possible successively and alternately, and each of 
 which supposes the possibility of the other, has been 
 the fundamental and regulative principle of the opera- 
 tions and speculations of analytical chemistry from the 
 time of Mayow to the present day. 
 
 6. Affinity is elective. When the idea of chemical 
 
 * Cap. xiv., p. 233. t Thomson's Chemistry, in. 8. 
 
396 PHILOSOPHY OF CHEMISTRY. 
 
 affinity, or disposition to unite, was brought into view by 
 the experiments and reasonings of chemists, they found 
 it necessary to consider this disposition as elective; 
 each element chose one rather than another of the ele- 
 ments which were presented to it, and quitted its union 
 with one to unite with another which it preferred. This 
 has already appeared in the passage just quoted from 
 Mayow. He adds in the same strain, " I have no doubt 
 that fixed salts choose one acid rather than another, in 
 order that they may coalesce with it in a more intimate 
 union." "Nullus dubito salia fixa acidum unum pra3 
 aliis eligere, ut cum eodem arctiore unione coalescant." 
 The same thought is expressed and exemplified by other 
 chemists: they notice innumerable cases in which, when 
 an ingredient is combined with a liquid, if a new sub- 
 stance be immersed which has a greater affinity for the 
 liquid, the liquid combines with the new r substance by 
 election, and the former ingredient is precipitated. Thus 
 Stahl says*, "In spirit of nitre dissolve silver; put in 
 copper and the silver is thrown down ; put in iron and 
 the copper goes down; put in zinc, the iron precipitates; 
 put in volatile alkali, the zinc is separated; put in fixed 
 alkali, the volatile quits its hold." As may be seen in 
 this example, we have in such cases, not only a prefer- 
 ence, but a long gradation of preferences. The spirit of 
 nitre will combine with silver, but it prefers copper; 
 prefers iron more ; zinc still more ; volatile alkali yet 
 more ; fixed alkali the most. 
 
 The same thing was proved to obtain with regard to 
 each element ; and when this was ascertained, it became 
 the object of chemists to express these degrees of prefer- 
 ence, by lists in which substances were arranged accord- 
 ing to their disposition to unite with another substance. 
 In this manner was formed Geoffroy's Table of Affinities 
 * Zymotechnia, 1697, p. 1H- 
 
IDEA OF CHEMICAL AFFINITY. 397 
 
 (1718), which we have already mentioned. This Table 
 was further improved by other writers, as Gellert (1751) 
 and Limbourg (1761). Finally Bergman improved 
 these Tables still further, taking into account not only 
 the order of affinities of each element for others, but 
 the sum of the tendencies to unite of each two elements, 
 which sum, he held, determined the resulting combina- 
 tion when several elements were in contact with each 
 other. 
 
 7. As we have stated in the History "% when the doc- 
 trine of elective affinities had assumed this very definite 
 and systematic form, it was assailed by Berthollet, who 
 maintained, in his Essai de Statique Chimique, (1803,) 
 that chemical affinities are not elective : that, when 
 various elements are brought together, their combina- 
 tions do not depend upon the kind of elements alone, 
 but upon the quantity of each which is present, that 
 which is most abundant always entering most largely 
 into the resulting compounds. It may seem strange 
 that it should be possible, at so late a period of the 
 science, to throw doubt upon a doctrine which had pre- 
 sided over and directed its progress so long. Proust 
 answered Berthollet, and again maintained that chemi- 
 cal affinity is elective. I have, in the History, given the 
 judgment of Berzelius upon this controversy. "Ber- 
 thollet," he says, " defended himself with an acuteness 
 which makes the reader hesitate in his judgment; but 
 the great mass of facts finally decided the point in 
 favour of Proust." I may here add the opinion pro- 
 nounced upon this subject by Dr. Turner f. "Bergman 
 erred in supposing the result of the chemical action to 
 be in every case owing to elective affinity [for this power 
 is modified in its effects by various circumstances] : but 
 
 * Hist. Ind. ScL, B. xiv. c. iii. 
 t Chemistry, p. 199. Otb edition. 
 
398 PHILOSOPHY OF CHEMISTRY. 
 
 Berthollet ran into the opposite extreme in declaring 
 that the effects formerly ascribed to that power are 
 never produced by it. That chemical attraction is ex- 
 erted between different bodies with different degrees of 
 energy, is, I apprehend, indisputable." And he then 
 proceeds to give many instances of differences in affinity 
 which cannot be accounted for by the operation of any 
 modifying causes. Still more recently, M. Dumas has 
 taken a review of this controversy ; and, speaking with 
 enthusiasm of the work of Berthollet, as one which had 
 been of inestimable service to himself in his early study 
 of chemistry, he appears at first disposed to award to 
 him the victory in this dispute. But his final verdict 
 leaves undamaged the general principle now under our 
 consideration, that chemical affinity is elective. "For 
 my own part," he says *, " I willingly admit the notions 
 of Berthollet when we have to do with acids or with 
 bases, of which the energy is nearly equal : but when 
 bodies endued with very energetic affinities are in pre- 
 sence of other bodies of which the affinities are very 
 feeble, I propose to adopt the following rule : In a solu- 
 tion, everything remaining dissolved, the strong affinities 
 satisfy themselves, leaving the weak affinities to arrange 
 matters with one another. The strong acids take the 
 strong bases, and the weak acids can only unite with the 
 weak bases. The known facts are perfectly in accord- 
 ance with this practical rule." It is obvious that this 
 recognition of a distinction between strong and mecik 
 affinities, which operates to such an extent as to deter- 
 mine entirely the result, is a complete acknowledgement 
 of the elective nature of affinity, as far as any person 
 acquainted with chemical operations could contend for 
 it. For it must be allowed by all, that solubility, and 
 other collateral circumstances, influence the course of 
 
 * Lecons de Philosophic Chimique, p. 386. 
 
IDEA OF CHEMICAL AFFINITY. 399 
 
 chemical combinations, since they determine whether 
 or not there shall take place that contact of elements 
 without which affinity cannot possibly operate. 
 
 8. Affinity is Definite as to quantity. In proportion 
 as chemists obtained a clearer view of the products of 
 the laboratory as results of the composition of elements, 
 they saw more and more clearly that these results were 
 definite ; that one element not only preferred to combine 
 with another of a certain kind, but also would combine 
 with it to a certain extent and no further, thus giving to 
 the result not an accidental and variable, but a fixed 
 and constant character. Thus salts being considered as 
 the result of the combination of two opposite principles, 
 acid and alkali, arid being termed neutral when these 
 principles exactly balanced each other, Rouelle (who 
 was Royal Professor at Paris in 1742,) admits of neu- 
 tral salts with excess of acid, neutral salts with excess 
 of base, and perfect neutral salts. Beaume maintained* 
 against him that there were no salts except those per- 
 fectly neutral, the other classes being the results of mix- 
 ture and imperfect combination. But this question was 
 not adequately treated till chemists made every experi- 
 ment with the balance in their hands. When this was 
 done, they soon discovered that, in each neutral salt, the 
 proportional weights of the ingredients which composed 
 it were always the same. This was ascertained by Wen- 
 zel, whose Doctrine of the Affinities of Bodies appeared 
 in 1777. He not only ascertained that the proportions 
 of elements in neutral chemical compounds are definite, 
 but also that they are reciprocal ; that is, that if A, a 
 certain weight of a certain acid, neutralize m, a certain 
 weight of a certain base, and B, a certain weight of a 
 certain other acid, neutralize n, a certain weight of a 
 certain other base ; the compound of a A and n will also 
 
 * Dumas, Phil. Chim.,y. 198. 
 
400 PHILOSOPHY OF CHEMISTRY. 
 
 be neutral ; as also that of B and m. The same views 
 were again presented by Richter in 1792, in his Prin- 
 ciples of the Measure of Chemical Elements. And along 
 with these facts, that of the combination of elements in 
 multiple proportions being also taken into account, the 
 foundations of the Atomic Theory were laid ; and that 
 Theory was propounded in 1803 by Mr. Dalton. That 
 theory, however, rests upon the Idea of Substance, as 
 well as upon that Idea of Chemical Affinity which we 
 are here considering ; and the discussion of its evidence 
 and truth must be for the present deferred. 
 
 9. The two principles just explained, that affinity 
 is definite as to the kind, and as to the quantity of the 
 elements which it unites, have here been stated as 
 results of experimental investigation. That they could 
 never have been clearly understood, and therefore never 
 firmly established, without laborious and exact experi- 
 ments, is certain ; but yet we may venture to say that 
 being once fully known, they possess an evidence beyond 
 that of mere experiment. For how, in fact, can we con- 
 ceive combinations, otherwise than as definite in kind and 
 quantity? If we were to suppose each element ready 
 to combine with any other indifferently, and indifferently 
 in any quantity, we should have a world in which all 
 would be confusion and indefiniteness. There would be 
 no fixed kinds of bodies; salts, and stones, and ores, 
 would approach to and graduate into each other by in- 
 sensible degrees. Instead of this, we know that the 
 world consists of bodies distinguishable from each other 
 by definite differences, capable of being classified and 
 named, and of having general propositions asserted con- 
 cerning them. And as we cannot conceive a world in 
 which this should not be the case, it would appear that 
 we cannot conceive a state of things in which the laws 
 of the combination of elements should not be of that 
 
IDEA OF CHEMICAL AFFINITY. 401 
 
 definite and measured kind which we have above as- 
 serted. 
 
 This will, perhaps, appear more clearly by stating our 
 fundamental convictions respecting chemical composi- 
 tion in another form, which I shall, therefore, proceed 
 to do. 
 
 10. Chemical Composition determines Physical Pro- 
 perties. However obscure and incomplete may be our 
 conception of the internal powers by which the ultimate 
 particles of bodies are held together, it involves, at least, 
 this conviction : that these powers are what determine 
 bodies to be bodies, and therefore contain the reason of 
 all the properties which, as bodies, they possess. The 
 forces by which the particles of a body are held together, 
 also cause it to be hard or soft, heavy or light, opake 
 or transparent, black or red ; for if these forces are not 
 the cause of these peculiarities, what can be the cause ? 
 By the very supposition which we make respecting these 
 forces, they include all the relations by which the parts 
 are combined into a whole, and therefore they, and they 
 only, must determine all the attributes of the whole. 
 The foundation of all our speculations respecting the 
 intimate constitution of bodies must be this principle, 
 that their composition determines their properties. 
 
 Accordingly we find our chemists reasoning from this 
 principle with great confidence, even in doubtful cases. 
 Thus Davy, in his researches concerning the diamond, 
 says: " That some chemical difference must exist between 
 the hardest and most beautiful of the gems and charcoal, 
 between a non-conductor and a conductor of electricity, 
 it is scarcely possible to doubt : and it seems reasonable 
 to expect that a very refined or perfect chemistry will 
 confirm the analogies of nature ; and show that bodies 
 cannot be the same in their composition or chemical 
 nature, and yet totally different in their chemical pro- 
 VOL. i. w. P. D D 
 
402 PHILOSOPHY OF CHEMISTRY. 
 
 perties." It is obvious that the principle here assumed 
 is so far from being a mere result of experience, that it 
 is here appealed to to prove that all previous results of 
 experience on this subject must be incomplete and inac- 
 curate ; and that there must be some chemical differ- 
 ence between charcoal and diamond, though none had 
 hitherto been detected. 
 
 11. In what manner, according to what rule, the 
 chemical composition shall determine the kind of the 
 substance, we cannot reasonably expect to determine by 
 mere conjecture or assumption, without a studious ex- 
 amination of natural bodies and artificial compounds. 
 Yet even in the most recent times, and among men of 
 science, we find that an assumption of the most arbitrary 
 character has in one case been mixed up with this in- 
 disputable principle, that the elementary composition 
 determines the kind of the substance. In the classifica- 
 tion of minerals, one school of mineralogists have rightly 
 taken it as their fundamental principle that the chemi- 
 cal composition shall decide the position of the mineral 
 in the system. But they have appended to this principle, 
 arbitrarily and unjustifiably, the maxim that the element 
 which is largest in quantity shall fix the class of the 
 substance. To make such an assumption is to renounce, 
 at once, all hope of framing a system which shall be 
 governed by the resemblances of the things classified ; 
 for how can we possibly know beforehand that fifty-five 
 per cent, of iron shall give a substance its predominant 
 properties, and that forty-five per cent, shall not ? Ac- 
 cordingly, the systems of mineralogical arrangement 
 which have been attempted in this way, (those of Haiiy, 
 Phillips, and others,) have been found inconsistent with 
 themselves, ambiguous, and incapable of leading to any 
 general truths. 
 
 12. Chemical Composition and Crystalline Form cor- 
 
IDEA OF CHEMICAL AFFINITY. 403 
 
 respond. Thus the physical properties of bodies depend 
 upon their chemical composition, but in a manner which 
 a general examination of bodies with reference to their 
 properties and their composition can alone determine. 
 We may, however, venture to assert further, that the 
 more definite the properties are, the more distinct may 
 we expect to find this dependence. Now the most 
 definite of the properties of bodies are those constant 
 properties which involve relations of space ; that is, their 
 figure. We speak not, however, of that external figure, 
 derived from external circumstances, which, so far from 
 being constant and definite, is altogether casual and arbi- 
 trary ; but of that figure which arises from their internal 
 texture, and which shows itself not only in the regular 
 forms which they spontaneously assume, but in the 
 disposition of the parts to separate in definite directions, 
 and no others. In short, the most definite of the pro- 
 perties of perfect chemical compounds is their crystalline 
 structure ; and therefore it is evident that the crystalline 
 structure of each body, and the forms which it affects, 
 must be in a most intimate dependence upon its chemical 
 composition. 
 
 Here again we are led to the brink of another 
 theory ; that of crystalline structure, which has excited 
 great interest among philosophers ever since the time of 
 Haiiy. But this theory involves, besides that idea of 
 chemical composition with which we are here concerned, 
 other conceptions, which enter into the relations of 
 figure. These conceptions, governed principally by the 
 idea of Symmetry, must be unfolded and examined before 
 we can venture to discuss any theory of crystallization : 
 and we shall proceed to do this as soon as we have 
 first duly considered the Idea of Substance and its con- 
 sequences. 
 
 DD2 
 
404 PHILOSOPHY OF CHEMISTRY. 
 
 CHAPTER III. 
 OF THE IDEA OF SUBSTANCE. 
 
 1. Axiom of the Indestructibility of Substance. WE 
 now come to an Idea of which the history is very differ- 
 ent from those of which we have lately been speaking. 
 Instead of being gradually and recently brought into a 
 clear light, as has been the case with the Ideas of Polarity 
 and Affinity, the Idea of Substance has been entertained 
 in a distinct form from the first periods of European 
 speculation. That this is so, is proved by our finding a 
 principle depending upon this idea current as an axiom 
 among the early philosophers of Greece : namely, that 
 nothing can be produced out of nothing. Such an axiom, 
 more fully stated, amounts to this : that the substance of 
 which a body consists is incapable of being diminished 
 (and consequently incapable of being augmented) in 
 quantity, whatever apparent changes it may undergo. 
 Its form, its distribution, its qualities, may vary, but the 
 substance itself is identically the same under all these 
 variations. 
 
 The axiom just spoken of was the great principle 
 of the physical philosophy of the Epicurean school, as 
 it must be of every merely material philosophy. The 
 reader of Lucretius will recollect the emphasis with 
 which it is repeatedly asserted in his poem : 
 
 E nilo nil gigni, in nilum nil posse reverti; 
 Nought comes of nought, nor ought returns to nought. 
 
 Those who engaged in these early attempts at physical 
 speculation were naturally much pleased with the clear- 
 ness which was given to their notions of change, compo- 
 sition, and decomposition, by keeping steadily hold of the 
 Idea of Substance, as marked by this fundamental axiom. 
 Nor has its authority ever ceased to be acknowledged. 
 
IDEA OF SUBSTANCE. 405 
 
 A philosopher was asked"", What is the weight of smoke ? 
 He answered, "Subtract the weight of the ashes from 
 the weight of the wood which is burnt, and you have the 
 weight of the smoke." This reply would be assented to 
 by all ; and it assumes as incontestable that even under 
 the action of fire, the material, the substance, does not 
 perish, but only changes its form. 
 
 This principle of the indestructibility of substance 
 might easily be traced in many reasonings and researches, 
 ancient and modern. For instance, when the chemist 
 works with the retort, he places the body on which he 
 operates in one part of an inclosed cavity, which, by its 
 bendings and communications, separates at the same 
 time that it confines, the products which result from 
 the action of fire : and he assumes that this process 
 is an analysis of the body into its ingredients, not a 
 creation of anything which did not exist before, or a 
 destruction of anything which previously existed. And 
 he assumes further, that the total quantity of the sub- 
 stance thus analyzed is the sum of the quantities of its 
 ingredients. This principle is the very basis of chemical 
 speculation, as we shall hereafter explain more fully. 
 
 2. The Idea of Substance. The axiom above spoken 
 of depends upon the Idea of Substance, which is involved 
 in all our views of external objects. We unavoidably 
 assume that the qualities and properties which we observe 
 are properties of things-, that the adjective implies a 
 substantive ; that there is, besides the external charac- 
 ters of things, something of which they are the characters. 
 An apple which is red, and round, and hard, is not merely 
 redness, and roundness, and hardness: these circum- 
 stances may all alter while the apple remains the same 
 apple. Behind or under the appearances which we see, 
 we conceive something of which we think ; or, to use the 
 * Kant, Kritik. der E. V., p. ]67. 
 
406 PHILOSOPHY OF CHEMISTRY. 
 
 metaphor which obtained currency among the ancient 
 philosophers, the attributes and qualities which we ob- 
 serve are supported by and inherent in something : and 
 this something is hence called a substratum or sub- 
 stance, that which stands beneath the apparent quali- 
 ties and supports them. 
 
 That we have such an Idea, using the term " Idea" in 
 the sense in which I have employed it throughout these 
 disquisitions, is evident from what has been already said. 
 The axiom of the indestructibility of substance proves 
 the existence of the Idea of Substance, just as the Axioms 
 of Geometry and Arithmetic prove the existence of the 
 Ideas of Space and Number. In the case of substance, 
 as of space or number, the ideas cannot be said to be 
 borrowed from experience, for the axioms have an au- 
 thority of a far more comprehensive and demonstrative 
 character than any which experience can bestow. The 
 axiom that nothing can be produced from nothing and 
 nothing destroyed, is so far from being a result of expe- 
 rience, that it is apparently contradicted by the most 
 obvious observation. It has, at first, the air of a paradox ; 
 and by those who refer to it, it is familiarly employed to 
 show how fallacious common observation is. The asser- 
 tion is usually made in this form ; that nothing is 
 created and nothing annihilated, notwithstanding that 
 the common course of our experience appears to show 
 the contrary. The principle is not an empirical, but a 
 necessary and universal truth; is collected, not from 
 the evidence of our senses, but from the operation of 
 our ideas. And thus the universal and undisputed au- 
 thority of the axiom proves the existence of the Idea of 
 Substance. 
 
 3. Locke's Denial of the Idea of Substance. I shall 
 not attempt to review the various opinions which have 
 been promulgated respecting this Idea : but it may be 
 
IDEA OF SUBSTANCE. 407 
 
 worth our while to notice briefly the part which it played 
 in the great controversy concerning the origin of our ideas 
 which Locke's Essay occasioned. Locke's object was to 
 disprove the existence of all ideas not derived from Sen- 
 sation or Reflection : and since the idea of substance as 
 distinct from external qualities, is manifestly not derived 
 directly from sensation, nor by any very obvious or dis- 
 tinct process from reflection, Locke was disposed to 
 exclude the idea as much as possible. Accordingly, in 
 his argumentation against Innate Ideas*, he says plainly, 
 " the idea of substance, which we neither have nor can 
 have by sensation or reflection." And the inference 
 which he draws is, " that we have no such clear idea at 
 all." What then, it may be asked, do we mean by the 
 word substance? This also he answers, though some- 
 what strangely, " We signify nothing by the word sub- 
 stance, but only an uncertain supposition of we know 
 not what, i. #., of something whereof we have no par- 
 ticular distinct positive idea, which we take to be the 
 substratum, or support, of those ideas we know." That 
 while he indulged in this tautological assertion of our 
 ignorance and uncertainty, he should still have been 
 compelled to acknowledge that the word substance had 
 some meaning, and should have been driven to explain it 
 by the identical metaphors of " substratum " and " sup- 
 port," is a curious proof how impossible it is entirely to 
 reject this idea. 
 
 But as we have already seen, the supposition of the 
 existence of substance is so far from being uncertain, that 
 it carries with it irresistible conviction, and substance is 
 necessarily conceived as something which cannot be pro- 
 duced or destroyed. It may be easily supposed, therefore, 
 that when the controversy between Locke and his assail- 
 ants came to this point, he would be in some difficulty. 
 
 * Essay , B. i. eh. iv. s. 18. 
 
408 PHILOSOPHY OF CHEMISTRY. 
 
 And, indeed, though with his accustomed skill in contro- 
 versy, he managed to retain a triumphant tone, he was 
 driven from his main points. Thus he repels the charge 
 that he to.ok the being of substance to be doubtful*. 
 He says, " Having everywhere affirmed and built upon it 
 that man is a substance, I cannot be supposed to question 
 or doubt of the being of substance, till I can question or 
 doubt of my own being." He attempts to make a stand 
 by saying that being of things does not depend upon our 
 ideas ; but if he had been asked how, without having an 
 idea of substance, he knew substance to be, it is difficult 
 to conceive what answer he could have made. Again, he 
 had said that our idea of substance arises from our " ac- 
 customing ourselves to suppose" a substratum of qua- 
 lities. Upon this his adversary, Bishop Stillingfleet, very 
 properly asks, Is this custom grounded upon true reason 
 or no ? To which Locke replies, that it is grounded upon 
 this: That we cannot conceive how simple ideas of sensible 
 qualities should subsist alone ; and therefore we suppose 
 them to exist in, and to be supported by some common 
 subject, which support we denote by the name substance. 
 Thus he allows, not only that we necessarily assume the 
 reality of substance, but that we cannot conceive qualities 
 without substance; which are concessions so ample as 
 almost to include all that any advocate for the Idea of 
 Substance need desire. 
 
 Perhaps Locke, and the adherents of Locke, in deny- 
 ing that we have an idea of substance in general, were 
 latently influenced by finding that they could not, by any 
 effort of mind, call up any image which could be con- 
 sidered as an image of substance in general. That in 
 this sense we have no idea of substance, is plain enough ; 
 but in the same sense we have no idea of space in 
 general, or of time, or number, or cause, or resemblance. 
 
 * Essay, B. n. ch. ii., and First Letter to the Bishop of Worcester. 
 
IDEA OF SUBSTANCE. 409 
 
 Yet we certainly have such a power of representing to 
 our minds space, time, number, cause, resemblance, as to 
 arrive at numerous truths by means of such representa- 
 tions. These general representations I have all along 
 called Ideas, nor can I discover any more appropriate 
 word ; and in this sense, we have also, as has now been 
 shown, an Idea of Substance. 
 
 4. Is all Material Substance heavy f The principle 
 that the quantity of the substance of any body remains 
 unchanged by our operations upon it, is, as we have said, 
 of universal validity. But then the question occurs, how 
 are we to ascertain the quantity of substance, and thus, 
 to apply the principle in particular cases. In the case 
 above mentioned, where smoke was to be weighed, it 
 was manifestly assumed that the quantity of the sub- 
 stance might be known by its weight; and that the total 
 quantity being unchanged, the total weight also would 
 remain the same. Now on what grounds do we make 
 this assumption ? Is all material substance heavy? and 
 if we can assert this to be so, on what grounds does the 
 truth of the assertion rest? These are not idle questions 
 of barren curiosity; for in the history of that science 
 (Chemistry) to which the idea of substance is principally 
 applicable, nothing less than the fate of a comprehen- 
 sive and long established theory (the Phlogiston theory) 
 depended upon the decision of this question. When it 
 was urged that the reduction of a metal from a calcined 
 to a metallic form could not consist in the addition of 
 phlogiston, because the metal was lighter than the calx 
 had been; it was replied by some, that this was not con- 
 clusive, for that phlogiston was a principle of levity, 
 diminishing the weight of the body to which it was 
 added. This reply was, however, rejected by all the 
 sounder philosophers, and the force of the argument 
 finally acknowledged. But why was this suggestion of a 
 
410 PHILOSOPHY OF CHEMISTRY. 
 
 substance having no weight, or having absolute levity, 
 repudiated by the most reflective reasoners? It is as- 
 sumed, it appears, that all matter must be heavy ; what 
 is the ground of this assumption ? 
 
 The ground of such an assumption appears to be the 
 following. Our idea of substance includes in it this: 
 that substance is a quantity capable of addition ; and 
 thus capable of making up, by composition, a sum equal 
 to all its parts. But substance, and the quantity of sub- 
 stance, can be known to us only by its attributes and 
 qualities. And the qualities which are capable constantly 
 and indefinitely of increase and diminution by increase 
 and diminution of the parts, must be conceived insepa- 
 rable from the substance. For the qualities, if removable 
 from the substance at all, must be removable by some 
 operation performed upon the substance ; and by the 
 idea of substance, all such operations are only equivalent 
 to separation, junction, and union of parts. Hence those 
 characters which thus universally increase and diminish 
 by addition and subtraction of the things themselves, 
 belong to the substance of the things. They are mea- 
 sures of its quantity, and are not merely its separable 
 qualities. 
 
 The weight of bodies is such a character. However 
 we compound or divide bodies, we compound and divide 
 their weight in the same manner. We may dismember 
 a body into the minutest parts; but the sum of the 
 weights of the parts is always equal to the whole weight 
 of the body. The weight of a body can be in no way 
 increased or diminished, except by adding something to 
 it or taking something from it. If we bake a brick, we 
 do not conceive that the change of colour or of hardness, 
 implies that anything has been created or destroyed. It 
 may easily be that the parts have only assumed a new 
 arrangement ; but if the brick have lost weight, we sup- 
 
IDEA OF SUBSTANCE. 411 
 
 pose that something (moisture for instance) has been 
 removed elsewhere. 
 
 Thus weight is apprehended as essential to matter. 
 In considering the dismemberment or analysis of bodies, 
 we assume that there must be some criterion of the 
 quantity of substance ; and this criterion can possess no 
 other properties than their weight possesses. If we 
 assume an element which has no weight, or the weight 
 of which is negative, as some of the defenders of phlo- 
 giston attempted to do, we put an end to all speculation 
 on such subjects. For if weight is not the criterion of 
 the quantity of one element, phlogiston for instance, why 
 is weight the criterion of the quantity of any other ele- 
 ment ? We may, by the same right, assume any other 
 real or imaginary element to have levity instead of gra- 
 vity ; or to have a peculiar intensity of gravity which 
 makes its weight no index of its quantity. In short, if 
 we do this, we deprive of all possibility of application 
 our notions of element, analysis, and composition ; and 
 violate the postulates on which the questions are pro- 
 pounded which we thus attempt to decide. 
 
 We must, then, take a constant and quantitative pro- 
 perty of matter, such as weight is, to be an index of the 
 quantity of matter or of substance to which it belongs. 
 I do not here speak of the question which has some- 
 times been proposed, whether the weight or the inertia 
 of bodies be the more proper measure of the quantity 
 of matter. For the measure of inertia is regulated by 
 the same assumption as that of substance : that the 
 quantity of the whole must be equal to the quantity of 
 all the parts : and inertia is measured by weight, for the 
 same reason that substance is so. 
 
 Having thus established the certainty, and ascer- 
 tained the interpretation of the fundamental principle 
 which the Idea of Substance involves, we are prepared 
 
412 PHILOSOPHY OF CHEMISTRY. 
 
 to consider its application in the science upon which it 
 has a peculiar bearing. 
 
 CHAPTER IV 
 
 APPLICATION OF THE IDEA OF SUBSTANCE IN 
 CHEMISTRY. 
 
 1. A Body is Equal to the Sum of its Elements. 
 FROM the earliest periods of chemistry the balance has 
 been familiarly used to determine the proportions of the 
 ingredients and of the compound ; and soon after the 
 middle of the last century, this practice was so studiously 
 followed, that Wenzel and Richter were thereby led to 
 the doctrine of Definite Proportions. But yet the full 
 value and significance of the balance, as an indispensable 
 instrument in chemical researches, was not understood 
 till the gaseous, as well as solid and fluid ingredients 
 were taken into the account. When this was done, it 
 was found that the principle, that the whole is equal to 
 the sum of its parts, of which, as we have seen, the 
 necessary truth, in such cases, flows from the idea of 
 substance, could be applied in the most rigorous manner. 
 And conversely, it was found that by the use of the 
 balance, the chemist could decide, in doubtful cases, 
 which was a whole, and which were parts. 
 
 For chemistry considers all the changes which belong 
 to her province as compositions and decompositions of 
 elements ; but still the question may occur, whether an 
 observed change be the one or the other. How can we 
 distinguish whether the process which we contemplate 
 be composition or decomposition? whether the new 
 body be formed by addition of a new, or subtraction of 
 an old element ? Again ; in the case of decomposition, 
 we may inquire, What are the ultimate limits of our 
 
APPLICATION OF THE IDEA OF SUBSTANCE. 413 
 
 analysis? If we decompound bodies into others more 
 and more simple, how far can we carry this succession 
 of processes ? How far can we proceed in the road of 
 analysis ? And in our actual course, what evidence have 
 we that our progress, as far as it has gone, has carried 
 us from the more complex to the more simple ? 
 
 To this we reply, that the criterion which enables us 
 to distinguish, decidedly and finally, whether our pro- 
 cess have been a mere analysis of the proposed body 
 into its ingredients, or a synthesis of some of them with 
 some new element, is the principle stated above, that 
 the weight of the whole is equal to the weight of 
 all the parts. And no process of chemical analysis or 
 synthesis can be considered complete till it has been 
 verified by this fact ; by finding that the weight of the 
 compound is the weight of its supposed ingredients ; or, 
 that if there be an element which we think we have 
 detached from the whole, its loss is betrayed by a cor- 
 responding diminution of weight. 
 
 I have already noticed what an important part this 
 principle has played in the great chemical controversy 
 which ended in the establishment of the oxygen theory. 
 The calcination of a metal was decided to be the union 
 of oxygen with the metal, and not the separation of 
 phlogiston from it, because it was found that in the pro- 
 cess of calcination, the weight of the metal increased, 
 and increased exactly as much as the weight of ambient 
 air diminished. When oxygen and hydrogen were ex- 
 ploded together, and a small quantity of water was pro- 
 duced, it was held that this was really a synthesis of 
 water, because, when very great care was taken with the 
 process, the weight of the water which resulted was 
 equal to the weight of the gases which disappeared. 
 
 2. Lavoisier. It was when gases came to be con- 
 sidered as entering largely into the composition of liquid 
 
414 PHILOSOPHY OF CHEMISTRY. 
 
 and solid bodies, that extreme accuracy in weighing was 
 seen to be so necessary to the true understanding of 
 chemical processes. It was in this manner discovered 
 by Lavoisier and his contemporaries that oxygen con- 
 stitutes a large ingredient of calcined metals, of acids, 
 and of water. A countryman of Lavoisier* has not only 
 given most just praise to that great philosopher for 
 having constantly tested all his processes by a careful 
 and skilful use of the balance, but has also claimed for 
 him the merit of having introduced the maxim, that in 
 chemical operations nothing is created and nothing lost. 
 But I think it is impossible to deny that this maxim is 
 assumed in all the attempts at analysis made by his 
 contemporaries, as well as by him. This maxim is indeed 
 included in any clear notion of analysis : it could not be 
 the result of the researches of any one chemist, but was 
 the governing principle of the reasonings of all. Lavoisier, 
 however, employed this principle with peculiar assiduity 
 and skill. In applying it, he does not confine himself to 
 mere additions and subtractions of the quantities of ingre- 
 dients ; but often obtains his results by more complex 
 processes. In one of his investigations he says, " I may 
 consider the ingredients which are brought together, and 
 the result which is obtained as an algebrical equation ; 
 and if I successively suppose each of the quantities of 
 this equation to be unknown, I can obtain its value 
 from the rest : and thus I can rectify the experiment by 
 the calculation, and the calculation by the experiment. 
 I have often taken advantage of this method, in order 
 to correct the first results of my experiments, and to 
 direct me in repeating them with proper precautions." 
 
 The maxim, that the whole is equal to the sum of all 
 its parts, is thus capable of most important and varied 
 employment in chemistry. But it may be applied in 
 
 * M. Dumas, Leconx de la Philosophic Chimique. 1837- p- 157- 
 
APPLICATION OF THE IDEA OF SUBSTANCE. 415 
 
 another form to the exclusion of a class of speculations 
 which are often put forwards. 
 
 3. Maxim respecting Imponderable Elements. 
 Several of the phenomena which belong to bodies, as 
 heat, light, electricity, magnetism, have been explained 
 hypothetically by assuming the existence of certain 
 fluids ; but these fluids have never been shown to have 
 weight. Hence such hypothetical fluids have been termed 
 imponderable elements. It is however plain, that so long 
 as these fluids appear to be without weight, they are 
 not elements of bodies in the same sense as those ele- 
 ments of which we have hitherto been speaking. Indeed 
 we may with good reason doubt whether those pheno- 
 mena depend upon transferable fluids at all. We have 
 seen strong reason to believe that light is not matter, but 
 only motion ; and the same thing appears to be probable 
 with regard to heat. Nor is it at all inconceivable that 
 a similar hypothesis respecting electricity and magnetism 
 should hereafter be found tenable. Now if heat, light, 
 and those other agents, be not matter, they are not 
 elements in such a sense as to be included in the prin- 
 ciple referred to above, That the body is equal to the 
 sum of its elements. Consequently the maxim just 
 stated, that in chemical operations nothing is created, 
 nothing annihilated, does not apply to light and heat. 
 They are not things. And whether heat can be pro- 
 duced where there was no heat before, and light struck 
 out from darkness, the ideas of which we are at present 
 treating do not enable us to say. In reasoning respect- 
 ing chemical synthesis and analysis therefore, we shall 
 only make confusion by attempting to include in our 
 conception the light and heat which are produced and 
 destroyed. Such phenomena may be very proper sub- 
 jects of study, as indeed they undoubtedly are; but 
 they cannot be studied to advantage by considering 
 
416 PHILOSOPHY OF CHEMISTRY. 
 
 them as sharing the nature of composition and decom- 
 position. 
 
 Again : in all attempts to explain the processes of 
 nature, the proper course is, first to measure the facts 
 with precision, and then to endeavour to understand 
 their cause. Now the facts of chemical composition and 
 decomposition, the weights of the ingredients and of the 
 compounds, are facts measurable with the utmost pre- 
 cision and certainty. But it is far otherwise with the 
 light and heat which accompany chemical processes. 
 When combustion, deflagration, explosion, takes place, 
 how can we measure the light or the heat? Even in 
 cases of more tranquil action, though we can apply the 
 thermometer, what does the thermometer tell us respect- 
 ing the quantity of the heat ? Since then we have no 
 measure which is of any value as regards such circum- 
 stances in chemical changes, if we attempt to account 
 for these phenomena on chemical principles, we intro- 
 duce, into investigations in themselves perfectly precise 
 and mathematically rigorous, another class of reasonings, 
 vague and insecure, of which the only possible effect is 
 to vitiate the whole reasoning, and to make our conclu- 
 sions inevitably erroneous. 
 
 We are led then to this maxim : that imponderable 
 fluids are not to be admitted as chemical elements of 
 bodies*. 
 
 4. It appears, I think, that our best and most philo- 
 
 * Since we are thus warned by a sound view of the nature of 
 science, from considering chemical affinity as having any hold upon 
 imponderable elements, we are manifestly still more decisively prohi- 
 bited from supposing mechanical impulse or pressure to have any 
 effect upon such elements. To make this supposition, is to connect the 
 most subtle and incorporeal objects which we know in nature by the 
 most gross material ties. This remark seems to be applicable to M. 
 Poisson's hypothesis that the electric fluid is retained at the surface of 
 bodies by the pressure of the atmosphere. 
 
APPLICATION OF THE IDEA OF SUBSTANCE. 417 
 
 sophical chemists have proceeded upon this principle in 
 their investigations. In reasoning concerning the con- 
 stitution of bodies and the interpretation of chemical 
 changes, the attempts to include in these interpretations 
 the heat or cold produced, by the addition or subtraction 
 of a certain hypothetical "caloric," have become more 
 and more rare among men of science. Such statements, 
 and the explanations often put forwards of the light and 
 heat which appear under various circumstances in the 
 form of fire, must be considered as unessential parts of 
 any sound theory. Accordingly we find Mr. Faraday 
 gradually relinquishing such views. In January, 1834, 
 he speaks generally of an hypothesis of this kind*. " I 
 cannot refrain from recalling here the beautiful idea put 
 forth, I believe by Berzelius, in his developement of his 
 views of the electro-chemical theory of affinity, that the 
 heat and light evolved during cases of powerful combi- 
 nation are the consequence of the electric discharge 
 which is at that moment taking place." But in April 
 of the same yearf, he observes, that in the combination 
 of oxygen and hydrogen to produce water, electric 
 powers to a most enormous amount are for the time 
 active, but that the flame which is produced gives but 
 feeble traces of such powers. " Such phenomena," 
 therefore, he adds, "may not, cannot, be taken as evi- 
 dences of the nature of the action ; but are merely inci- 
 dental results, incomparably small in relation to the 
 forces concerned, and supplying no information of the 
 way in which the particles are active on each other, or 
 in which their forces are finally arranged." 
 
 In pursuance of this maxim, we must consider as an 
 unessential part of the oxygen theory that portion of it, 
 much insisted upon by its author at the time, in which 
 when sulphur, for instance, combined with oxygen to 
 
 * Researches, 870. t Ib. 960. 
 
 VOL. I. W. P. E E 
 
418 PHILOSOPHY OF CHEMISTRY. 
 
 produce sulphuric acid, the combustion was accounted 
 for by means of the caloric which was supposed to be 
 liberated from its combination with oxygen. 
 
 5. Controversy of the Composition of Water. There 
 is another controversy of our times to which we may 
 with great propriety apply the maxim now before us. 
 After the glory of having first given a true view of the 
 composition of water had long rested tranquilly upon 
 the names of Cavendish and Lavoisier, a claim was 
 made in favour of James Watt as the real author of this 
 discovery by his son, (Mr. J. Watt,) and his eulogist, 
 (M. Arago"*.) It is not to our purpose here to discuss 
 the various questions which have arisen on this subject 
 respecting priority of publication, and respecting the 
 translation of opinions published at one time into the 
 language of another period. But if we look at Watt's 
 own statement of his views, given soon after those of 
 Cavendish had been published, we shall perceive that 
 it is marked by a violation of this maxim : we shall 
 find that he does admit imponderable fluids as chemical 
 elements ; and thus shows a vagueness and confusion in 
 his idea of chemical composition. With such imperfec- 
 tion in his views, it is not surprizing that Watt, not only 
 did not anticipate, but did not apprehend quite precisely 
 the discovery of Cavendish and Lavoisier. Watt's state- 
 ment of his views is as folio ws f : "Are we not autho- 
 rized to conclude that water is composed of dephlogisti- 
 cated air and phlogiston deprived of part of their latent 
 or elementary heat ; that dephlogisticated or pure air 
 is composed of water deprived of its phlogiston and 
 united to elementary heat and light ; and that the latter 
 are contained in it in a latent state, so as not to be sen- 
 sible to the thermometer or to the eye ; and if light be 
 
 * Eloge dc James Watt, Annuaire du Bur. des Long., 1839. 
 t Phil. Trans., 1784, p. 332. 
 
APPLICATION OF THE IDEA OF SUBSTANCE. 419 
 
 only a modification of heat, or a circumstance attending 
 it, or a component part of the inflammable air, then 
 pure or dephlogisticated air is composed of water de- 
 prived of its phlogiston and united to elementary heat ?" 
 
 When we compare this doubtful and hypothetical 
 statement, involving so much that is extraneous and 
 heterogeneous, with the conclusion of Cavendish, in 
 which there is nothing hypothetical or superfluous, we 
 may confidently assent to the decision which has been 
 pronounced by one * of our own time in favour of Caven- 
 dish, And we may with pleasure recognize, in this 
 enlightened umpire, a due appreciation of the value of 
 the maxim on which we are now insisting. " Cavendish," 
 says Mr. Vernon Harcourt, "pared off from the hypo- 
 theses their theories of combustion, and affinities of 
 imponderable for ponderable matter, as complicating 
 chemical with physical considerations." 
 
 6. Relation of Heat to Chemistry. But while we 
 thus condemn the attempts to explain the thermotical 
 phenomena of chemical processes by means of che- 
 mical considerations, it may be asked if we are alto- 
 gether to renounce the hope of understanding such 
 phenomena ? It is plain, it may be said, that heat gene- 
 rated in chemical changes is always a very important 
 
 * The Rev. W. Vernon Harcourt, Address to the British Asso- 
 ciation, 1839. Since the first edition of this work was published, and 
 also since the second edition of the History of the Inductive Sciences, 
 Mr. Watt's correspondence bearing upon the question of the Compo- 
 sition of Water has been published by Mr. Muirhead. I do not 
 find, in this publication, any reason for withdrawing what I have 
 stated in the text above : but with reference to the statement in the 
 History, it appears that Mr. Cavendish's claim to the discovery was 
 not uncontested in his own time. Mr. Watt had looked at the com- 
 position of water, as a problem to be solved, perhaps more distinctly 
 than Mr. Cavendish had done ; and he conceived himself wronged by 
 Mr. Cavendish's putting forwards his experiment as the first solution 
 of this problem. 
 
 E E 2 
 
420 PHILOSOPHY OF CHEMISTRY. 
 
 circumstance, and can sometimes be measured, and per- 
 haps reduced to laws ; are we prohibited from speculat- 
 ing concerning the causes of such circumstances and 
 such laws ? And to this we reply, that we may properly 
 attempt to connect chemical with thermotical processes, 
 so far as we have obtained a clear and probable view of 
 the nature of the thermotical processes. When our 
 theory of Thermotics is tolerably complete and certain, 
 we may with propriety undertake to connect it with our 
 theory of Chemistry. But at present we are not far 
 enough advanced in our knowledge of heat to make this 
 attempt with any hope of success. We can hardly 
 expect to understand the part which heat plays in the 
 union of two bodies, when we cannot as yet compre- 
 hend in what manner it produces the liquefaction or 
 vaporization of one body. We cannot look to account 
 for Gay Lussac and Dalton's Law, that all gases expand 
 equally by heat, till we learn how heat causes a gas to 
 expand. We cannot hope to see the grounds of Dulong 
 and Petit' s Law, that the specific heat of all atoms is 
 the same, till we know much more, not only about atoms, 
 but about specific heat. We have as yet no thermotical 
 theory which even professes to account for all the pro- 
 minent facts of the subject*: and the theories which 
 have been proposed are of the most diverse kind. 
 Laplace assumes particles of bodies surrounded by 
 atmospheres of caloric f ; Cauchy makes heat consist in 
 longitudinal vibrations of the ether of which transverse 
 vibrations produce light : in Ampere's theory J, heat 
 consists in the vibrations of the particles of bodies. 
 And so long as we have nothing more certain in our 
 conceptions of heat than the alternative of these and 
 other precarious hypotheses, how can we expect to arrive 
 at any real knowledge, by connecting the results of sucli 
 * Hist. Ind. Sci., B. x. c. 4, t Ib. $ It,. 
 
THE ATOMIC THEORY. 421 
 
 hypotheses with the speculations of Chemistry, of which 
 science the theory is at least equally obscure ? 
 
 The largest attempts at chemical theory have been 
 made in the form of the Atomic Theory, to which I have 
 just had occasion to allude. I must, therefore, before 
 quitting the subject, say a few words respecting this 
 theory. 
 
 CHAPTER V. 
 THE ATOMIC THEORY. 
 
 1. The Atomic Theory considered on Chemical 
 Grounds. WE have already seen that the combinations 
 which result from chemical affinity are definite, a certain 
 quantity of one ingredient uniting, not with an uncer- 
 tain, but with a certain quantity of another ingredient. 
 But it was found, in addition to this principle, that one 
 ingredient would often unite with another in different 
 proportions, and that, in such cases, these proportions 
 are multiples one of another. In the three salts formed 
 by potassa with oxalic acid, the quantities of acid which 
 combine with the same quantity of alkali are exactly in 
 the proportion of the numbers 1, 2, 4. And the same 
 rule of the existence of multiple proportions is found to 
 obtain in other cases. 
 
 It is obvious that such results will be accounted for, 
 if we suppose the base and the acid to consist each of 
 definite equal particles, and that the formation of the 
 salts above mentioned consists in the combination of one 
 particle of the base with one particle of acid, with two 
 particles of acid, and with four particles of acid, respec- 
 tively. But further ; as we have already stated, chemi- 
 cal affinity is not only definite, but reciprocal. The pro- 
 
422 PHILOSOPHY OF CHEMISTRY. 
 
 portions of potassa and soda which form neutral salts 
 being 590 and 391 in one case, they are so in all cases. 
 These numbers represent the proportions of weight in 
 which the two bases, potassa and soda, enter into ana- 
 logous combinations ; 590 of potassa is equivalent to 
 391 of soda. These facts with regard to combination 
 are still expressed by the above supposition of equal 
 particles, assuming that the weights of a particle of 
 potassa and of soda are in the proportion of 590 to 391. 
 
 But we pursue our analysis further. We find that 
 potassa is a compound of a metallic base, potassium, 
 and of oxygen, in the proportion of 490 to 100 ; we 
 suppose, then, that the particle of potassa consists of a 
 particle of potassium and a particle of oxygen, arid these 
 latter particles, since we see no present need to suppose 
 them divided, potassium and oxygen being simple bodies, 
 we may call atoms, and assume to be indivisible. And 
 by supposing all simple bodies to consist of such atoms, 
 and compounds to be formed by the union of two, or 
 three, or more of such atoms, we explain the occurrence 
 of definite and multiple proportions, and we construct 
 the Atomic Theory. 
 
 2. Hypothesis of Atoms. So far as the assumption 
 of such atoms as we have spoken of serves to express 
 those laws of chemical composition which we have 
 referred to, it is a clear and useful generalization. But 
 if the Atomic Theory be put forwards (and its author, 
 Dr. Dalton, appears to have put it forwards with such 
 an intention,) as asserting that chemical elements are 
 really composed of atoms, that is, of such particles not 
 further divisible, we cannot avoid remarking, that for 
 such a conclusion, chemical research has not afforded, 
 nor can afford, any satisfactory evidence whatever. The 
 smallest observable quantities of ingredients, as well as 
 the largest, combine according to the laws of proportions 
 
THE ATOMIC THEORY. 423 
 
 and equivalence which have been cited above. How 
 are we to deduce from such facts any inference with 
 regard to the existence of certain smallest possible par- 
 ticles? The Theory, when dogmatically taught as a 
 physical truth, asserts that all observable quantities of 
 elements are composed of proportional numbers of par- 
 ticles which can no further be subdivided ; but all which 
 observation teaches us is, that if there be such particles, 
 they are smaller than the smallest observable quantities. 
 In chemical experiment, at least, there is not the slight- 
 est positive evidence for the existence of such atoms. 
 The assumption of indivisible particles, smaller than the 
 smallest observable, which combine, particle with par- 
 ticle, will explain the phenomena; but the assumption 
 of particles bearing this proportion, but not possessing 
 the property of indivisibility, will explain the phenomena 
 at least equally well. The decision of the question, 
 therefore, whether the Atomic Hypothesis be the proper 
 way of conceiving the chemical combinations* of sub- 
 stances, must depend, not upon chemical facts, but upon 
 our conception of substance. In this sense the question 
 is an ancient and curious controversy, and we shall here- 
 after have to make some remarks upon it. 
 
 3. Chemical Difficulties of the Hypothesis. But 
 before doing this, we may observe that there is no 
 small difficulty in reconciling this hypothesis with the 
 facts of chemistry. According to the theory, all salts, 
 compounded of an acid and a base, are analogous in their 
 atomic constitution ; and the number of atoms in one 
 such compound being known or assumed, the number of 
 atoms in other salts may be determined, But when we 
 proceed in this course of reasoning to other bodies, as 
 metals, we find ourselves involved in difficulties. The 
 protoxide of iron is a base which, according to all ana- 
 logy, must consist of one atom of iron and one of oxygen : 
 
424 PHILOSOPHY OF CHEMISTRY. 
 
 but the peroxide of iron is also a base, and it appears by 
 the analysis of this substance that it must consist of two- 
 thirds of an atom of iron and one atom of oxygen. 
 Here, then, our indivisible atoms must be divisible, even 
 upon chemical grounds. And if we attempt to evade 
 this difficulty by making the peroxide of iron consist of 
 two atoms of iron and three of oxygen, we have to make 
 a corresponding alteration in the theoretical constitution 
 of all bodies analogous to the protoxide ; and thus we 
 overturn the very foundation of the theory. Chemical 
 facts, therefore, not only do not prove the Atomic Theory 
 as a physical truth, but they are not, according to any 
 modification yet devised of the theory, reconcileable with 
 its scheme. 
 
 Nearly the same conclusions result from the attempts 
 to employ the Atomic Hypothesis in expressing another 
 important chemical law ; the law of the combinations of 
 gases according to definite proportions of their volumes, 
 experimentally established by Gay Lussac*. In order 
 to account for this law, it has been very plausibly sug- 
 gested that all gases, under the same pressure, contain 
 an equal number of atoms in the same space ; and that 
 when they combine, they unite atom to atom. Thus one 
 volume of chlorine unites with one volume of hydrogen, 
 and form hydrochloric acidf. But then this hydro- 
 chloric acid occupies the space of the two volumes ; and 
 therefore the proper number of particles cannot be sup- 
 plied, and the uniform distribution of atoms in all gases 
 maintained, without dividing into two each of the com- 
 pound particles, constituted of an atom of chlorine and 
 an atom of hydrogen. And thus in this case, also, the 
 Atomic Theory becomes untenable if it be understood to 
 imply the indivisibility of the atoms. 
 
 In all these attempts to obtain a distinct physical 
 
 * Hist. Ind. Sc. 9 B. xiv. c. 8. t Dumas, Phil. Chim. 263. 
 
THE ATOMIC THEORY. 425 
 
 conception of chemical union by the aid of the Atomic 
 Hypothesis, the atoms are conceived to be associated by 
 certain forces of the nature of mechanical attractions. 
 But we have already seen* that no such mode of con- 
 ception can at all explain or express the facts of che- 
 mical combination ; and therefore it is not wonderful that 
 when the Atomic Theory attempts to give an account of 
 chemical relations by contemplating them under such 
 an aspect, the facts on which it grounds itself should be 
 found not to authorize its positive doctrines ; and that 
 when these doctrines are tried upon the general range 
 of chemical observation, they should prove incapable of 
 even expressing, without self-contradiction, the laws of 
 phenomena. 
 
 4. Grounds of the Atomic Doctrine. Yet the doc- 
 trine of atoms, or of substance as composed of indivisible 
 particles, has in all ages had great hold upon the minds 
 of physical speculators; nor would this doctrine ever 
 have suggested itself so readily, or have been maintained 
 so tenaciously, as the true mode of conceiving chemical 
 combinations, if it had not been already familiar to the 
 minds of those who endeavour to obtain a general view 
 of the constitution of nature. The grounds of the assump- 
 tion of the atomic structure of substance are to be found 
 rather in the idea of substance itself, than in the experi- 
 mental laws of chemical affinity. And the question of 
 the existence of atoms, thus depending upon an idea 
 which has been the subject of contemplation from the 
 very infancy of philosophy, has been discussed in all ages 
 with interest and ingenuity. On this very account it is 
 unlikely that the question, so far as it bears upon che- 
 mistry, should admit of any clear and final solution. Still 
 it will be instructive to look back at some of the opinions 
 which have been delivered respecting this doctrine. 
 
 * See Chapter I. of this Book. 
 
426 PHILOSOPHY OF CHEMISTRY. 
 
 5. Ancient Prevalence of the Atomic Doctrine. The 
 doctrine that matter consists of minute, simple, indivisible, 
 indestructible particles as its ultimate elements, has been 
 current in all ages and countries, whenever the tendency 
 of man to wide and subtle speculations has been active. 
 I need not attempt to trace the history of this opinion 
 in the schools of Greece and Italy. It was the leading 
 feature in the physical tenets of the Epicureans, and was 
 adopted by their Roman disciples, as the poem of Lucre- 
 tius copiously shows us. The same tenet had been held 
 at still earlier periods, in forms more or less definite, by 
 other philosophers. It is ascribed to Democritus, and is 
 said to have been by him derived from Leucippus. But 
 this doctrine is found also, we are told*, among the 
 speculations of another intellectual and acute race, the 
 Hindoos. According to some of their philosophical 
 writers, the ultimate elements of matter are atoms, of 
 which it is proved by certain reasonings, that they are 
 each one-sixth of one of the motes that float in the 
 sunbeam. 
 
 This early prevalence of controversies of the widest 
 and deepest kind, which even in our day remain unde- 
 cided, has in it nothing which need surprize us ; or, at 
 least, it has in it nothing which is not in conformity with 
 the general course of the history of philosophy. As soon 
 as any ideas are clearly possessed by the human mind, its 
 activity and acuteness in reasoning upon them are such, 
 that the fundamental antitheses and ultimate difficul- 
 ties which belong to them are soon brought into view. 
 The Greek and Indian philosophers had mastered com- 
 pletely the Idea of Space, and possessed the Idea of 
 Substance in tolerable distinctness. They were, therefore, 
 quite ready, with their lively and subtle minds, to discuss 
 the question of the finite and infinite divisibility of matter, 
 * By Mr. Colebrook. Asiatic Res. 1824. 
 
THE ATOMIC THEORY. 427 
 
 so far as it involved only the ideas of space and of sub- 
 stance, and this accordingly they did with great ingenuity 
 and perseverance. 
 
 But the ideas of Space and of Substance are far from 
 being sufficient to enable men to form a complete general 
 view of the constitution of matter. We must add to 
 these ideas, that of mechanical Force with its antagonist 
 Resistance, and that of the Affinity of one kind of matter 
 for another. Now the former of these ideas the ancients 
 possessed in a very obscure and confused manner ; and 
 of the latter they had no apprehension whatever. They 
 made vague assumptions respecting the impact and pres- 
 sure of atoms on each other ; but of their mutual attrac- 
 tion and repulsion they never had any conception, except 
 of the most dim and wavering kind ; and of an affinity 
 different from mere local union they did not even dream. 
 Their speculations concerning atoms, therefore, can have 
 no value for us, except as a part of the history of science. 
 If their doctrines appear to us to approach near to the 
 conclusions of our modern philosophy, it must be because 
 our modern philosophy is that philosophy which has not 
 fully profited by the additional light which the experi- 
 ments and meditations of later times have thrown upon 
 the constitution of matter. 
 
 6. Bacon. Still, when modern philosophers look 
 upon the Atomic Theory of the ancients in a general point 
 of view merely, without considering the special conditions 
 which such a theory must fulfil, in order to represent the 
 discoveries of modern times, they are disposed to regard 
 it with admiration. Accordingly we find Francis Bacon 
 strongly expressing such a feeling. The Atomic Theory 
 is selected and dwelt upon by him as the chain which 
 connects the best parts of the physical philosophy of the 
 ancient and the modern world. Among his works is a 
 remarkable dissertation On the Philosophy of Democri- 
 
428 PHILOSOPHY OF CHEMISTRY. 
 
 tus, Parmenides, and Telesius: the last mentioned of 
 whom was one of the revivers of physical science in 
 modern times. In this work he speaks of the atomic 
 doctrine of Democritus as a favourable example of the 
 exertions of the undisciplined intellect. "Hsec ipsa 
 placita, quamvis paulo emendatiora, talia sunt qualia 
 esse possunt ilia quse ab intellectu sibi permisso, nee 
 continenter et gradatim sublevato, profecta videntur." 
 " These doctrines, thus [in an ancient fable] presented in 
 a better form, are such glimpses of truth as can be ob- 
 tained by the intellect left to its own natural impulses, 
 and not ascending by successive and connected steps," 
 [as the Baconian philosophy directs.] " Accordingly," 
 he adds, " the doctrine of Atoms, from its going a step 
 beyond the period in which it was advanced, was ridi- 
 culed by the vulgar, and severely handled in the dispu- 
 tations of the learned, notwithstanding the profound 
 acquaintance with physical science by which its author 
 was allowed to be distinguished, and from which he 
 acquired the character of a magician." 
 
 " However," he continues, " neither the hostility of 
 Aristotle, with all his skill and vigour in disputation, 
 (though, like the Ottoman sultans, he laboured to destroy 
 all his brother philosophers that he might rest undis- 
 puted master of the throne of science,) nor the majestic 
 and lofty authority of Plato, could effect the subversion 
 of the doctrine of Democritus. And while the opinions 
 of Plato and Aristotle were rehearsed with loud decla- 
 mation and professorial pomp in the schools, this of 
 Democritus was always held in high honour by those of 
 a deeper wisdom, who followed in silence a severer path 
 of contemplation. In the days of Roman speculation it 
 kept its ground and its favour ; Cicero everywhere speaks 
 of its author with the greatest praise ; and Juvenal, who, 
 like poets in general, probably expressed the prevailing 
 
THE ATOMIC THEORY. 429 
 
 judgment of his time, proclaims his merit as a noble 
 exception to the general stupidity of his countrymen. 
 
 . . . . Cujus prudentia monstrat 
 
 Magnos posse viros et magna exempla daturos 
 
 Vervecum in patria crassoque sub aere nasci. 
 
 " The destruction of this philosophy was not effected 
 by Aristotle and Plato, but by Genseric and Attila, and 
 their barbarians. For then, when human knowledge had 
 suffered shipwreck, those fragments of the Aristotelian 
 and Platonic philosophy floated on the surface like things 
 of some lighter and emptier sort, and so were preserved ; 
 while more solid matters went to the bottom, and were 
 almost lost in oblivion." 
 
 7. Modern Prevalence of the Atomic Doctrine. It is 
 our business here to consider the doctrine of Atoms only 
 in its bearing upon existing physical sciences, and I must 
 therefore abstain from tracing the various manifestations 
 of it in the schemes of hypothetical cosmologists ; its 
 place among the vortices of Descartes, its exhibition in 
 the monads of Leibnitz. I will, however, quote a pas- 
 sage from Newton to show the hold it had upon his 
 mind. 
 
 At the close of his Opticks he says, "All these 
 things being considered, it seems probable to me that 
 God, in the beginning, formed matter in solid, massy, 
 hard, impenetrable, moveable particles, of such sizes and 
 figures, and with such other properties, and in such pro- 
 portions to space, as most conduced to the end for which 
 He formed them; and that these primitive particles, 
 being solids, are incomparably harder than any porous 
 bodies compounded of them, even so very hard as never 
 to wear or break in pieces ; no ordinary power being able 
 to divide what God had made one in the first creation. 
 While the particles continue entire, they may compose 
 
430 PHILOSOPHY OF CHEMISTRY. 
 
 bodies of one and the same nature and texture in all 
 ages : but should they wear away or break in pieces, the 
 nature of things depending on them would be changed. 
 Water and earth composed of old worn particles and 
 fragments of particles would not be of the same nature 
 and texture now with water and earth composed of entire 
 particles in the beginning. And therefore that nature 
 may be lasting, the changes of corporeal things are to be 
 placed only in the various separations and new associa- 
 tions and motions of these permanent particles ; com- 
 pounded bodies being apt to break, not in the midst of 
 solid particles, but where those particles are laid together 
 and only touch in a few points." 
 
 We shall hereafter see how extensively the atomic 
 doctrine has prevailed among still more recent philoso- 
 phers. Not only have the chemists assumed it as the 
 fittest form for exhibiting the principles of multiple pro- 
 portions; but the physical mathematicians, as Laplace 
 and Poisson, have made it the basis of their theories 
 of heat, electricity, capillary action; and the crystal- 
 lographers have been supposed to have established both 
 the existence and the arrangement of such ultimate 
 molecules. 
 
 In the way in which it has been employed by such 
 writers, the hypothesis of ultimate particles has been of 
 great use, and is undoubtedly permissible. But when we 
 would assert this theory, not as a convenient hypothesis 
 for the expression or calculation of the laws of nature, 
 but as a philosophical truth respecting the constitution 
 of the universe, we find ourselves checked by difficulties 
 of reasoning which we cannot overcome, as well as by 
 conflicting phenomena which we cannot reconcile. I 
 will attempt to state briefly the opposing arguments on 
 this question. 
 
THE ATOMIC THEORY. 431 
 
 8. Arguments for and against Atoms. The leading 
 arguments on the two sides of the question, in their most 
 general form, may be stated as follows : 
 
 For the Atomic Doctrine. The appearances which 
 nature presents are compounded of many parts, but if we 
 go on resolving the larger parts into smaller, and so on 
 successively, we must at last come to something simple. 
 For that which is compound can be so no otherwise than 
 by composition of what is simple ; and if we suppose all 
 composition to be removed, which hypothetically we may 
 do, there can remain nothing but a number of simple 
 substances, capable of composition, but themselves not 
 compounded. That is, matter being dissolved, resolves 
 itself into atoms. 
 
 Against the Atomic Doctrine. Space is divisible 
 without limit, as may be proved by geometry; and matter 
 occupies space, therefore matter is divisible without limit, 
 and no portion of matter is indivisible, or an atom. 
 
 And to the argument on the other side just stated, it 
 is replied that we cannot even hypothetically divest a 
 body of composition, if by composition we mean the 
 relation of point to point in space. However small be 
 a particle, it is compounded of parts having relation in 
 space. 
 
 The Atomists urge again, that if matter be infinitely 
 divisible, a finite body consists of an infinite number of 
 parts, which is a contradiction. To this it is replied, 
 that the finite body consists of an infinite number of 
 parts in the same sense in which the parts are infinitely 
 small, which is no contradiction. 
 
 But the opponents of the Atomists not only rebut, 
 but retort this argument drawn from the notion of 
 infinity. Your atoms, they say, are indivisible by any 
 finite force ; therefore they are infinitely hard ; and thus 
 your finite particles possess infinite properties. To this 
 
432 PHILOSOPHY OF CHEMISTRY. 
 
 the Atomists are wont to reply, that they do not mean 
 the hardness of their particles to be infinite, but only so 
 great as to resist all usual natural forces. But here it is 
 plain that their position becomes untenable; for, in the 
 first place, their assumption of this precise degree of 
 hardness in the particles is altogether gratuitous; and in 
 the next place, if it were granted, such particles are not 
 atoms, since in the next moment the forces of nature 
 may be augmented so as to divide the particle, though 
 hitherto undivided. 
 
 Such are the arguments for and against the Atomic 
 Theory in its original form. But when these atoms are 
 conceived, as they have been by Newton, and commonly 
 by his followers, to be solid, hard particles exerting 
 attractive and repulsive forces, a new set of arguments 
 come into play. Of these, the principal one may be thus 
 stated : According to the Atomic Theory thus modified, 
 the properties of bodies depend upon the attractions and 
 repulsions of the particles. Therefore, among other 
 properties of bodies, their hardness depends upon such 
 forces. But if the hardness of the bodies depends upon 
 the forces, the repulsion, for instance, of the particles, 
 upon what does the hardness of the particles depend ? 
 what progress do we make in explaining the properties 
 of bodies, when we assume the same properties in our 
 explanation? and to what purpose do we assume that 
 the particles are hard ? 
 
 9. Transition to Boscovictis Theory. To this diffi- 
 culty it does not appear easy to offer any reply. But 
 if the hardness and solidity of the particles be given 
 up as an incongruous and untenable appendage to the 
 Newtonian view of the Atomic Theory, we are led to 
 the theory of Boscovich, according to which matter 
 consists not of solid particles, but of mere mathematical 
 centers of force. According to this theory, each body is 
 
THE ATOMIC THEORY. 433 
 
 composed of a number of geometrical points from which 
 emanate forces, following certain mathematical laws in 
 virtue of which the forces become, at certain small dis- 
 tances attractive, at certain other distances repulsive, 
 and at greater distances attractive again. From these 
 forces of the points arise the cohesion of the parts of 
 the same body, the resistance which it exerts against the 
 pressure of another body, and finally the attraction of 
 gravitation which it exerts upon bodies at a distance. 
 
 This theory is at least a homogenous and consistent 
 theory, and it is probable that it may be used as an 
 instrument for investigating and expressing true laws of 
 nature ; although, as we have already said, the attempt 
 to identify the forces by which the particles of bodies 
 are bound together with mechanical attraction appears 
 to be a confusion of two separate ideas *. 
 
 10. Use of the Molecular Hypothesis. In this form, 
 representing matter as a collection of molecules or 
 centers of force, the Atomic Theory has been abundantly 
 employed in modern times as an hypothesis on which 
 calculations respecting the elementary forces of bodies 
 might be conducted. When thus employed, it is to be 
 considered as expressing the principle that the pro- 
 perties of bodies depend upon forces emanating from 
 
 * " Boscovich's Theory," that all bodies may be considered as con- 
 sisting of a mere collection of centers of forces, may be so conceived as 
 possibly to involve an explanation of all the powers which their parts 
 exert, (such powers, namely, as those which produce optical, thermo- 
 tical, and chemical phenomena ;) but this theory cannot supply an 
 explanation of the mechanical properties of a body as a whole, especially 
 of its inertia. A collection of mere centers of force can have no inertia. 
 If two bodies are considered as two collections of centers of force, the 
 one attracting the other, there is in this view nothing to limit or deter- 
 mine the velocity with which the one body will approach the other. A 
 world composed of such bodies is not a material world : for matter (as 
 we have already seen in Book in. Chapter v.) implies not only force, 
 but something which resists the action of force. 
 
 VOL. I. W. P. F F 
 
434 PHILOSOPHY OF CHEMISTRY. 
 
 immovable points of their mass. This view of the way 
 in which the properties of bodies are to be treated by 
 the mechanical philosopher was introduced by Newton, 
 and was a natural sequel to the success which he had 
 obtained by reasoning concerning central forces on a 
 large scale. I have already quoted his Preface to the 
 Primipia, in which he says, " Many things induce me to 
 believe that the rest of the phenomena of nature, as 
 well as those of astronomy, may depend upon certain 
 forces by which the particles of bodies, in virtue of causes 
 not yet known, are urged towards each other and cohere 
 in regular figures, or are mutually repelled and recede ; 
 and philosophers, knowing nothing of these forces, have 
 hitherto failed in their examination of nature." Since 
 the time of Newton, this line of speculation has been fol- 
 lowed with great assiduity, and by some mathematicians 
 with great success. In particular Laplace has shown that 
 the hypothesis may, in many instances, be made a much 
 closer representation of nature, if we suppose the forces 
 exerted by the particles to decrease so rapidly with the 
 increasing distance from them, that the force is finite 
 only at distances imperceptible to our senses, and vanishes 
 at all remoter points. He has taught the method of 
 expressing and calculating such forces, and he and other 
 mathematicians of his school have applied this method 
 to many of the most important questions of physics ; as 
 capillary action, the elasticity of solids, the conduction 
 and radiation of heat. The explanation of many appa- 
 rently unconnected and curious observed facts by these 
 mathematical theories gives us a strong assurance that 
 its essential principles are true. But it must be observed 
 that the actual constitution of bodies as composed of 
 distinct and separate particles is by no means proved by 
 these coincidences. The assumption, in the reasoning, 
 of certain centers of force acting at a distance, is to be 
 
THE ATOMIC THEORY. 435 
 
 considered as nothing more than a method of reducing 
 to calculation that view of the constitution of bodies 
 which supposes that they exert force at every point. It 
 is a mathematical artifice of the same kind as the hypo- 
 thetical division of a body into infinitesimal parts, in 
 order to find its center of gravity ; and no more implies 
 a physical reality than that hypothesis does. 
 
 11. Poissoris Inference. When, therefore, M. Pois- 
 ' son, in his views of Capillary Action, treats this hypo- 
 thetical distribution of centers of force as if it were a 
 physical fact, and blames Laplace for not taking account 
 of their different distribution at the surface of the fluid 
 and below it*, he appears to push the claims of the 
 molecular hypothesis too far. The only ground for the 
 assumption of separate centers, is that we can thus 
 explain the action of the whole mass. The intervals 
 between the centers nowhere enter into this explanation : 
 and therefore we can have no reason for assuming these 
 intervals different in one part of the fluid and in the 
 other. M. Poisson asserts that the density of the fluid 
 diminishes when we approach very near the surface ; but 
 he allows that this diminution is not detected by expe- 
 riment, and that the formulae on his supposition, so far 
 as the results go, are identical with those of Laplace. 
 It is clear, then, that his doctrine consists merely in the 
 assertion of the necessary truth of a part of the hypo- 
 thesis which cannot be put to the test of experiment. 
 It is true, that so long as we have before us the hypo- 
 thesis of separate centers, the particles very near the 
 surface are not in a condition symmetrical with that of 
 the others : but it is also true that this hypothesis is 
 only a step of calculation. There results, at one period 
 of the process of deduction, a stratum of smaller density 
 at the surface of the fluid ; but at a succeeding point of 
 
 * Poisson, Theorie de F Action Capillaire. 
 
 FF2 
 
436 PHILOSOPHY OF CHEMISTRY. 
 
 the reasoning the thickness of this stratum vanishes ; it 
 has no physical existence. 
 
 Thus the molecular hypothesis, as used in such cases, 
 does not differ from the doctrine of forces acting at every 
 point of the mass ; and this principle, which is common 
 to both the opposite views, is the true part of each. 
 
 12. Wollastons Argument. An attempt has been 
 made in another case, but depending on nearly the same 
 arguments, to bring the doctrine of ultimate atoms to 
 the test of observation. In the case of the air, we know 
 that there is a diminution of density in approaching the 
 upper surface of the atmosphere, if it have a surface : 
 but it is held by some that except we allow the doctrine 
 of ultimate molecules, it will not be bounded by any 
 surface, but will extend to an infinite distance. This is 
 the reasoning of Wollaston*. "If air consists of any 
 ultimate particles no longer divisible, then must the ex- 
 pansion of the medium composed of them cease at that 
 distance where the force of gravity downwards is equal 
 to the resistance arising from the repulsive force of the 
 medium." But if there be no such ultimate particles, 
 every stratum will require a stratum beyond it to prevent 
 by its weight a further expansion, and thus the atmo- 
 sphere must extend to an infinite distance. And Wol- 
 laston conceived that he could learn from observation 
 whether the atmosphere was thus diffused through all 
 space; for if so, it must, he argued, be accumulated 
 about the larger bodies of the system, as Jupiter and 
 the Sun, by the law of universal gravitation ; and the 
 existence of an atmosphere about these bodies, might, 
 he remarked, be detected by its effects in producing 
 refraction. His result is, that "all the phenomena accord 
 entirely with the supposition that the earth's atmosphere 
 is of finite extent, limited by the weight of ultimate 
 * Phil. Trans., 1822, p. 89. 
 
THE ATOMIC THEORY. 437 
 
 atoms of definite magnitude, no longer divisible by re- 
 pulsion of their parts." 
 
 A very little reflection will show us that such a line 
 of reasoning cannot lead to any result. For we know 
 nothing of the law which connects the density with the 
 compressing force, in air so extremely rare as we must 
 suppose it to be near the boundary of the atmosphere. 
 Now there are possible laws of dependence of the den- 
 sity upon the compressing force such that the atmosphere 
 would terminate in virtue of the law without any assump- 
 tion of atoms. This may be proved by mathematical 
 reasoning. If we suppose the density of air to be as the 
 square root of the compressing force, it will follow that 
 at the very limits of the atmosphere, the strata of equal 
 thickness may observe in their densities such a law of 
 proportion as is expressed by the numbers 7, 5, 3, 1 *. 
 
 If it be asked how, on this hypothesis, the density of 
 the highest stratum can be as 1, since there is nothing 
 to compress it, we answer that the upper part of the 
 highest stratum compresses the lower, and that the 
 density diminishes continually to the surface, so that the 
 need of compression and the compressing weight vanish 
 together. 
 
 The fallacy of concluding that because the height 
 of the atmosphere is finite, the weight of the highest 
 stratum must be finite, is just the same as the fallacy 
 of those who conclude that when we project a body ver- 
 
 * For the compressing force on each being as the whole weight 
 beyond it, will be for the four highest strata, 16, 9, 4 and 1, of which 
 the square roots are as 4, 3, 2, 1, or, as 8, 6, 4, 2 ; and though these 
 numbers are not exactly as the densities 7? &, 3, 1, those who are 
 a little acquainted with mathematical reasoning, will see that the dif- 
 ference arises from taking so small a number of strata. If we were to 
 make the strata indefinitely thin, as to avoid error we ought to do, the 
 coincidence would be exact ; and thus, according to this law, the series 
 of strata terminates as we ascend, without any consideration of atoms. 
 
438 PHILOSOPHY OF CHEMISTRY. 
 
 tically upwards, because it occupies only a finite time in 
 ascending to the highest point, the velocity at the last 
 instant of the ascent must be finite. For it might be 
 said, if the last velocity of ascent be not finite, how can 
 the body describe the last particle of space in a finite 
 time ? and the answer is, that there is no last finite par- 
 ticle of space, and therefore no last finite velocity. 
 
 13. Permanence of Properties of Bodies. We have 
 already seen that, in explaining the properties of matter 
 as we find them in nature, the assumption of solid, hard, 
 indestructible particles is of no use or value. But we 
 may remark, before quitting the subject, that Newton 
 appears to have had another reason for assuming such 
 particles, and one well worthy of notice. He wished to 
 express, by means of this hypothesis, the doctrine that 
 the laws of nature do not alter with the course of time. 
 This we have already seen in the quotation from Newton. 
 44 The ultimate particles of matter are indestructible, 
 unalterable, impenetrable ; for if they could break or 
 wear, the structure of material bodies now would be dif- 
 ferent from that which it was when the particles were 
 new." No philosopher will deny the truth which is thus 
 conveyed by the assertion of atoms; but it is obviously 
 equally easy for a person who rejects the atomic view, 
 to state this truth by saying that the forces which matter 
 exerts do not vary with time, but however modified by 
 the new modifications of its form, are always unimpaired 
 in quantity, and capable of being restored to their 
 former mode of action. 
 
 We now proceed to speculations in which the funda- 
 mental conceptions may, perhaps, be expressed, at least 
 in some cases, by means of the arrangement of atoms ; 
 but in which the philosophy of the subject appears to 
 require a reference to a new Fundamental Idea. 
 
439 
 
 BOOK VII, 
 
 THE PHILOSOPHY OF MORPHOLOGY, 
 INCLUDING CRYSTALLOGRAPHY. 
 
 CHAPTER I. 
 EXPLICATION OF THE IDEA OF SYMMETRY. 
 
 1. WE have seen in the History of the Sciences, 
 that the principle which I have there termed""" the prin- 
 ciple of developed and metamorphosed Symmetry, has 
 been extensively applied in botany and physiology, and 
 has given rise to a province of science termed Morphology. 
 In order to understand clearly this principle, it is neces- 
 sary to obtain a clear idea of the Symmetry of which we 
 thus speak. But this Idea of Symmetry is applicable 
 in the inorganic, as well as in the organic kingdoms of 
 nature; it is presented to our eyes in the forms of 
 minerals, as well as of flowers and animals; we must, 
 therefore, take it under our consideration here, in order 
 that we may complete our view of mineralogy, which, as 
 I have repeatedly said, is an essential part of chemical 
 science. I shall accordingly endeavour to unfold the 
 Idea of Symmetry with which we here have to do. 
 
 It will of course be understood that by the term 
 Symmetry I here intend, not that more indefinite attri- 
 bute of form which belongs to the domain of the fine 
 arts, as when we speak of the " symmetry " of an edifice 
 
 Hist. Ind. Sci., B. xvn. c. vi. 
 
440 PHILOSOPHY OF MORPHOLOGY. 
 
 or of a sculptured figure, but a certain definite relation 
 or property, no less rigorous and precise than other re- 
 lations of number and position, which is thus one of the 
 sure guides of the scientific faculty, and one of the bases 
 of our exact science. 
 
 2. In order to explain what Symmetry is in this 
 sense, let the reader recollect that the bodies of animals 
 consist of two equal and similar sets of members, the 
 right and the left side; that some flowers consist of 
 three or of five equal sets of organs, similarly and re- 
 gularly disposed, as the iris has three straight petals, 
 and three reflexed ones, alternately disposed, the rose 
 hasjto equal and similar sepals of the calyx, and alter- 
 nate with these, as many petals of the corolla. This 
 orderly and exactly similar distribution of two, or three, 
 or five, or any other number of parts, is Symmetry ; and 
 according to its various modifications, the forms thus 
 determined are said to be symmetrical with various 
 numbers of members. The classification of these dif- 
 ferent kinds of symmetry has been most attended to in 
 Crystallography, in which science it is the highest and 
 most general principle by which the classes of forms 
 are governed. Without entering far into the techni- 
 calities of the subject, we may point out some of the 
 features of such classes. 
 
 The first of the figures (1) in 
 the margin may represent the 
 summit of a crystal as it ap- 
 pears to an eye looking directly 
 down upon it ; the center of the 
 figure represents the summit of a pyramid, and the 
 spaces of various forms which diverge from this point 
 represents sloping sides of the pyramid. Now it will be 
 observed that the figure consists of three portions exactly 
 similar to one another, and that each part or member is 
 
EXPLICATION OF THE IDEA OF SYMMETRY. 441 
 
 repeated in each of these portions. The faces, or pairs 
 of faces, are repeated in threes, with exactly similar 
 forms and angles. This figure is said to be three-mem- 
 bered, or to have triangular symmetry. The same kind 
 of symmetry may exist in a flower, as presented in the 
 accompanying figure, and does, in fact, occur in a large 
 class of flowers, as for example, all the lily tribe. The 
 next pair of figures (2) have four equal and similar por- 
 tions, and have their members or 
 pairs of members four times re- 
 peated. Such figures are termed 
 four-membered, and are said to 
 have square or tetragonal sym- 
 metry. The pentagonal symme- 
 try, formed by five similar mem- 
 bers, is represented in the next 
 figures (3). It occurs abundantly 
 in the vegetable world, but never 
 among crystals; for the pen- 
 tagonal figures which crystals 
 sometimes assume, are never ex- 
 actly regular. But there is still 
 another kind of symmetry (4) in 
 which the opposite ends are ex- 
 actly similar to each other and 
 also the opposite sides; this is 
 oblong, or two-and-tivo-membered 
 symmetry. And finally, we have 
 the case of simple symmetry (5) 
 in which the two sides of the 
 object are exactly alike (in op- 
 posite positions) without any 
 further repetition. 
 
 3. These different kinds of symmetry occur in various 
 ways in the animal, vegetable, and mineral kingdom ; 
 
 ^ : 
 
442 PHILOSOPHY OF MORPHOLOGY. 
 
 thus vertebrate animals have a right and a left side 
 exactly alike, and thus possess simple symmetry. The 
 same kind of symmetry (simple symmetry) occurs very 
 largely in the forms of vegetables, as in most leaves, in 
 papilionaceous, personate, and labiate flowers. Among 
 minerals, crystals which possess this symmetry are called 
 oblique-prismatic, and are of very frequent occurrence. 
 The oblong, or two-and-two membered symmetry belongs 
 to right-prismatic crystals ; and may be seen in cruci- 
 ferous flowers, for though these are cross-shaped, the 
 cross has two longer and two shorter arms, or pairs of 
 arms. The square or tetragonal symmetry occurs in 
 crystals abundantly ; to the vegetable world it appears 
 to be less congenial ; for though there are flowers with 
 four exactly similar and regularly-disposed petals, as the 
 herb Paris (Paris quadrifolia), these flowers appear, 
 from various circumstances, to be deviations from the 
 usual type of vegetable forms. The trigonal, or three- 
 membered symmetry is found abundantly both in plants 
 and in crystals, while the pentagonal symmetry, on the 
 other hand, though by far the most common among 
 flowers, nowhere occurs in minerals, and does not appear 
 to be a possible form of crystals. This pentagonal form 
 further occurs in the animal kingdom, which the oblong, 
 triangular, and square forms do not. Many of Cuvier's 
 radiate animals appear in this pentagonal form, as 
 echini and pentacrinites, which latter have hence their 
 name. 
 
 4. The regular, or as they may be called, the normal 
 types of the vegetable world appear to be the forms 
 which possess triangular and pentagonal symmetry; 
 from these the others may be conceived to be derived, 
 by transformations resulting from the expansion of one 
 or more parts. Thus it is manifest that if in a three- 
 membered or five-membcred flower, one of the petals be 
 
EXPLICATION OF THE IDEA OF SYMMETRY. 443 
 
 expanded more than the other, it is immediately reduced 
 from pentagonal or trigonal, to simple symmetry. And 
 the oblong or two-and-two membered symmetry of the 
 flowers of cruciferous plants, (in which the stamens are 
 four large and two small ones, arranged in regular 
 opposition,) is held by botanists to result from a normal 
 form with ten stamens; Meinecke explaining this by 
 adhesion, and Sprengei by the metamorphosis of the 
 stamens into petals*. 
 
 It is easy to see that these various kinds of symmetry 
 include relations both of form and of number, but more 
 especially of the latter kind ; and as this symmetry is 
 often an important character in various classes of natural 
 objects, such classes have often curious numerical pro- 
 perties. One of the most remarkable and extensive of 
 these is the distinction which prevails between mono- 
 cotyledonous and dicotyledonous plants; the number 
 three being the ground of the symmetry of the former, 
 and the number five, of the latter. Thus liliaceous and 
 bulbous plants, and the like, have flowers of three or 
 six petals, and the other organs follow the same num- 
 bers : while the vast majority of plants are pentandrous, 
 and with their five stamens have also their other parts 
 in fives. This great numerical distinction corresponding 
 to a leading difference of physiological structure cannot 
 but be considered as a highly curious fact in phytology. 
 Such properties of numbers, thus connected in an incom- 
 prehensible manner with fundamental and extensive 
 laws of nature, give to numbers an appearance of mys- 
 terious importance and efficacy. We learn from history 
 how strongly the study of such properties, as they are 
 exhibited by the phenomena of the heavens, took posses- 
 sion of the mind of Kepler ; perhaps it was this which, 
 at an earlier period, contributed in no small degree to 
 * Sprengei, Gcsch. d. Bot., n. 304. 
 
444 PHILOSOPHY OF MORPHOLOGY. 
 
 the numerical mysticism of the Pythagoreans in anti- 
 quity, and of the Arabians and others in the middle 
 ages. In crystallography, numbers are the primary 
 characters in which the properties of substances are 
 expressed; they appear, first, in that classification of 
 forms which depends on the degree of symmetry, that 
 is, upon the number of correspondencies ; and next, in 
 the laws of derivation, which, for the most part, appear 
 to be common in their occurrence in proportion to the 
 numerical simplicity of their expression. But the mani- 
 festation of a governing numerical relation in the or- 
 ganic world strikes us as more unexpected ; and the 
 selection of the number five as the index of the sym- 
 metry of dicotyledonous plants and radiated animals, (a 
 number which is nowhere symmetrically produced in 
 inorganic bodies,) makes this a new and remarkable 
 illustration of the constancy of numerical relations. We 
 may observe, however, that the moment one of these 
 radiate animals has one of its five members expanded, 
 or in any way peculiarly modified, (as happens among 
 the echini) it is reduced to the common type of animals 
 simply symmetrical, with a right and left side. 
 
 5. It is not necessary to attempt to enumerate all the 
 kinds of Symmetry, since our object is only to explain 
 what Symmetry is, and for this purpose enough has 
 probably been said already. It will be seen, as soon as 
 the notion of Symmetry in general is well apprehended, 
 that it is or includes a peculiar Fundamental Idea, not 
 capable of being resolved into any of the ideas hitherto 
 examined. It may be said, perhaps, that the Idea of 
 Symmetry is a modification or derivative of our ideas of 
 space and number; that a symmetrical shape is one 
 which consists of parts exactly similar, repeated a cer- 
 tain number of times, and placed so as to correspond 
 with each other. But on further reflection it will be 
 
EXPLICATION OF THE IDEA OF SYMMETRY. 445 
 
 seen that this repetition and correspondence of parts in 
 symmetrical figures are something peculiar ; for it is not 
 any repetition or any correspondence of parts to which 
 we should give the name of symmetry, in the manner in 
 which we are now using the term. Symmetrical arrange- 
 ments may, no doubt, be concerned with space and posi- 
 tion, time and number ; but there appears to be implied 
 in them a Fundamental Idea of regularity, of complete- 
 ness, of complex simplicity, which is not a mere modifi- 
 cation of other ideas. 
 
 6. It is, however, not necessary, in this and in similar 
 cases to determine whether the idea which we have 
 before us be a peculiar and independent Fundamental 
 Idea or a modification of other ideas, provided we clearly 
 perceive the evidence of those Axioms by means of 
 which the Idea is applied in scientific reasonings. Now 
 in the application of the Idea of Symmetry to crystallo- 
 graphy, phytology and zoology, we must have this idea 
 embodied in some principle which asserts more than a 
 mere geometrical or numerical accordance of members. 
 We must have it involved in some vital or productive 
 action, in order that it may connect and explain the facts 
 of the organic world. Nor is it difficult to enunciate such 
 a principle. We may state it in this manner. All the sym- 
 metrical members of a natural product are, under like 
 circumstances, alike affected by the natural formative 
 power. The parts which we have termed symmetrical, 
 resemble each other, not only in their form and position, 
 but also in the manner in which they are produced and 
 modified by natural causes. And this principle we assume 
 to be necessarily true, however unknown and inconceiv- 
 able may be the causes which determine the phenomena. 
 Thus it has not yet been found possible to discover or re- 
 present to ourselves, in any intelligible manner, the forces 
 by which the various faces of a crystal are consequent 
 
446 PHILOSOPHY OF MORPHOLOGY. 
 
 upon its primary form ; but the whole of crystallography 
 rests upon this principle, that if one of the primary planes 
 or axes be modified in any manner, all the symmetrical 
 planes and axes must be modified in the same manner. 
 And though accidental mechanical or other causes may 
 interfere with the actual exhibition of such faces, we do 
 not the less assume their crystallographical reality, as 
 inevitably implied in the law of symmetry of the cry- 
 stal*. And we apply similar considerations to organized 
 beings. We assume that in a regular flower, each of 
 the similar members has the same organization and 
 similar powers of developement ; and hence if among 
 these similar parts some are much less developed than 
 others, we consider them as abortive; and if we wish 
 to remove doubts as to what are symmetrical members 
 in such a case, we make the inquiry by tracing the ana- 
 tomy of these members, or by following them in their 
 earlier states of developement, or in cases where their 
 capabilities are magnified by monstrosity or otherwise. 
 The power of developement may be modified by exter- 
 nal causes, and thus we may pass from one kind of sym- 
 metry to another ; as we have already remarked. Thus 
 a regular flower with pentagonal symmetry, growing on 
 a lateral branch, has one petal nearest to the axis of the 
 plant : if this petal be more or less expanded than the 
 others, the pentagonal symmetry is interfered with, and 
 the flower may change to a symmetry of another kind. 
 But it is easy to see that all such conceptions of expan- 
 sion, abortion, and any other kind of metamorphosis, go 
 upon the supposition of identical faculties and tenden- 
 cies in each similar member, in so far as such tendencies 
 
 * Some crystalline forms, instead of being holohedral (provided 
 with their whole number of faces), are hemihedral (provided with only 
 half their number of faces). But in these hemihedral forms the half 
 of the faces are still symmetrically suppressed. 
 
EXPLICATION OF THE IDEA OF SYMMETRY. 447 
 
 have any relation to the symmetry. And thus the prin- 
 ciple we have stated above is the basis of that which, in 
 the History, we termed the Principle of Developed and 
 Metamorphosed Symmetry. 
 
 We shall not at present pursue the other applications 
 of this Idea of Symmetry, but we shall consider some of 
 the results of its introduction into Crystallography. 
 
 CHAPTER II. 
 
 APPLICATION OF THE IDEA OF SYMMETRY 
 TO CRYSTALS. 
 
 1. MINERALS and other bodies of definite chemical 
 composition often exhibit that marked regularity of form 
 and structure which we designate by terming them 
 Crystals; and in such crystals, when we duly study them, 
 we perceive the various kinds of symmetry of which we 
 have spoken in the previous chapter. And the different 
 kinds of symmetry which we have there described are 
 now usually distinguished from each other, by writers 
 on crystallography. Indeed it is mainly to such writers 
 that we are indebted for a sound and consistent classifi- 
 cation of the kinds arid degrees of symmetry of which 
 forms are capable. But this classification was by no 
 means invented as soon as mineralogists applied them- 
 selves to the study of crystals. These first attempts to 
 arrange crystalline forms were very imperfect ; those, 
 for example, of Linnaeus, Werner, Rome de Lisle, and 
 Hauy. The essays of these writers implied a classifica- 
 tion at once defective and superfluous. They reduced 
 all crystals to one or other of certain fundamental 
 forms ; and this procedure might have been a perfectly 
 good method of dividing crystalline forms into classes, 
 
448 PHILOSOPHY OF MORPHOLOGY. 
 
 if the fundamental forms had been selected so as to ex- 
 emplify the different kinds of symmetry. But this was 
 not the case. Haiiy's fundamental or " primitive" forms, 
 were, for instance, the following : the parallelepiped, 
 the octahedron, the tetrahedron, the regular hexagonal 
 prism, the rhombic dodecahedron, and the double hexa- 
 gonal pyramid. Of these, the octahedron, the tetra- 
 hedron, the rhombic dodecahedron, all belong to the 
 same kind of symmetry (the TESSULAR systems) ; also 
 the hexagonal prism and the hexagonal pyramid both 
 belong to the RHOMBIC system ; while the parallelepiped 
 is so employed as to include all kinds of symmetry. 
 
 It is, however, to be recollected that Haiiy, in his 
 selection of primitive forms, not only had an eye to the 
 external form of the crystal and to its degree and 
 kind of regularity, but also made his classification with 
 an especial reference to the cleavage of the mineral, 
 which he considered as a primary element in crystalline 
 analysis. There can be no doubt that the cleavage of a 
 crystal is one of its most important characters : it is a 
 relation of form belonging to the interior, which is to be 
 attended to no less than the form of the exterior. But 
 still, the cleavage is to be regarded only as determining 
 the degree of geometrical symmetry of the body, and not 
 as defining a special geometrical figure to which the 
 body must be referred. To have looked upon it in the 
 latter light, was a mistake of the earlier crystallographic 
 speculators, on which we shall shortly have to remark. 
 
 2. I have said that the reference of crystals to Pri- 
 mitive Forms might have been well employed as a mode 
 of expressing a just classification of them. This follows 
 as a consequence from the application of the Principle 
 stated in the last chapter, that all symmetrical mem- 
 bers are alike affected. Thus we may take an upright 
 triangular prism as the representative of the rhombic 
 
IDEA OF SYMMETRY IN CRYSTALS. 449 
 
 system, and if we then suppose one of the upper edges 
 to be cut off, or truncated, we must, by the Principle of 
 Symmetry, suppose the other two upper edges to be 
 truncated in precisely the same manner. By this trun- 
 cation we may obtain the upper part of a rhombohedron ; 
 and by truncations of the same kind, symmetrically 
 affecting all the analogous parts of the figure, we may 
 obtain any other form possessing three-membered sym- 
 metry. And the same is true of any of the other kinds 
 of symmetry, provided we make a proper selection of a 
 fundamental form. And this was really the method 
 employed by Demeste, Werner, and Rome -de Lisle. 
 They assumed a Primitive Form, and then conceived 
 other forms, such as they found in nature, to be derived 
 from the Primitive Form by truncation of the edges, 
 acumination of the corners, and the like processes. This 
 mode of conception was a perfectly just and legitimate 
 expression of the general Idea of Symmetry. 
 
 3. The true view of the degrees of symmetry was, as I 
 have already said, impeded by the attempts which Haiiy 
 and others made to arrive at primitive forms by the light 
 which cleavage was supposed to throw upon the structure 
 of minerals. At last, however, in Germany, as I have 
 narrated in the History of Mineralogy *, Weiss and Mohs 
 introduced a classification of forms implying a more phi- 
 losophical principle, dividing the forms into Systems; 
 which, employing the terms of the latter writer, we shall 
 call the tessular, the pyramidal or square pyramidal, 
 the prismatic or oblong, and the rhombohedral systems. 
 
 Of these forms, the three latter may be at once 
 referred to those kinds of symmetry of which we have 
 spoken in the last chapter. The rhombohedral system 
 has triangular symmetry, or is three-membered : the 
 pyramidal has square symmetry, or is four-membered : 
 
 * Hist. Ind. Scl, B. xv. c. iv. 
 VOL. I. W. P. G G 
 
450 PHILOSOPHY OF MORPHOLOGY. 
 
 the prismatic has oblong symmetry, and is two-and-two- 
 membered. But the kinds of symmetry which were 
 spoken of in the former chapter, do not exhaust the idea 
 when applied to minerals. For the symmetry which was 
 there explained was such only as can be exhibited on a 
 surface, whereas the forms of crystals are solid. Not 
 only have the right and left parts of the upper surface of 
 a crystal relations to each other ; but the upper surface 
 and the lateral faces of the crystal have also their rela- 
 tions ; they may be different, or they may be alike. 
 If we take a cube, and hold it so that four of its faces 
 are vertical, not only are all these four sides exactly simi- 
 lar, so as to give square symmetry ; but also we may turn 
 the cube, so that any one of these four sides shall become 
 the top, and still the four sides which are thus made 
 vertical, though not the same which were vertical before, 
 are still perfectly symmetrical. Thus this cubical figure 
 possesses more than square symmetry. It possesses 
 square symmetry in a vertical as well as in a horizontal 
 sense. It possesses a symmetry which has the same 
 relation to a cube which four-membered symmetry has to 
 a square. And this kind of symmetry is termed the 
 cubical or tessular symmetry. All the other kinds of 
 symmetry have reference to an axis, about which the 
 corresponding parts are disposed; but in tessular sym- 
 metry the horizontal and vertical axes are also symme- 
 trical, or interchangeable ; and thus the figure may be 
 said to have no axis at all. 
 
 4. It has already been repeatedly stated that, by the 
 very idea of symmetry, all the incidents of form must 
 affect alike all the corresponding parts. Now in crystals 
 we have, among these incidents, not only external figure, 
 but cleavage, which may be considered as internal figure. 
 Cleavage, then, must conform to the degree of symmetry 
 of the figure. Accordingly cleavage, no less than form, is 
 
IDEA OF SYMMETRY IN CRYSTALS. 4i51 
 
 to be attended to in determining to what system a mineral 
 belongs. If a crystal were to occur as a square prism or 
 pyramid, it would not on that account necessarily belong 
 to the square pyramidal system. If it were found that 
 it was cleavable parallel to one side of the prism, but not 
 in the transverse direction, it has only oblong symmetry ; 
 and the equality of the sides which makes it square is 
 only accidental. 
 
 Thus no cleavage is admissible in any system of 
 crystallization which does not agree with the degree of 
 symmetry of the system. On the other hand, any cleavage 
 which is consistent with the symmetry of the system, is 
 (hypothetically at least) allowable. Thus in the oblong 
 prismatic system we may have a cleavage parallel to one 
 side only of the prism ; or parallel to both, but of differ- 
 ent distinctness ; or parallel to the two diagonals of the 
 prism but of the same distinctness ; or we may have both 
 these cleavages together. In the rhombohedral system, 
 the cleavage may be parallel to the sides of the rhombo- 
 hedron, as in Calc Spar: or, in the same system, the 
 cleavage, instead of being thus oblique to the axis, 
 may be along the axis in those directions which make 
 equal angles with each other : this cleavage easily gives 
 either a triangular or a hexagonal prism. Again, in the 
 tessular system, the cleavage may be parallel to the sur- 
 face of the cube, which is thus readily separable into 
 other cubes, as in Galena ; or the cleavage may be such 
 as to cut off the solid angle of the cube, and since there 
 are eight of these, such cleavage gives us an octahedron, 
 which, however, may be reduced to a tetrahedron, by 
 rejecting all parallel faces, as being mere repetitions of 
 the same cleavage ; this is the case with Fluor Spar : 
 or the cube of the tessular system may be cleavable in 
 planes which truncate all the edges of the cube ; and as 
 these are twelve, we thus obtain the dodecahedron with 
 
 GG2 
 
452 PHILOSOPHY OF MORPHOLOGY. 
 
 rhombic faces : this occurs in Zinc Blende. And thus 
 we see the origin of Haiiy's various primitive forms, the 
 tetrahedron, octahedron, and rhombic dodecahedron, all 
 belonging to the tessular system : they are, in fact, dif- 
 ferent cleavage forms of that system. 
 
 5. I do not dwell upon other incidents of crystals 
 which have reference to form, nor upon the lustre, 
 smoothness, and striation of the surfaces. To all such 
 incidents the general principle applies, that similar parts 
 are similarly affected ; and hence, if any parts are found 
 to be constantly and definitely different from other parts 
 of the same sort, they are not similar parts ; and the 
 symmetry is to be interpreted with reference to this 
 difference. 
 
 We have now to consider the inferences which have 
 been drawn from these incidents of crystallization, with 
 regard to the intimate structure of bodies. 
 
 CHAPTER III. 
 
 SPECULATIONS FOUNDED UPON THE 
 SYMMETRY OF CRYSTALS. 
 
 1. WHEN a crystal, as, for instance, a crystal of galena, 
 (sulphuret of lead,) is readily divisible into smaller cubes, 
 and these into smaller ones, and so on without limit, it is 
 very natural to represent to ourselves the original cube as 
 really consisting of small cubical elements; and to imagine 
 that it is a philosophical account of the physical structure 
 of such a substance to say that it is made up of cubical 
 molecules. And when the galena crystal has externally 
 the form of a cube, there is no difficulty in such a con- 
 ception ; for the surface of the crystal is also conceived 
 as made up of the surfaces of its cubical molecules. We 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 453 
 
 conceive the crystal so constituted, as we conceive a wall 
 built of bricks. 
 
 But if, as often happens, the galena crystal be an 
 octahedron, a further consideration is requisite in order 
 to understand its structure, pursuing still the same hypo- 
 thesis. The mineral is still, as in the other case, readily 
 cleavable into small cubes, having their corners turned 
 to the faces of the octahedron. Therefore these faces 
 can no longer be conceived as made up of the faces of 
 cubical elements of which the whole is constituted. If 
 we suppose a pile of such small cubes to be closely built 
 together, but with decreasing width above, so as to form 
 a pyramid, the face of such a pyramid will no longer be 
 plane ; it will consist of a great number of the corners 
 or edges of the small elementary cubes. It would ap- 
 pear at first sight, therefore, that such a face cannot 
 represent the smooth polished surface of a crystal. 
 
 But when we come to look more closely, this diffi- 
 culty disappears. For how large are these elementary 
 cubes ? We cannot tell, even supposing they really have 
 any size. But we know that they must be, at any rate, 
 very small ; so small as to be inappreciable by our senses, 
 for our senses find no limit to the divisibility of minerals 
 by cleavage. Hence the surface of the pyramid above 
 described would not consist of visible corners or edges, 
 but would be roughened by specks of imperceptible size ; 
 or rather, by supposing these specks to become still 
 smaller, the roughness becomes smoothness. And thus 
 we may have a crystal with a smooth surface, made up of 
 small cubes in such a manner that their surfaces are all 
 oblique to the surface of the crystal. 
 
 Haiiy, struck by some instances in which the suppo- 
 sition of such a structure of crystals appeared to account 
 happily for several of their relations and properties, 
 adopted and propounded it as a general theory. The 
 
454 PHILOSOPHY OF MORPHOLOGY. 
 
 small elements, of which he supposed crystals to be thus 
 built up, he termed integrant molecules. The form of 
 these molecules might or might not be the same as the 
 primitive form with which his construction was supposed 
 to begin ; but there was, at any rate, a close connexion 
 between these forms, since both of them were founded 
 on the cleavage of the mineral. The tenet that crystals 
 are constituted in the manner which I have been de- 
 scribing, I shall call the Theory of Integrant Molecules, 
 and I have now to make some remarks on the grounds 
 of this theory. 
 
 2. In the case of which I have spoken, the mineral 
 used as the example, galena, readily splits into cubes, and 
 cubes are easily placed together so as to fit eat other, 
 and fill the space which they occupy. The same is the 
 case in the mineral which suggested to Haliy his theory, 
 namely, calc spar. The crystals of this substance are 
 readily divisible into rhombohedrons, a form like a brick 
 with oblique angles; and such bricks can be built to- 
 gether so as to produce crystals of all the immense 
 varieties of form which calc spar presents. This kind of 
 masonry is equally possible in many other minerals ; but 
 as we go through the mineral kingdom in our survey, we 
 soon find cases which offer difficulties. Some minerals 
 cleave only in two directions, some in one only ; in such 
 cases we cannot by cleavage obtain an integrant mole- 
 cule of definite form ; one of its dimensions, at least, 
 must remain indeterminate and arbitrary. Again, in 
 some instances, we have more than three different planes 
 of cleavage, as in fluor spar, where we have four. The 
 solid, bounded by four planes, is a tetrahedron ; or if we 
 take four pairs of parallel faces, an octahedron. But if 
 we attempt to take either of these forms for our inte- 
 grant molecule, we are met by this difficulty : that a col- 
 lection of such forms will not fill space. Perhaps this 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 455 
 
 difficulty will be more readily conceived by the general 
 reader if it be contemplated with reference to plane 
 figures. It will readily be seen that a number of equal 
 squares may be put together so as to fill the space which 
 they occupy ; but if we take a number of equal regular 
 octagons, we may easily convince ourselves that no pos- 
 sible arrangement can make them cover a flat space with- 
 out leaving blank spots between. In like manner octa- 
 hedrons or tetrahedrons cannot be arranged in solid space 
 so as to fill it. They necessarily leave vacancies. Hence 
 the structure of fluor spar, and similar crystals, was a 
 serious obstacle in the way of the theory of integrant 
 molecules. That theory had been adopted in the first 
 instance because portions of the crystal, obtained by 
 cleavage, could be built up into a solid mass; but this 
 ground of the theory failed altogether in such instances 
 as I have described, and hence the theory, even upon the 
 representations of its adherents, had no longer any claim 
 to assent. 
 
 The doctrine of Integral Molecules, however, was by 
 no means given up at once, even in such instances. In 
 this and in other subjects, we may observe that a theory, 
 once constructed and carried into detail, has such a hold 
 upon the minds of those who have been in the habit of 
 applying it, that they will attempt to uphold it by intro- 
 ducing suppositions inconsistent with the original founda- 
 tions of the theory. Thus those who assert the atomic 
 theory, reconcile it with facts by taking the halves of 
 atoms ; and thus the theory of integrant molecules was 
 maintained for fluor spar, by representing the elemen- 
 tary octahedrons of which crystals are built up, as 
 touching each other only by the edges. The contact 
 of surface with surface amongst integrant molecules had 
 been the first basis of the theory ; but this supposition 
 being here inapplicable, was replaced by one which 
 
456 PHILOSOPHY OF MORPHOLOGY. 
 
 made the theory no longer a representation of the 
 facts (the cleavages), but a mere geometrical construc- 
 tion. Although, however, the inapplicability of the 
 theory to such cases was thus, in some degree, disguised 
 to the disciples of Haiiy, it was plain that, in the face of 
 such difficulties, the Theory of Integrant Molecules could 
 not hold its place as a philosophical truth. But it still 
 answered the purpose (a very valuable one, and one to 
 which crystallography is much indebted,) of an instru- 
 ment for calculating the geometrical relations of the parts 
 of crystals to each other: for the integrant molecules 
 were supposed to be placed layer above layer, each layer 
 as we ascend, decreasing by a certain number of mole- 
 cules and rows of molecules ; and the calculation of these 
 laws of decrement was, in fact, the best mode then known 
 of determining the positions of the faces. The Theory 
 of Decrements served to express and to determine, in 
 a great number of the most obvious cases, the laws of 
 phenomena in crystalline forms, though the Theory of 
 Integrant Morecules could not be maintained as a just 
 view of the structure of crystals. 
 
 3. The Theory of Integrant Molecules, however, in- 
 volved this just and important principle : that a true view 
 of the intimate structure of crystals must include and 
 explain the facts of crystallization, that is, crystalline 
 form and cleavage; and that it must take these into 
 account, according to their degree of symmetry. So far 
 all theories concerning the elements of crystals must 
 agree. And it was soon seen that this was, in reality, all 
 that had been established by the investigations of Haiiy 
 and his school. I have already, in the History, quoted 
 Weiss's reflections on making this step. "When in 
 1809," he says*, "I published my Dissertation, I shared 
 the common opinion as to the necessity of the assump- 
 
 * Acad. Berlin. 1816. p. 307- 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 457 
 
 tion, and the reality of the existence of a primitive form, 
 at least in a sense not very different from the usual sense 
 of the expression." He then proceeds to relate that he 
 sought a ground for such an opinion, independent of the 
 doctrine of atoms, which he, in common with a great 
 number of philosophers of that time in his own country, 
 was disposed to reject, inclining to believe that the pro- 
 perties of .bodies were determined by forces which acted 
 in them, and not by molecules of which they were com- 
 posed. He adds, that in pursuing this train of thought, 
 he found, " that out of his primitive forms there was gra- 
 dually unfolded to his hands that which really governs 
 them, and is not affected by their casual fluctuations ; 
 namely, the fundamental relations of their Dimensions," 
 or as we now may call them, Axes of Symmetry. With 
 reference to these axes, he found, as he goes on to say, 
 that " a multiplicity of internal oppositions, necessarily 
 and mutually interdependent, are developed in the crys- 
 talline mass, each relation having its own polarity ; so 
 that the crystalline character is co-extensive with these 
 polarities." The character of these polarities, whether 
 manifested in crystalline faces, cleavage, or any other 
 incidents of crystallization, is necessarily displayed in the 
 degree and kind of symmetry which the crystal possesses : 
 and thus this symmetry, in all our speculations concern- 
 ing the structure of crystals, necessarily takes the place 
 of that enumeration of primitive forms which were re- 
 jected as inconsistent with observed facts, and destitute 
 of sound scientific principle. 
 
 I may just notice here what I have stated in the 
 History of Mineralogy""", that the distinction of systems 
 of crystallization, as introduced by Weiss and Mohs, was 
 strikingly confirmed by Sir David Brewster's discoveries 
 respecting the optical properties of minerals. The splen- 
 
 * Hisl. Ind. Set., B. xv. c. v. 
 
458 PHILOSOPHY OF MORPHOLOGY. 
 
 did phenomena which were produced by passing polarized 
 light through crystals, were found to vary according as 
 the crystals were of the rhombohedral, square pyramidal, 
 oblong prismatic, or tessular system. The optical ex- 
 actly corresponded with the geometrical symmetry. In 
 the two former systems were crystals uniaxal in respect 
 of their optical properties ; the oblong prismatic was 
 biaxal; while in the tessular, the want of a predominant 
 axis prevented the phenomena here spoken of from oc- 
 curring at all. The optical experiments must have led 
 to a classification of crystals into the above systems or 
 something nearly equivalent, even had they not been 
 already so arranged by attention to their forms. 
 
 4. While in Germany Weiss and Mohs with their 
 disciples, were gradually rejecting what was superfluous 
 in the previous crystallographical hypytheses, philoso- 
 phers in England were also trying to represent to them- 
 selves the constitution of crystals in a manner which 
 should be free from the obviously arbitrary and untenable 
 fictions of the Haiiyian school. These attempts, how- 
 ever, were not crowned with much success. One mode 
 of representing the structure of crystals which suggested 
 itself, was to reject the polyhedral forms which Haiiy gave 
 to his integrant molecules, and to conceive the elements 
 of crystals as spheres, the properties of the crystal being 
 determined not by the surfaces, but by the position of 
 the elements. This was done by Wollaston, in the Phi- 
 losophical Transactions for 1813. He applied this view 
 to the tessular system, in which, indeed, the application 
 is not difficult; and he showed that octahedral and tetra- 
 hedral figures may be deduced from symmetrical ar- 
 rangements of equal spherules. But though in doing 
 this, he manifested a perception of the conditions of the 
 problem, he appeared to lose his hold on the real ques- 
 tion when he tried to pass on to other systems of 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 459 
 
 crystallization. For he accounted for the rhombohedral 
 system by supposing the spheres changed into spheroids. 
 Such a procedure involved him in a gratuitous and use- 
 less hypothesis : for to what purpose do we introduce 
 the arrangement of atoms (instead of their figure,) as a 
 mode of explaining the symmetry of the crystallization, 
 when at the next step we ascribe to the atom, by an 
 arbitrary fiction, a symmetry of figure of the same kind 
 as that which we have to explain ? It is just as easy, 
 and as allowable, to assume an elementary rhombohe- 
 dron, as to assume elementary spheroids, of which the 
 rhombohedrons are constructed. 
 
 5. Many hypotheses of the same kind might be 
 adduced, devised both by mineralogists and chemists. 
 But almost all such speculations have been pursued 
 with a most surprizing neglect of the principle which 
 obviously is the only sound basis on which they can pro- 
 ceed. The principle is this: that All hypotheses con- 
 cerning the arrangement of the elementary atoms of 
 bodies in space must be constructed with reference to the 
 general facts of crystallization. The truth and import- 
 ance of this principle can admit of no doubt. For if we 
 make any hypothesis concerning the mode of connexion 
 of the elementary particles of bodies, this must be done 
 with the view of representing to ourselves the forces 
 which connect them, and the results of these forces as 
 manifested in the properties of the bodies. Now the 
 forces which connect the particles of bodies so as to 
 make them crystalline, are manifestly chemical forces. 
 It is only definite chemical compounds which crystallize; 
 and in crystals the force of cohesion by which the par- 
 ticles are held together cannot in any way be distin- 
 guished or separated from the chemical force by which 
 their elements are combined. The elements are under- 
 stood to be combined, precisely because the result is 
 
460 PHILOSOPHY OF MORPHOLOGY. 
 
 a definite, apparently homogeneous substance. The 
 properties of the compound bodies depend upon the 
 elements and their mode of combination ; for, in fact, 
 these include everything on which they can depend. 
 There are no other circumstances than these which can 
 affect the properties of a body. Therefore all those pro- 
 perties which have reference to space, namely, the cry- 
 stalline properties, cannot depend upon anything else 
 than the arrangement of the elementary molecules in 
 space. These properties are the facts which any hypo- 
 thesis of the arrangement of molecules must explain, or 
 at least render conceivable; and all such hypotheses, all 
 constructions of bodies by supposed arrangements of 
 molecules, can have no other philosophical object than to 
 account for facts of this kind. If they do not do this, they 
 are mere arbitrary geometrical fictions, which cannot be 
 in any degree confirmed or authorized by an examination 
 of nature, and are therefore not deserving of any regard. 
 6. Those philosophers who have endeavoured to 
 represent the mode in which bodies are constructed by 
 the combination of their chemical atoms, have often un- 
 dertaken to show, not only that the atoms are combined, 
 but also in what positions and configurations they are 
 combined. And it is truly remarkable, as I have already 
 said, that they have done this, almost in every instance, 
 without any consideration of the crystalline character of 
 the resulting combinations; from which alone we receive 
 any light as to the relation of their elements in space. 
 Thus Dr. Dalton, in his Elements of Chemistry, in which 
 he gave to the world the Atomic Theory as a representa- 
 tion of the doctrine of definite and multiple proportions, 
 also published a large collection of Diagrams, exhibiting 
 what he conceived to be the configuration of the atoms 
 in a great number of the most common combinations 
 of chemical elements. Now these hypothetical diagrams 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 461 
 
 do not in any way correspond, as to the nature of their 
 symmetry, with the compounds, as we find them dis- 
 playing their symmetry when they occur crystallized. 
 Carbonate of lime has in reality a triangular symmetry, 
 since it belongs to the rhombohedral system; Dr. Dalton's 
 carbonate of lime would be an oblique rhombic prism 
 or pyramid. Sulphate of baryta is really two-and-two 
 membered ; Dr. Dalton's diagram makes it two-and-one 
 membered. Alum is really octahedral or tessular ; but 
 according to the diagram it could not be so, since the 
 two ends of the atom are not symmetrical. And the 
 same want of correspondence between the facts and the 
 hypothesis runs through the whole system, It need not 
 surprize us that the theoretical arrangement of atoms 
 does not explain the facts of crystallization ; for to pro- 
 duce such an explanation would be a second step in 
 science quite as great as the first, the discovery of the 
 atomic theory in its chemical sense. But we may allow 
 ourselves to be surprized that an utter discrepance be- 
 tween all the facts of crystallization and the figures 
 assumed in the theory, did not suggest any doubt as to 
 the soundness of the mode of philosophizing by which 
 this part of the theory was constructed. 
 
 7. Some little accordance between the hypothetical 
 arrangements of chemical atoms and the facts of crystal- 
 lization, does appear to have been arrived at by some of 
 the theorists to whom we here refer, although by no 
 means enough to show a due conviction of the importance 
 of the principle stated above. Thus Wollaston, in the 
 Essay above noticed, after showing that a symmetrical 
 arrangement of equal spherules would give rise to octa- 
 hedral and other tessular figures, remarks, very properly, 
 that the metals, which are simple bodies, crystallize in 
 such forms. M. Ampere'"" also, in 1814, published a 
 
 * Ann. de Ckimie, torn. xc. p. 43. 
 
462 PHILOSOPHY OF MORPHOLOGY. 
 
 brief account of an hypothesis of a somewhat similar 
 nature, and stated himself to have developed this specu- 
 lation in a Memoir which has not yet, so far as I am 
 aware, been published. In this notice he conceives 
 bodies to be compounded of molecules, which, arranged 
 in a polyhedral form, constitute particles. These repre- 
 sentative forms of the particles depend on chemical laws. 
 Thus the particles of oxygen, of hydrogen, and of azote, 
 are composed each of four molecules. Hence it is col- 
 lected that the particles of nitrous gas are composed of 
 two molecules of oxygen and two of azote ; and similar 
 conclusions are drawn respecting other substances. These 
 conclusions, though expressed by means of the polyhe- 
 drons thus introduced, are supported by chemical, rather 
 than by crystallographical comparisons. The author 
 does, indeed, appeal to the crystallization of sal am- 
 moniac as an argument* ; but as all the forms which 
 he introduces appear to belong to the tessular system 
 of crystallization, there is, in his reasonings, nothing 
 distinctive ; and therefore nothing, crystallographically 
 speaking, of any weight on the side of this theory. 
 
 8. Any hypothesis which should introduce any 
 principle of chemical order among the actual forms of 
 minerals, would well deserve attention. At first sight, 
 nothing can appear more anomalous than the forms 
 which occur. We have, indeed, one broad fact, which 
 has an encouraging aspect, the tessular forms in which 
 the pure metals crystallize. The highest degree of che- 
 mical and of geometrical simplicity coincide: irregularity 
 disappears precisely where it is excluded by the consi- 
 deration above stated, that the symmetry of chemical 
 composition must determine the symmetry of crystalline 
 form'"". 
 
 * Ann. de Chimie, torn. xc. p. 83. 
 
 t Inasmuch as this law, that the simple metals crystallize in tes- 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 463 
 
 But if we go on to any other class of crystalline 
 forms, we soon find ourselves lost in our attempts to 
 follow any thread of order. We have indeed many large 
 groups connected by obvious analogies ; as the rhombo- 
 hedral carbonates of lime, magnesia, iron, manganese; 
 the prismatic carbonates and sulphates of lime, baryta, 
 strontia, lead. But even in these, we cannot form any 
 plausible hypothesis of the arrangement of the elements 5 
 and in other cases to which we naturally turn, we can 
 find nothing but confusion. For instance, if we examine 
 the oxides of metals : those of iron are rhombohedral 
 and tessular ; those of copper, tessular ; those of tin, 
 of titanium, of manganese, square pyramidal; those of 
 antimony, prismatic j and we have other forms for other 
 substances. 
 
 It may be added, that if we take account of the 
 
 sular forms, is the most signal example of that connexion between the 
 chemical nature of a body and its crystalline form, I in the former 
 Edition stated it with as much generality as I could find any ground 
 for, and I should have been glad if I could have added confirmation of 
 the law, derived from later observations. But the most recent investi- 
 gations of crystallographers appear to have afforded exceptions rather 
 than examples of the rule. Arsenic and Tellurium are said to be rkom- 
 bohedral. Antimony, stated by Haiiy to be octahedral (and therefore 
 tessular), has been found by more modern observers to be rhombohedral. 
 Tin has been obtained by Professor Miller in beautiful crystals belonging 
 to the pyramidal system. Professor Noggerath has observed in Zinc, 
 after cooling from fusion, hexagonal cleavage, rendering it probable that 
 the mineral crystallized in rhombohedrons having their axes vertical, 
 like ice. G. Rose conceives it highly probable that Osmium and 
 Iridium are rhombohedral. (Poggendorf. Bd. LIV.) 
 
 But all the more perfect metals are tessular ; namely, Gold, Silver, 
 Mercury, Platinum, Iron, Copper; also Bismuth. Perhaps the observa- 
 tion in which the crystallization of Zinc is affected by its position is, on 
 that very account, no sufficient evidence of its free crystallization. "We 
 can hardly conceive a collection of perfectly simple, similar particles to 
 crystallize so as to have one pre-eminent axis, without some extraneous 
 action affecting them. 
 
464 PHILOSOPHY OF MORPHOLOGY. 
 
 optical properties which, as we have already stated, have 
 constant relations to the crystalline forms, the confusion 
 is still further increased ; for the optical dimensions vary 
 in amount, though not in symmetry, where chemistry 
 can trace no difference of composition. 
 
 9. We will not quit the subject, however, without 
 noticing the much more promising aspect which it has 
 assumed by the detection of such groups as are referred 
 to in the last article ; or in other words, by Mitscher- 
 lich's discovery of Isomorphism. According to that dis- 
 covery, there are various elements which may take the 
 place of each other in crystalline bodies, either without 
 any alteration of the crystalline form, or at most with 
 only a slight alteration of its dimensions. Such a group 
 of elements we have in the earths lime and magnesia, 
 the protoxides of iron and manganese : for the carbo- 
 nates of all these bases occur crystallized in forms of 
 the rhombohedral system, the characteristic angle being 
 nearly the same in all. Now lime and magnesia, by 
 the discoveries of modern chemistry, are really oxides of 
 metals; and therefore all these carbonates have a similar 
 chemical constitution, while they have also a similar 
 crystalline form. Whether or no we can devise any 
 arrangement of molecules by which this connexion of 
 the chemical and the geometrical property can be repre- 
 sented, we cannot help considering the connexion as an 
 extremely important fact in the constitution of bodies ; 
 and such facts are more likely than any other to give 
 us some intelligible view of the relations of the ultimate 
 parts of bodies. The same may be said of all the other 
 isomorphous or plesiomorphous groups*. For instance, 
 we have a number of minerals which belong to the 
 same system of crystallization, but in which the chemical 
 composition appears at first sight to be very various: 
 * See Hist. hid. Set., B. xv. c. vi. 
 
SPECULATIONS ON THE SYMMETRY OF CRYSTALS. 465 
 
 namely, spinelle, pleonaste, gahnite, franklinite, chromic 
 iron oxide, magnetic iron oxide : but Abich has shown 
 that all these may be reduced to a common chemical 
 formula; they are bioxides of one set of bases, com- 
 bined with trioxides of another set. Perhaps some 
 mathematician may be able to devise some geometrical 
 arrangement of such a group of elements which may 
 possess the properties of the tessular system. Hypothe- 
 tical arrangements of atoms, thus expressing both the 
 chemical and the crystalline symmetry which we know 
 to belong to the substance, would be valuable steps in 
 analytical science; and when they had been duly verified, 
 the hypotheses might easily be divested of their atomic 
 character. 
 
 Thus, as we have already said, mineralogy, under- 
 stood in its wider sense, as the counterpart of chemistry, 
 has for one of its main objects to discover those relations 
 of the elements of bodies which have reference to space. 
 In this research, the foundation of all sound speculation 
 is the kind and degree of symmetry of form which we 
 find in definite chemical compounds : and the problem 
 at present before the inquirer is, to devise such arrange- 
 ments of molecules as shall answer the conditions alike 
 of chemistry and of crystallography. 
 
 We now proceed to the Classificatory Sciences, of 
 which Mineralogy is one, though hitherto by far the 
 least successful. 
 
 VOL. i. w. P. H H 
 
466 
 
 BOOK VIII. 
 
 THE PHILOSOPHY OF THE CLASSIFI- 
 C A TORY SCIENCES. 
 
 CHAPTER I. 
 
 THE IDEA OF LIKENESS AS GOVERNING THE 
 USE OF COMMON NAMES. 
 
 1. Object of the Chapter. NOT only the Classificatory 
 Sciences, but the application of names to things in the 
 rudest and most unscientific manner, depends upon our 
 apprehending them as like each other. We must there- 
 fore endeavour to trace the influence and operation of 
 the Idea of Likeness in the common use of language, 
 before we speak of the conditions under which it acquires 
 its utmost exactness and efficacy. 
 
 It will be my object to show in this, as in previous 
 cases, that the impressions of sense are apprehended by 
 acts of the mind ; and that these mental acts necessarily 
 imply certain relations which may be made the subjects 
 of speculative reasoning. We shall have, if we can, to 
 seize and bring into clear view the principles which the 
 relation of like and unlike involves, and the mode in 
 which these principles have been developed. 
 
 2. Unity of the Individual. But before we can attend 
 to several things as like or unlike, we must be able to 
 apprehend each of these by itself as one thing. It may at 
 first sight perhaps appear that this apprehension results 
 immediately from the impressions on our senses, without 
 
THE IDEA OF LIKENESS. 467 
 
 any act of our thoughts. A very little attention, how- 
 ever, enables us to see that thus to single out special 
 objects requires a mental operation as well as a sensation. 
 How, for example, without an exertion of mental activity, 
 can we see one tree, in a forest where there are many? We 
 have, spread before us, a collection of colours and forms, 
 green and brown, dark and light, irregular and straight : 
 this is all that sensation gives or can give. But we asso- 
 ciate one brown trunk with one portion of the green mass, 
 excluding the rest, although the neighbouring leaves are 
 both nearer in contiguity and more similar in appearance 
 than is the stem. We thus have before us one tree ; but 
 this unity is given by the mind itself. We see the green 
 and the brown, but we -must make the tree before we can 
 see it. 
 
 That this composition of our sensations so as to form 
 one thing implies an act of our own, will perhaps be 
 more readily allowed, if we once more turn our attention 
 to the manner in which we sometimes attempt to imitate 
 and record the objects of sight, by drawing. When we do 
 this, as we have already observed, we mark this unity of 
 each object, by drawing a line to separate the parts 
 which we include from those which we exclude; an 
 Outline. This line corresponds to nothing which we see ; 
 the beginner in drawing has great difficulty in discern- 
 ing it ; he has in fact to make it. It is, as has been said 
 by a painter of our own time*, a fiction: but it is a 
 fiction employed to mark a real act of the mind ; to 
 designate the singleness of the object in our conception. 
 As we have said elsewhere, we see lines, but especially 
 outlines, by mentally drawing them ourselves. 
 
 The same act of conception which the outline thus 
 represents and commemorates in visible objects, the 
 same combination of sensible impressions into a unit, is 
 
 * Phillips On Painting, Design. 
 
 HH2 
 
468 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 exercised also with regard to the objects of all our 
 senses : and the singleness thus given to each object, is 
 a necessary preliminary to its being named or repre- 
 sented in any other way. 
 
 But it may be said, Is it then by an arbitrary act of 
 our own that we put together the branches of the same 
 tree, or the limbs of the same animal ? Have we equally 
 the power and the right to make the branch of the fir a 
 part of the neighbouring oak ? Can we include in the 
 outline of a man any object with which he happens to 
 be in contact? 
 
 Such suppositions are manifestly absurd. And the 
 answer is, that though we give unity to objects by an 
 act of thought, it is not by an arbitrary act ; but by a 
 process subject to certain conditions ; to conditions 
 which exclude such incongruous combinations as have 
 just been spoken of. 
 
 What are these conditions which regulate our appre- 
 hension of an object as one? which determine what 
 portion of our impressions does, and what portion does 
 not belong to the same thing ? 
 
 3. Condition of Unity. I reply, that the primary and 
 fundamental condition is, that we must be able to make 
 intelligible assertions respecting the object, and to enter- 
 tain that belief of which assertions are the exposition. A 
 tree grows, sheds its leaves in autumn, and buds again in 
 the spring, waves in the wind, or falls before the storm. 
 And to the tree belong all those parts which must be 
 included in order that such declarations, and the thoughts 
 which they convey, shall have a coherent and permanent 
 meaning. Those are its branches which wave and fall with 
 its trunk ; those are its leaves which grow on its branches. 
 The permanent connexions which we observe, perma- 
 nent, among unconnected changes which affect the sur- 
 rounding appearances, are what we bind together as 
 
THE IDEA OF LIKENESS. 469 
 
 belonging to one object. This permanence is the condi- 
 tion of our conceiving the object as one. The connected 
 changes may always be described by means of assertions ; 
 and the connexion is seen in the identity of the subject 
 of successive predications ; in the possibility of applying 
 many verbs to one substantive. We may therefore ex- 
 press the condition of the unity of an object to be this : 
 that assertions concerning the object shall be possible : or 
 rather we should say, that the acts of belief which such 
 assertions enunciate shall be possible. 
 
 It may seem to be superfluous to put in a form so 
 abstract and remote, the grounds of a process apparently 
 so simple as our conceiving an object to be one. But 
 the same condition to which we have thus been led, as 
 the essential principle of the unity of objects, namely, 
 that propositions shall be possible, will repeatedly occur 
 in the present chapter ; and it may serve to illustrate our 
 views, to show that this condition pervades even the 
 simplest cases. 
 
 4. Kinds. The mental synthesis of which we have 
 thus spoken, gives us our knowledge of individual things; 
 it enables me to apprehend that particular tree or man 
 which I now see, or, by the help of memory, the tree or 
 the man I saw yesterday. But the knowledge with 
 which we have mainly here to do is not a knowledge of 
 individuals but of kinds; of such classes as are indicated 
 by common names. We have to make assertions con- 
 cerning a tree or a man in general, without regarding 
 what is peculiar to this man or that tree. 
 
 Now it is clear that certain individual objects are all 
 called man, or all called tree, in virtue of some resem- 
 blance which they have. If we had not the power of 
 perceiving in the appearances around us, likeness and 
 unlikeness, we could not consider objects as distributed 
 into kinds at all. The impressions of sense would throng 
 
470 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 upon us, but being uncompared with each other, they 
 would flow away like the waves of the sea, and each 
 vanish from our contemplation when the sensation faded. 
 That we do apprehend surrounding objects as belonging 
 to permanent kinds, as being men and horses, oaks and 
 roses, arises from our having the idea of likeness, and 
 from our applying it habitually, and so far as such a 
 classification requires. 
 
 Not only can we employ the idea of likeness in this 
 manner, but we apply it incessantly and universally to 
 the whole mass and train of our sensations. For we have 
 no external sensations to which we cannot apply some 
 language or other, and all language necessarily implies 
 recognition of resemblances. We cannot call an object 
 green or round without comparing in our thoughts its 
 colour or its shape, with a shape and a colour seen in 
 other objects. All our sensations, therefore, without any 
 exception of kind or time, are subject to this constant 
 process of classification ; and the idea of likeness is per- 
 petually operating to distribute them into kinds, at least 
 so far as the use of language requires. 
 
 We come then again to the question, Upon what 
 principle, under what conditions, is the idea of likeness 
 thus operative ? What are the limits of the classes thus 
 formed ? Where does that similarity end, which induces 
 and entitles us to call a thing a tree ? What universal 
 rule is there for the application of common names, so 
 that we may not apply them wrongly ? 
 
 5. Not made by Definitions. Perhaps some one might 
 expect in answer to these inquiries a definition or a series 
 of definitions ; might imagine that some description of a 
 tree might be given which might show when the term 
 was applicable and when it was not ; and that we might 
 construct a body of rules to which such descriptions must 
 conform. But on consideration it will be clear that the 
 
THE IDEA OF LIKENESS. 471 
 
 real solution of our difficulty cannot be obtained in such 
 a manner. For first ; such descriptions must be given in 
 words, and therefore suppose that we have already satis- 
 fied ourselves how words are to be used. If we define a 
 tree to be " a living thing without the power of voluntary 
 motion," we shall be called upon to define "a living 
 thing;" and it is manifest that this renewal of the demand 
 for definition might be repeated indefinitely ; and, there- 
 fore, we cannot in this way come to a final principle. And 
 in the next place, most of those who use language, even 
 with great precision and consistency, would find it diffi- 
 cult or impossible to give good definitions even of a few 
 of the general names which they use; and therefore 
 their practice cannot be regulated by any tacit reference 
 to such definitions. That definitions of terms are of 
 great use and importance in their right place, we shall 
 soon see; but their place is not to regulate the use of 
 common language. 
 
 What then, once more, is this regulative principle? 
 What rules do men follow in the use of words, so as 
 commonly to avoid confusion and ambiguity? How do 
 they come to understand each other so well as they 
 ordinarily do, respecting the limits of classes never de- 
 fined, and which they cannot define ? What is the com- 
 mon Convention, or Condition to which they conform ? 
 
 6. Condition of the Use of Terms. To this we reply, 
 that the Condition which regulates the use of language, 
 is that it shall be capable of being used ; that is, that 
 general assertions shall be possible. The term tree is 
 applicable as far as it is useful in expressing our know- 
 ledge concerning trees: thus we know that trees are 
 fixed in the ground, have a solid stem, branches, leaves, 
 and many other properties. With regard to all the 
 objects which surround us, we have an immense store of 
 
472 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 knowledge of such properties, and we employ the names 
 of the objects in such a manner as enables us to express 
 these properties. 
 
 But the connexion of such properties is variable and 
 indefinite. Some properties are constantly combined, 
 others occasionally only. The leaves of different oaks 
 resemble each other, the branches resemble far less, and 
 may differ very widely. The term oak does not enable 
 us to say that all oaks have straight branches or all 
 crooked. Terms can only express properties as far as 
 they are constant. Not only, therefore, the accumula- 
 tion of a vast mass of knowledge of the properties and 
 attributes of objects, but also an observation of the 
 habitual connexion of such properties is needed, to direct 
 us to the consistent application of terms : to enable us 
 to apply them so as to express truths. But here again 
 we are largely provided with the requisite knowledge 
 and observation by the common course of our existence. 
 The unintermitting stream of experience supplies us 
 with an incalculable amount of such observed connex- 
 ions. All men have observed that the associations of 
 the same form of leaves are more constant than of the 
 same form of branches ; that though persons walk in 
 different attitudes none go on all fours; and thus the 
 term oak is so applied as to include those cases in 
 which the leaves are alike in form though the branches 
 be unlike ; and though we should refuse to apply the 
 term man to a class of creatures which habitually 
 and without compulsion used four legs, we make no 
 scruple of affixing it to persons of very different figures. 
 The whole of human experience being composed of such 
 observed connexions, we have thus materials even for 
 the immense multiplicity of names which human lan- 
 guage contains; all which names are, as we have said, 
 
THE IDEA OF LIKENESS. 473 
 
 regulated in their application by the condition of ex- 
 pressing such experience. 
 
 Thus amid the countless combinations of properties 
 and divisions of classes which the structure of language 
 implies, scarcely any are arbitrary or capricious. A word 
 which expressed a mere wanton collection of unconnected 
 attributes could hardly be called a word ; for of such a 
 collection of properties no truth could be asserted, and 
 the word would disappear, for want of some occasion on 
 which it could be used. Though much of the fabric of 
 language appears, not unnaturally, fantastical and purely 
 conventional, it is in fact otherwise. The associations 
 and distinctions of phraseology are not more fanciful than 
 is requisite to make them correspond to the apparent 
 caprices of nature or of thought ; and though much in 
 language may be called conventional, the conventions 
 exist for the sake of expressing some truth or opinion, 
 and not for their own sake. The principle, that the con- 
 dition of the use of terms is the possibility of general, 
 intelligible, consistent assertions, is true in the most 
 complete and extensive sense. 
 
 7. Terms may have different Uses. The Terms with 
 which we are here most concerned are Names of Classes 
 of natural objects ; and when we say that the principle 
 and the limit of such Names are their use in expressing 
 propositions concerning the classes, it is clear that much 
 will depend on the kind of propositions which we mainly 
 have to express : and that the same name may have 
 different limits, according to the purpose we have in view. 
 For example, is the whale properly included in the 
 general term fish f When men are concerned in catching 
 marine animals, the main features of the process are the 
 same however the animals may differ ; hence whales are 
 classed with fishes, and we speak of the whale-fishery. 
 But if we look at the analogies of organization, we find 
 
474 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 that, according to these, the whale is clearly not a fish, but 
 a beast, (confining this term, for the sake of distinctness, to 
 suckling beasts or mammals). In Natural History, there- 
 fore, the whale is not included among fish. The indefi- 
 nite and miscellaneous propositions which language is 
 employed to enunciate in the course of common practical 
 life, are replaced by a more coherent and systematic col- 
 lection of properties, when we come to aim at scientific 
 knowledge. But we shall hereafter consider the principle 
 of the classifications of Natural History ; our present 
 subject is the application of the Idea of Likeness in 
 common practice and common language. 
 
 8. Gradation of Kinds. Common names, then, in- 
 clude many individuals associated in virtue of resem- 
 blances, and of permanently connected properties ; and 
 such names are applicable as far as they serve to express 
 such properties. These collections of individuals are 
 termed Kinds, Sorts, Classes. 
 
 But this association of particulars is capable of degrees. 
 As individuals by their resemblances form Kinds, so kinds 
 of things, though different, may resemble each other so as 
 to be again associated in a higher Class; and there may 
 be several successive steps of such classification. Man, 
 horse, tree, stone, are each a name of a Kind ; but animal 
 includes the two first and excludes the others; living 
 thing is a term which includes animal and tree but not 
 stone; body includes all the four. And such a subordi- 
 nation of kinds may be traced very widely in the arrange- 
 ments of language. 
 
 The condition of the use of the wider is the same as 
 that of the narrower Names of Classes ; they are good 
 as far as they serve to express true propositions. In 
 common language, though such an order of generality 
 may in a variety of instances be easily discerned, it is 
 not systematically and extensively referred to ; but this 
 
THE IDEA OF LIKENESS. 475 
 
 subordination and graduated comprehensiveness is the 
 essence of the methods and nomenclatures of Natural 
 History, as we shall soon have to show. 
 
 But such subordination is not without its use, even in 
 common cases, and when it is expressed in the terms of 
 common language. Thus organized body is a term which 
 includes plants and animals; animal includes beasts, 
 birds, fishes; beast includes horses and dogs; dogs, again, 
 are greyhounds, spaniels, terriers. 
 
 9. Characters of Kinds. Now when we have such a 
 Series of Names and Classes, we find that we take for 
 granted irresistibly that each class has some character 
 which distinguishes it from other classes included in the 
 superior division. We ask what kind of beast a dog is ; 
 what kind of animal a beast is ; and we assume that such 
 questions admit of answer ; that each kind has some 
 mark or marks by which it may be described. And such 
 descriptions may be given: an animal is an organized 
 body having sensation and volition ; man is a reasonable 
 animal. Whether or no we assent to the exactness of 
 these definitions, we allow the propriety of their form. 
 If we maintain these to be wrong, we must believe some 
 others to be right, however difficult it may be to hit 
 upon them. We entertain a conviction that there must 
 be, among things so classed and named, a possibility of 
 defining each. 
 
 Now what is the foundation of this postulate ? What 
 is the ground of this assumption, that there must exist a 
 definition which we have never seen, and which perhaps 
 no one has seen in a satisfactory form ? The knowledge 
 of this definition is by no means necessary to our using 
 the word with propriety; for any one can make true asser- 
 tions about dogs, but who can define a dog? And yet if 
 the definition be not necessary to enable us to use the 
 word, why is it necessary at all? I allow that we pos- 
 
476 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 sess an indestructible conviction that there must be such 
 a character of each kind as will supply a definition ; but 
 I ask, on what this conviction rests. 
 
 I reply, that our persuasion that there must needs be 
 characteristic marks by which things can be defined in 
 words, is founded on the assumption of the necessary 
 possibility of reasoning. 
 
 The reference of any object or conception to its class 
 without definition, may give us a persuasion that it 
 shares the properties of its class, but such classing does 
 not enable us to reason upon those properties. When 
 we consider man as an animal, we ascribe to him in 
 thought the appetites, desires, affections, which we 
 habitually include in our notion of animal : but except 
 we have expressed these in some definition or acknow- 
 ledged description of the term animal, we can make no 
 use of the persuasion in ratiocination. But if we have 
 described animals as " beings impelled to action by appe- 
 tites and passions," we can not only think, but say, " man 
 is an animal, and therefore he is impelled to act by 
 appetites and passions." And if we add a further defi- 
 nition, that "man is a reasonable animal," and if it ap- 
 pear that " reason implies conformity to a rule of action," 
 we can then further infer that man's nature is to con- 
 form the results of animal appetite and passion to a rule 
 of action. 
 
 The possibility of pursuing any such train of reason- 
 ing as this, depends on the definitions, of animal and of 
 man, which we have introduced ; and the possibility of 
 reasoning concerning the objects around us being inevit- 
 ably assumed by us from the constitution of our nature, 
 we assume consequently the possibility of such defini- 
 tions as may thus form part of our deduction, and the 
 existence of such defining characters. 
 
 10. Difficulty of Definitions. But though men are, 
 
THE IDEA OF LIKENESS. 477 
 
 on such grounds, led to make constant and importunate 
 demands for definitions of the terms which they employ 
 in their speculations, they are, in fact, far from being 
 able to carry into complete effect the postulate on which 
 they proceed, that they must be able to find definitions 
 which by logical consequence shall lead to the truths 
 they seek. The postulate overlooks the process by which 
 our classes of things are formed and our names applied. 
 This process consisting, as we have already said, in 
 observing permanent connexions of properties, and in 
 fixing them by the attribution of names, is of the nature 
 of the process of induction, of which we shall afterwards 
 have to speak. And the postulate is so far true, that 
 this process of induction being once performed, its result 
 may usually be expressed by means of a few definitions, 
 and may thus lead by a deduction to a train of real 
 truths. 
 
 But in the subjects where we principally find such a 
 subordination of classes as we have spoken of, this pro- 
 cess of deduction is rarely of much prominence : for 
 example, in the branches of natural history. Yet it is 
 in these subjects that the existence and importance of 
 these characteristic marks, which we have spoken of, 
 principally comes into view. In treating of these marks, 
 however, we enter upon methods which are technical 
 and scientific, not popular and common. And before 
 we make this transition, we have a remark to make on 
 the manner in which writers, without reference to phy- 
 sics or natural history, have spoken of kinds, their sub- 
 ordination, and their marks. 
 
 11. "The Five Words." These things, the nature 
 and relations of classes, were, in fact, the subjects of 
 minute and technical treatment by the logicians of the 
 school of Aristotle. Porphyry wrote an Introduction to 
 the Categories of that philosopher, which is entitled On 
 
478 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 the Five Words. The " Five Words" are Genus, Species, 
 Difference, Property, Accident. Genus and Species are 
 superior and inferior classes, and are stated* to be ca- 
 pable of repeated subordination. The "most general 
 Genus" is the widest class, the "most special Species" 
 the narrowest. Between these are intermediate classes, 
 which are Genera with regard to those below, and Spe- 
 cies with regard to those above them. Thus Being is 
 the most general Genus ; under this is Body ; under 
 Body is Living Body ; under this again Animal ; under 
 Animal is Rational Animal, or Man ; under Man are 
 Socrates and Plato, and other individual men. 
 
 The Difference is that which is added to the genus 
 to make the species ; thus Rational is the Difference by 
 which the genus Animal is made the species Man ; the 
 Difference in this Technical sense is the "Specific," or 
 species-making Difference f. It forms the Definition for 
 the purposes of logic, and corresponds to the " Charac- 
 ter" (specific or generic) of the Natural Historians. 
 Indeed several of them, as, for instance, Linnaeus, in his 
 Philosophia Botanica, always call these Characters the 
 Difference, by a traditional application of the Peripatetic 
 terms of art. 
 
 Of the other two words, the Property is that which 
 though not employed in defining the class, belongs to 
 every part of it;); : it is, " What happens to all the class, 
 to it alone, and at all times ; as to be capable of laugh- 
 ing is a property of a man." 
 
 The Accident is that which may be present and ab- 
 sent without the destruction of the subject, as to sleep 
 is an Accident (a thing which happens) to man. 
 
 I need not dwell further on this system of techni- 
 calities. The most remarkable points in it are those 
 which I have already noticed ; the doctrine of the suc- 
 
 * Porpliyr. Isagog. c. 23. t ei'Sowoio?. + Isagog. c. 4. 
 
THE IDEA OF LIKENESS. 479 
 
 cessive subordination of genera, and the fixing attention 
 upon the specific difference. These doctrines, though 
 invented in order to make reasoning more systematic, 
 and at a period anterior to the existence of any classi- 
 ficatory science, have, by a curious contrast with the 
 intentions of their founders, been of scarcely any use in 
 sciences of reasoning, but have been amply applied and 
 developed in the Natural History which arose in later 
 times. We must now treat of the principles on which 
 this science proceeds, and explain what peculiar and 
 technical processes it employs in addition to those of 
 common thought and common language. 
 
 CHAPTER II. 
 
 THE METHODS OF NATURAL HISTORY, AS 
 REGULATED BY THE IDEA OF LIKENESS. 
 
 SECT. I. Natural History in general. 
 
 1. Idea of Likeness in Natural History. THE 
 various branches of Natural History, in so far as they 
 are classificatory sciences merely, and do not depend 
 upon physiological views, rest upon the same Idea of 
 Likeness which is the ground of the application of the 
 names, more or less general, of common language. But 
 the nature of science requires that for her purposes this 
 idea should be applied in a more exact and rigorous 
 manner than in its common and popular employment; 
 just as occurs with regard to the other Ideas on which 
 science is founded ; for instance, as the idea of space 
 gives rise, in popular use, to the relations implied in the 
 prepositions and adjectives which refer to position and 
 
480 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 form, and in its scientific developement gives rise to the 
 more precise relations of geometry. 
 
 The way in which the Idea of Likeness has been 
 applied, so as to lead to the construction of a science, is 
 best seen in Botany: for, in the Classification of Ani- 
 mals, we are inevitably guided by a consideration of the 
 function of parts ; that is, by an idea of purpose, and not 
 of likeness merely : and in Mineralogy, the attempts at 
 classification on the principles of Natural History have 
 been hitherto very imperfectly successful. But in Botany 
 we have an example of a branch of knowledge in which 
 systematic classification has been effected with great 
 beauty and advantage ; and in which the peculiarities 
 and principles on which such classification must depend 
 have been carefully studied. Many of the principal 
 botanists, as Linnaeus, Adanson, Decandolle, have not 
 only practically applied, but have theoretically enun- 
 ciated, what they held to be the sound maxims of classi- 
 ficatory science : and have thus enabled us to place 
 before the reader with confidence the philosophy of this 
 kind of science. 
 
 2. Condition of its Use. We may begin by remark- 
 ing that the Idea of Likeness, in its systematic employ- 
 ment, is governed by the same principle which we have 
 already spoken of as regulating the distribution of things 
 into kinds, and the assignment of names in unsystematic 
 thought and speech ; namely, the condition that general 
 propositions shall be possible. But as in this case the 
 propositions are to be of a scientific form and exactness, 
 the likeness must be treated with a corresponding pre- 
 cision; and its consequences traced by steady and dis- 
 tinct processes. Naturalists must, for their purposes, 
 employ the resemblances of objects in a technical man- 
 ner. This technical process may be considered as con- 
 sisting of three steps ; The fixation of the resemblances ; 
 
METHODS OF NATURAL HISTORY. 481 
 
 The use of them in making a classification ; The means 
 of applying the classification. These three steps may be 
 spoken of as the Terminology, the Plan of the System, 
 and the Scheme of the Characters. 
 
 SECT. II. Terminology*. 
 
 3. Terminology signifies the collection of terms, or 
 technical words, which belong to the science. But in 
 fixing the meaning of the terms, at least of the descrip- 
 tive terms, we necessarily fix, at the same time, the per- 
 ceptions and notions which the terms are to convey; 
 and thus the Terminology of a classificatory science 
 exhibits the elements of its substance as well as of its 
 language. A large but indispensable part of the study 
 of botany (and of mineralogy and zoology also,) con- 
 sists in the acquisition of the peculiar vocabulary of the 
 science. 
 
 The meaning of technical terms can be fixed in the 
 first instance only by convention, and can be made intel- 
 ligible only by presenting to the senses that which the 
 terms are to signify. The knowledge of a colour by its 
 name can only be taught through the eye. No descrip- 
 tion can convey to a hearer what we mean by apple- 
 green or French grey. It might, perhaps, be supposed 
 that, in the first example, the term apple, referring to 
 so familiar an object, sufficiently suggests the colour 
 intended. But it may easily be seen that this is not 
 true; for apples are of many different hues of green> 
 and it is only by a conventional selection that we can 
 
 * Decandolle and others use the term Glossology instead of Termi- 
 nology ', to avoid the blemish of a word compounded of two parts taken 
 from different languages. The convenience of treating the termination 
 ology (and a few other parts of compounds) as not restricted to Greek 
 combinations, is so great, that I shall venture, in these cases, to dis- 
 regard this philological scruple. 
 
 VOL. I. W. P. 1 1 
 
482 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 appropriate the term to one special shade. When this 
 appropriation is once made, the term refers to the sen- 
 sation, and not to the parts of the term ; for these enter 
 into the compound merely as a help to the memory, 
 whether the suggestion be a natural connexion as in 
 " apple-green," or a casual one as in " French grey." In 
 order to derive due advantage from technical terms of 
 this kind, they must be associated immediately with the 
 perception to which they belong; and not connected 
 with it through the vague usages of common language. 
 The memory must retain the sensation ; and the techni- 
 cal word must be understood as directly as the most 
 familiar word, and more distinctly. When we find such 
 terms as tin-white or pinchbeck-brown, the metallic 
 colour so denoted ought to start up in our memory 
 without delay or search. 
 
 This, which it is most important to recollect with 
 respect to the simpler properties of bodies, as colour and 
 form, is no less true with respect to more compound 
 notions. In all cases the term is fixed to a peculiar 
 meaning by convention ; and the student, in order to use 
 the word, must be completely familiar with the conven- 
 tion, so that he has no need to frame conjectures from 
 the word itself. Such conjectures would always be inse- 
 cure, and often erroneous. Thus the term papilionace- 
 ous, applied to a flower, is employed to indicate, not only 
 a resemblance to a butterfly, but a resemblance arising 
 from five petals of a certain peculiar shape and arrange- 
 ment ; and even if the resemblance were much stronger 
 than it is in such cases, yet if it were produced in a 
 different way, as, for example, by one petal, or two only, 
 instead of a " standard," two " wings," and a " keel" con- 
 sisting of two parts more or less united into one, we 
 should no longer be justified in speaking of it as a "pa~ 
 pilionaceous" flower. 
 
METHODS OF NATURAL HISTORY. 483 
 
 The formation of an exact and extensive descriptive 
 language for botany has been executed with a degree of 
 skill and felicity, which, before it was attained, could 
 hardly have been dreamt of as attainable. Every part 
 of a plant has been named ; and the form of every part, 
 even the most minute, has had a large assemblage of 
 descriptive terms appropriated to it, by means of which 
 the botanist can convey and receive knowledge of form 
 and structure, as exactly as if each minute part were 
 presented to him vastly magnified. This acquisition was 
 part of the Linnaean reform, of which we have spoken in 
 the History. " Tournefort," says Decandolle*, "appears 
 to have been the first who really perceived the utility of 
 fixing the sense of terms in such a way as always to 
 employ the same word in the same sense, and always to 
 express the same idea by the same word; but it was 
 Linnaeus who really created and fixed this botanical lan- 
 guage, and this is his fairest claim to glory, for by this 
 fixation of language he has shed clearness and precision 
 over all parts of the science." 
 
 It is not necessary here to give any detailed account 
 of the terms of botany. The fundamental ones have 
 been gradually introduced, as the parts of plants were 
 more carefully and minutely examined. Thus the flower 
 was successively distinguished into the calyx, the corolla, 
 the stamens, and the pistils : the sections of the corolla 
 were termed petals by Columna ; those of the calyx were 
 called sepals by Neckerf. Sometimes terms of greater 
 generality were devised ; as perianth to include the calyx 
 and corolla, whether one or both of these were present J; 
 pericarp for the part inclosing the grain, of whatever 
 kind it be, fruit, nut, pod, &c. And it may easily be 
 imagined that descriptive terms may, by definition and 
 
 * Theor. Elem., p. 327. t Dec. 329. 
 
 For this Erhart and Decaudollc use Peri-gone. 
 
 112 
 
484 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 combination, become very numerous and distinct. Thus 
 leaves may be called pinnatifid*> pinnatipdrtite, pinna- 
 tisect, pinnatilobate, palmatifid, palmatipartite, &c., and 
 each of these words designates different combinations of 
 the modes and extent of the divisions of the leaf with 
 the divisions of its outline. In some cases arbitrary 
 numerical relations are introduced into the definition: 
 thus a leaf is called Ulobate\ when it is divided into two 
 parts by a notch ; but if the notch go to the middle of 
 its length, it is Ufid ; if it go near the base of the leaf, 
 it is bipartite ; if to the base, it is bisect. Thus, too, a 
 pod of a cruciferous plant is a silica J if it be four times 
 as long as it is broad, but if it be shorter than this it is 
 a silicula. Such terms being established, the form of 
 the very complex leaf or frond of a fern is exactly con- 
 veyed by the following phrase : " fronds rigid pinnate, 
 pinnse recurved subunilateral pinnatifid, the segments 
 linear undivided or bifid spinuloso-serrate $." 
 
 Other characters, as well as form, are conveyed with 
 the like precision : Colour by means of a classified scale 
 of colours, as we have seen in speaking of the measures 
 of secondary qualities ; to which, however, we must add, 
 that the naturalist employs arbitrary names, (such as we 
 have already quoted,) and not mere numerical exponents, 
 to indicate a certain number of selected colours. This 
 was done with most precision by Werner, and his scale 
 of colours is still the most usual standard of naturalists. 
 Werner also introduced a more exact terminology with 
 regard to other characters which are important in mine- 
 ralogy, as lustre, hardness. But Mohs improved upon 
 this step by giving a numerical scale of hardness, in 
 which talc is 1, gypsum 2, calc spar 3, and so on, as 
 
 * Dec. 318. t Ib. 493. J Ib. 422. 
 
 Hooker, Brit. Flo., p. 450. Hymenophyllum Wilsoni, Scottish 
 filmy-fern, abundant in the Highlands of Scotland and about Killarney. 
 
METHODS OF NATURAL HISTORY. 485 
 
 we have already explained in the History of Mineralogy. 
 Some properties, as specific gravity, by their definition 
 give at once a numerical measure ; and others, as crys- 
 talline form, require a very considerable array of mathe- 
 matical calculation and reasoning, to point out their 
 relations and gradations. In all cases the features of 
 likeness in the objects must be rightly apprehended, in 
 order to their being expressed by a distinct terminology. 
 Thus no terms could describe crystals for any purpose 
 of natural history, till it was discovered that in a class 
 of minerals the proportion of the faces might vary, 
 while the angle remained the same. Nor could crystals 
 be described so as to distinguish species, till it was found 
 that the derived arid primitive forms are connected by 
 very simple relations of space and number. The dis- 
 covery of the mode in which characters must be appre- 
 hended so that they may be considered as fixed for a 
 class, is an important step in the progress of each branch 
 of Natural History ; and hence we have had, in the 
 History of Mineralogy and Botany, to distinguish as 
 important and eminent persons those who made such dis- 
 coveries, Rome de Lisle and Haiiy, Cesalpinus and Gesner. 
 By the continued progress of that knowledge of 
 minerals, plants, and other natural objects, in which such 
 persons made the most distinct and marked steps, but 
 which has been constantly advancing in a more gradual 
 and imperceptible manner, the most important and 
 essential features of similarity and dissimilarity in such 
 objects have been selected, arranged, and fitted with 
 names ; and we have thus in such departments, systems 
 of Terminology which fix our attention upon the re- 
 semblances which it is proper to consider, and enable 
 us to convey them in words. We have now to speak of 
 the mode in which such resemblances have been em- 
 ployed in the construction of a Systematic Classification. 
 
486 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 SECT. III. The Plan of the System. 
 
 4. The collection of sound views and maxims by 
 Avhich the resemblances of natural objects are applied so 
 as to form a scientific classification, is a department of 
 the philosophy of natural history which has been termed 
 by some writers (as Decandolle,) Taxonomy, as contain- 
 ing the Laws of the Taxis, (arrangement). By some 
 Germans this has been denominated Systematik ; if we 
 could now form a new substantive after the analogy of 
 the words Logick, Rhetorick, and the like, we might call 
 it Systematick. But though our English writers com- 
 monly use the expression Systematical Botany for the 
 Botany of Classification, they appear to prefer the term 
 Diatoms for the method of constructing the classifica- 
 tion. The rules of such a branch of science are curious 
 and instructive. 
 
 In framing a Classification of objects we must attend 
 to their resemblances and differences. But here the 
 question occurs, to what resemblances and differences? 
 for a different selection of the points of resemblance 
 would give different results : a plant frequently agrees 
 in leaves with one group of plants, in flowers with an- 
 other. Which set of characters are we to take as our 
 guide ? 
 
 The view already given of the regulative principle of 
 all classification, namely, that it must enable us to assert 
 true and general propositions, will obviously occur as 
 applicable here. The object of a scientific Classification 
 is to enable us to enunciate scientific truths : we must 
 therefore classify according to those resemblances of 
 objects (plants or any others,) which bring to light such 
 truths. 
 
 But this reply to the inquiry, " On what characters 
 of resemblance we are to found our system," is still too 
 

 METHODS OF NATURAL HISTORY. 487 
 
 general and vague to be satisfactory. It carries us, 
 however, as far as this ; that since the truths we are to 
 attend to are scientific truths, governed by precise and 
 homogeneous relations, we must not found our scientific 
 Classification on casual, indefinite, and unconnected con- 
 siderations. We must not, for instance, be satisfied with 
 dividing plants, as Dioscorides does, into aromatic, escu- 
 lent, medicinal, and vinous ; or even with the long pre- 
 valent distribution into trees, shrubs, and herbs; since 
 in these subdivisions there is no consistent principle. 
 
 5. Latent Reference to Natural Affinity. But there 
 may be several kinds of truths, all exact and coherent, 
 which may be discovered concerning plants or any other 
 natural objects ; and if this should be the case, our rule 
 leaves us still at a loss in what manner our classification 
 is to be constructed. And, historically speaking, a much 
 more serious inconvenience has been this; that the 
 task of classification of plants was necessarily performed 
 when the general laws of their form and nature were 
 very little known ; or rather, when the existence of such 
 laws was only just beginning to be discerned. Even 
 up to the present day, the general propositions which 
 botanists are able to assert concerning the structure 
 and properties of plants, are extremely imperfect and 
 obscure. 
 
 We are thus led to this conclusion : that the Idea of 
 Likeness could not be applied so as to give rise to a 
 scientific Classification of plants, till considerable pro- 
 gress was made in studying the general relations of 
 vegetable form and life ; and that the selection of the 
 resemblances which should be taken into account, must 
 depend upon the nature of the relations which were then 
 brought into view. 
 
 But this amounts to saying that, in the consideration 
 of the Classification of vegetables, other Ideas must be 
 
488 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 called into action as well as the Idea of Likeness. The 
 additional general views to which the more intimate 
 study of plants leads, must depend, like all general 
 truths, upon some regulating Idea which gives unity to 
 scattered facts. No progress could be made in botanical 
 knowledge without the operation of such principles : and 
 such additional Ideas must be employed, besides those 
 of mere likeness and unlikeness, in order to point out 
 that Classification which has a real scientific value. 
 
 Accordingly, in the classificatory sciences, Ideas other 
 than Likeness do make their appearance. Such Ideas 
 in botany have influenced the progress of the science, 
 even before they have been clearly brought into view. 
 We have especially the Idea of Affinity, which is the 
 basis of all Natural Systems of Classification, and which 
 we shall consider in a succeeding chapter. The assump- 
 tion that there is a Natural System, an assumption made 
 by all philosophical botanists, implies a belief in the 
 existence of Natural Affinity, and is carried into effect 
 by means of principles which are involved in that Idea. 
 But as the formation of all systems of classification must 
 involve, in a great degree, the Idea of Resemblance and 
 Difference, I shall first consider the effect of that Idea, 
 before I treat specially of Natural Affinity. 
 
 6. Natural Classes. Many attempts were made to 
 classify vegetables before the rules which govern a natu- 
 ral system were clearly apprehended. Botanists agree 
 in esteeming some characters as of more value than 
 others, before they had agreed upon any general rules 
 or principles for estimating the relative importance of 
 the characters. They were convinced of the necessity 
 of adding other considerations to that of Resemblance, 
 without seeing clearly what these others ought to be. 
 They aimed at a Natural Classification, without knowing 
 distinctly in what manner it was to be Natural. 
 
METHODS OF NATURAL HISTORY. 489 
 
 The attempts to form Natural Classes, therefore, in 
 the first part of their history, belong to the Idea of Like- 
 ness, though obscurely modified, even from an early 
 period, by the Ideas of Affinity, and even of Function 
 and of Developement. Hence Natural Classes may, to 
 a certain extent, be treated of in this place. 
 
 Natural Classes are opposed to Artificial Classes 
 which are understood to be regulated by an assumed 
 character. Yet no classes can be so absolutely Artificial 
 in this sense, as to be framed upon characters arbitra- 
 rily assumed; for instance, no one would speak of a 
 class of shrubs defined by the circumstance of each hav- 
 ing a hundred leaves : for of such a class no assertion 
 could be made, and 'therefore the class could never come 
 under our notice. In what sense then are Artificial 
 Classes to be understood, as opposed to Natural ? 
 
 7. Artificial Classes. To this question, the follow- 
 ing is the answer. When Natural Classes of a certain 
 small extent have been formed, a system may be devised 
 which shall be regulated by a few selected characters, 
 and which shall not dissever these small Natural Classes, 
 but conform to them as far as they go. If these selected 
 characters b6 then made absolute and imperative, and if 
 we abandon all attempt to obtain Natural Classes of any 
 higher order and wider extent, we form an Artificial 
 System. 
 
 Thus in the Linnsean System of Botanical Classifica- 
 tion, it is assumed that certain natural groups, namely, 
 Species and Genera, are established; it is conceived, 
 moreover, that the division of Classes according to the 
 number of stamens and of pistils does not violate the 
 natural connexions of Species and Genera. This arrange- 
 ment, according to the number of stamens and pistils, 
 (further modified in certain cases by other considera- 
 tions,) is then made the ground of all the higher 
 
490 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 divisions of plants, and thus we have an Artificial 
 System. 
 
 It has been objected to this view, that the Linnsean 
 Artificial System does not in all cases respect the boun- 
 daries of genera, but would, if rigorously applied, dis- 
 tribute the species of the same genus into different 
 artificial classes ; it would divide, for instance, the genera 
 Valeria/no, Geranium*, &c. To this we must reply, 
 that so far as the Linnsean System does this, it is an 
 imperfect Artificial System. Its great merit is in its 
 making such a disjunction in comparatively so few cases; 
 and in the artificial characters being, for the most part, 
 obvious and easily applied. 
 
 8. Are Genera Natural f It has been objected also 
 that Genera are not Natural groups. Linnaeus asserts 
 in the most positive manner that they aref. On which 
 Adanson observes J, " I know not how any Botanist can 
 maintain such a thesis : that which is certain is, that up 
 to the present time no one has been able to prove it, nor 
 to give an exact definition of a natural genus, but only 
 of an artificial." He then brings several arguments to 
 confirm this view. 
 
 But we are to observe, in answer to this, that 
 Adanson improperly confounds the recognition of the 
 existence of a natural group with the invention of a 
 technical mark or definition of it. Genera are groups 
 of species associated in virtue of natural affinity, of gene- 
 ral resemblance, of real propinquity: of such groups, 
 certain selected characters, one or few, may usually be 
 discovered, by which the species may be referred to their 
 groups. These Artificial characters do not constitute, 
 but indicate the genus : they are the Diagnosis, not the 
 basis of the Diataxis: and they are always subject to be 
 
 * Decand. Ttieor. Elem., p. 45. f Phil. Bot., Art. 165. 
 
 $ Famille de Ph., Pref. cv. 
 
METHODS OF NATURAL HISTORY.. 491 
 
 rejected, and to have others substituted for them, when 
 they violate the natural connexion of species which a 
 minute and enlarged study discovers. 
 
 It is, therefore, no proof that Genera are not Natural, 
 to say that their artificial characters are different in dif- 
 ferent systems. Such characters are only different at- 
 tempts to confine the variety of nature within the limits 
 of definition. Nor is it sufficient to say that these groups 
 themselves are different in different writers ; that some 
 botanists make genera what others make only species ; 
 as Pedicular is, Rhinantlius, Euphrasia, Antirrhinum*. 
 This discrepancy shows only that the natural arrange- 
 ment is not yet completely known, even in the smaller 
 groups ; a conclusion to which we need not refuse our 
 assent. But in opposition to these negatives, the man- 
 ner in which Genera have been established proves that 
 they are regulated by the principle of being natural, and 
 by that alone. For they are not formed according to any 
 d priori rule. The Botanist does not take any selected 
 or arbitrary part or parts of the plants, and marshal his 
 genera according to the differences of this part. On the 
 contrary, the divisions of genera are sometimes made by 
 means of the flower ; sometimes by means of the fruit : 
 the anthers, the stamens, the seeds, the pericarp, and 
 the most varied features of these parts, are used in the 
 most miscellaneous and unsystematic manner. Linnaeus 
 has indeed laid down a maxim that the characteristic 
 differences of genera must reside in the fructification f : 
 but Adanson has justly remarked J, that an arbitrary 
 restriction like this makes the groups artificial: and 
 that in some families other characters are more essen- 
 tial than those of the fructification ; as the leaves in the 
 families of Aparinece and Leguminosce, and the disposi- 
 
 * Adanson, p. cvi. t Phil Bot., Art. 162. 
 
 J Adanson, Pref., p. cxx. 
 
492 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 tion of the flowers in Labiates. And Naturalists are so 
 far from thinking it sufficient to distribute species into 
 genera by arbitrary marks, that we find them in many 
 cases lamenting the absence of good natural marks : as 
 in the families of Umbelliferce, where Linnaeus declared 
 that any one who could find good characters of genera 
 would deserve great admiration, and where it is only of 
 late that good characters have been discovered and the 
 arrangement settled* by means principally of the ribs of 
 the fruit f. 
 
 It is thus clear that Genera are not established on 
 any assumed or preconceived basis. What, then, is the 
 principle which regulates botanists when they try to fix 
 genera ? What is the arrangement which they thus wish 
 for, without being able to hit upon it ? What is the 
 tendency which thus drives them from the corolla to the 
 anthers, from the flower to the fruit, from the fructifica- 
 tion to the leaves ? It is plain that they seek something, 
 not of their own devising and creating ; not anything 
 merely conventional and systematic; but something 
 which they conceive to exist in the relations of the 
 plants themselves; something which is without the 
 mind, not within; in nature, not in art; in short, a 
 Natural Order. 
 
 Thus the regulative principle of a Genus, or of any 
 other natural group is, that it is, or is supposed to be, 
 natural. And by reference to this principle as our guide, 
 we shall be able to understand the meaning of that in- 
 definiteness and indecision which we frequently find in 
 the descriptions of such groups, and which must appear 
 so strange and inconsistent to any one who does not 
 suppose these descriptions to assume any deeper ground 
 
 * Lindley, Nat. Syst., p. 5. 
 
 t In like manner we find Cuvier saying of Rondelet that he has 
 "un sentiment tres vrai des genres." Hist. Ichth., p. 39. 
 
METHODS OF NATURAL HISTORY. 493 
 
 of connexion than an arbitrary choice of the botanist. 
 Thus in the family of the Rose-tree, we are told that 
 the ovules are very rarely erect*, the stigmata are 
 usually simple. Of what use, it might be asked, can 
 such loose accounts be ? To which the answer is, that 
 they are not inserted in order to distinguish the species, 
 but in order to describe the family, and the total rela- 
 tions of the ovules and of the stigmata of the family are 
 better known by this general statement. A similar 
 observation may be made with regard to the Anomalies 
 of each group, which occur so commonly, that Mr. Lind- 
 ley, in his Introduction to the Natural System of Botany, 
 makes the "Anomalies" an article in each Family. Thus, 
 part of the character of the Rosacese is that they have 
 alternate stipulate leaves, and that the albumen is obli- 
 terated: but yet in Lowea, one of the genera of this 
 family, the stipulse are absent ; and the albumen is pre- 
 sent in another, Neillia. This implies, as we have already 
 seen, that the artificial character (or diagnosis as Mr. 
 Lindley calls it) is imperfect. It is, though very nearly, 
 yet not exactly, commensurate with the natural group : 
 and hence, in certain cases, this character is made to 
 yield to the general weight of natural affinities. 
 
 9. Difference of Natural History and Mathematics. 
 These views, of classes determined by characters which 
 cannot be expressed in words, of propositions which 
 state, not what happens in all cases, but only usually, 
 of particulars which are included in a class though they 
 transgress the definition of it, may very probably surprize 
 the reader. They are so contrary to many of the received 
 opinions respecting the use of definitions and the nature 
 of scientific propositions, that they will probably appear 
 to many persons highly illogical and unphilosophical. 
 But a disposition to such a judgment arises in a great 
 
 * Lindley, Nat. Syst., p. 81. 
 
494 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 measure from this ; that the mathematical and mathe- 
 matico-physical sciences have, in a great degree, deter- 
 mined men's views of the general nature and form of 
 scientific truth ; while Natural History has not yet had 
 time or opportunity to exert its due influence upon the 
 current habits of philosophizing. The apparent indefi- 
 niteness and inconsistency of the classifications and 
 definitions of Natural History belongs, in a far higher 
 degree, to all other except mathematical speculations : 
 and the modes in which approximations to exact distinc- 
 tions and general truths have been made in Natural His- 
 tory, may be worthy our attention, even for the light 
 they throw upon the best modes of pursuing truth of all 
 kinds. 
 
 10. Natural Groups given by Type not by Definition. 
 The further developement of this suggestion must be 
 considered hereafter. But we may here observe, that 
 though in a Natural Group of objects a definition can no 
 longer be of any use as a regulative principle, classes are 
 not, therefore, left quite loose, without any certain stand- 
 ard or guide. The class is steadily fixed, though not 
 precisely limited ; it is given, though not circumscribed ; 
 it is determined, not by a boundary line without, but by 
 a central point within ; not by what it strictly excludes, 
 but . by what it eminently includes ; by an example, not 
 by a precept ; in short, instead of Definition we have a 
 Type for our director. 
 
 A Type is an example of any class, for instance, a 
 species of a genus, which is considered as eminently pos- 
 sessing the characters of the class. All the species 
 which have a greater affinity with this Type-species than 
 with any others, form the genus, and are ranged about 
 it, deviating from it in various directions and different 
 degrees. Thus a genus may consist of several species 
 which approach very near the type, and of which the 
 
METHODS OF NATURAL HISTORY. 495 
 
 claim to a place with it is obvious ; while there may be 
 other species which straggle further from this central 
 knot, and which yet are clearly more connected with it 
 than with any other. And even if there should be some 
 species of which the place is dubious, and which appear 
 to be equally bound to two generic types, it is easily seen 
 that this would not destroy the reality of the generic 
 groups, any more than the scattered trees of the inter- 
 vening plain prevent our speaking intelligibly of the dis- 
 tinct forests of two separate hills. 
 
 The Type-species of every genus, the Type-genus of 
 every family, is, then, one which possesses all the cha- 
 racters and properties of the genus in a marked and pro- 
 minent manner. The Type of the Rose family has alter- 
 nate stipulate leaves, wants the albumen, has the ovules 
 not erect, has the stigmata simple, and besides these 
 features, which distinguish it from the exceptions or 
 varieties of its class, it has the features which make it 
 prominent in its class. It is one of those which possess 
 clearly several leading attributes; and thus, though we 
 cannot say of any one genus that it must be the Type of 
 the family, or of any one species that it must be the Type 
 of the genus, we are still not wholly to seek : the Type 
 must be connected by many affinities with most of the 
 others of its group ; it must be near the center of the 
 crowd, and not one of the stragglers. 
 
 11. It has already been repeatedly stated, as the 
 great rule of all classification, that the classification must 
 serve to assert general propositions. It may be asked 
 wliat propositions we are able to enunciate by means of 
 such classifications as we are now treating of. And the 
 answer is, that the collected knowledge of the characters, 
 habits, properties, organization, and functions of these 
 groups and families, as it is found in the best botanical 
 works, and as it exists in the minds of the best botanists, 
 
496 PHILOSOPHY OF THE CLASSIFICATOUY SCIENCES. 
 
 exhibits to us the propositions which constitute the 
 science, and to the expression of which the classification 
 is to serve. All that is not strictly definition, that is, all 
 that is not artificial character, in the descriptions of such 
 classes, is a statement of truths, more or less general, 
 more or less precise, but making up, together, the posi- 
 tive knowledge which constitutes the science. As we 
 have said, the consideration of the properties of plants in 
 order to form a system of classification, has been termed 
 Taxonomy, or the Systematick of Botany ; all the parts 
 of the descriptions, which, taking the system for granted, 
 convey additional information, are termed the Physio- 
 graphy of the science ; and the same terms may be 
 applied in the other branches of Natural History. 
 
 12. Artificial and Natural Systems. If I have suc- 
 ceeded in making it apparent that an artificial system of 
 characters necessarily implies natural classes which are 
 not severed by the artificial marks, we shall now be 
 able to compare the nature and objects of the Artificial 
 and Natural Systems; points on which much has been 
 written in recent times. 
 
 The Artificial System is one which is, or professes to 
 be, entirely founded upon marks selected according to the 
 condition which has been stated, of not violating certain 
 narrow natural groups ; namely, in the Linnsean system, 
 the natural genera of plants. The marks which form the 
 basis of the system, being thus selected, are applied 
 rigorously and universally without any further regard 
 to any other characters or indications of affinity. Thus 
 in the Linnsean system, which depends mainly on the 
 number of male organs or stamens, and on the number 
 of female organs or styles, the largest divisions, or the 
 Classes, are arranged according to the number of the 
 stamens, and are monandria, diandria, triandria, te- 
 trandria, pentandria, heocandria, and so on : the names 
 
METHODS OF NATURAL HISTORY. 497 
 
 being formed of the Greek numerical words, and of the 
 word which implies male. And the Orders of each of 
 these Classes are distinguished by the number of styles, 
 and are called monogynia, digynia, trigynia, and so on, 
 the termination of these words meaning female. And so 
 far as this numerical division and subdivision go on, the 
 system is a rigorous system, and strictly artificial. 
 
 But the condition that the artificial system shall leave 
 certain natural affinities untouched, makes it impossible 
 to go through the vegetable kingdom by a method of 
 mere numeration of stamens and styles. The distinction 
 of flowers with twenty and with thirty stamens is not a 
 fixed distinction : flowers of one and the same kind, as 
 roses, have, some fewer than the former, some more than 
 the latter number. The Artificial System, therefore, must 
 be modified. And there are various relations of con- 
 nexion and proportion among the stamina which are 
 more permanent and important than their mere num- 
 ber. Thus flowers with two longer and two shorter 
 stamens are not placed in the class tetrandria, but are 
 made a separate class didynamia ; those with four longer 
 and two shorter are in like manner tetradynamia, not 
 hexandria ; those in which the filaments are bound into 
 two bundles are diadelphia. All these and other classes 
 are deviations from the plan of the earlier Classes, and 
 are so far defects of the artificial system ; but they are 
 deviations requisite in order that the system may leave 
 a basis of natural groups, without which it would not be 
 a System of Vegetables. And as the division is still 
 founded on some properties of the stamens, it combines 
 not ill with that part of the system which depends on 
 the number of them. The Classes framed in virtue of 
 these various considerations make up an Artificial System 
 which is tolerably coherent. 
 
 " But since the Artificial System thus regards natural 
 
 VOL. I. W. P. K K 
 
498 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 groups, in what does it differ from a Natural System?" 
 It differs in this : That though it allows certain subor- 
 dinate natural groups, it merely allows these, and does 
 not endeavour to ascend to any wider natural groups. 
 It takes all the higher divisions of its scheme from its 
 artificial characters, its stamens and pistils, without look- 
 ing to any natural affinities. It accepts natural Genera, 
 but it does not seek natural Families, or Orders, or 
 Classes. It assumes natural groups, but does not inves- 
 tigate any; it forms wider and higher groups, but pro- 
 fesses to frame them arbitrarily. 
 
 But then, on the other hand, the question occurs, 
 " This being the case, what can be the use of the Artificial 
 System?" If its characters, in the higher stages of clas- 
 sification, be arbitrary, how can it lead us to the natural 
 relations of plants? And the answer is, that it does so 
 in virtue of the original condition, that there shall be 
 certain natural relations which the artificial system shall 
 not transgress ; and that its use arises from the facility 
 with which we can follow the artificial arrangement as 
 far as it goes. We can count the stamens and pistils, 
 and thus we know the Class and Order of our plant ; and 
 we have then to discover its Genus and Species by means 
 less symmetrical but more natural. The Artificial Sys- 
 tem, though arbitrary in a certain degree, brings us to a 
 Class in which the whole of each Genus is contained, and 
 there we can find the proper Genus by a suitable method 
 of seeking. No Artificial System can conduct us into 
 the extreme of detail, but it can place us in a situation 
 where the detail is within our reach. We cannot find 
 the house of a foreign friend by its latitude and longi- 
 tude; but we may be enabled, by a knowledge of the 
 latitude and longitude, to find the city in which he 
 dwells, or at least the island ; and we then can reach his 
 abode by following the road or exploring the locality. 
 
METHODS OF NATURAL HISTORY. 499 
 
 The Artificial System is such a method of travelling by 
 latitude and longitude ; the Natural System is that which 
 is guided by a knowledge of the country. 
 
 The Natural System, then, is that which endeavours 
 to arrange by the natural affinities of objects; and more 
 especially, which attempts to ascend from the lower 
 natural groups to the higher ; as for example from genera 
 to natural families, orders, and classes. But as we have 
 already hinted, these expressions of natural affinities, 
 natural groups, and the like, when considered in refer- 
 ence to the idea of resemblance alone, without studying 
 analogy or function, are very vague and obscure. We 
 must notice some of the attempts which were made 
 under the operation of this imperfect view of the subject. 
 
 SECT. IV. Modes of framing Natural Systems. 
 
 13. Decandolle"* distinguishes the attempts at Na- 
 tural Classifications into three sorts : those of blind trial, 
 (tdtonnement), those of general comparison, and those of 
 subordination of characters. The two former do not 
 depend distinctly upon any principle, except resem- 
 blance ; the third refers us to other views, and must be 
 considered in a future chapter. 
 
 Method of Blind Trial. The notion of the existence 
 of natural classes dependent on the general resemblance 
 of plants, of an affinity showing itself in different parts 
 and various ways, though necessarily somewhat vague 
 and obscure, was acted upon at an early period, as we 
 have seen in the formation of genera ; and was enunciated 
 in general terms soon after. Thus Magnoliusf says that 
 he discerns in plants an affinity, by means of which they 
 may be arranged in families. " Yet it is impossible to 
 
 * Theor. Elem., art. 41. 
 
 t Dec. Theor. Elem., art. 42. Petri Magnoli, Prodromus Hist. 
 Gen. Plant., 1689. 
 
 KK 2 
 
500 PHILOSOPHY OF THE CLASSIFICATOKY SCIENCES. 
 
 obtain from the fructification alone the Characters of 
 these families ; and I have therefore chosen those parts 
 of plants in which the principal characteristic marks are 
 found, as the root, the stem, the flower, the seed. In 
 some plants there is even a certain resemblance; an 
 affinity which does not consist in the parts considered 
 separately, but in their totality ; an affinity which may be 
 felt but not expressed ; as we see in the families of agri- 
 monies and cinquefoils, which every botanist will judge 
 to be related, though they differ by their roots, their 
 leaves, their flowers, and their seeds." 
 
 This obscure feeling of a resemblance on the whole, 
 a naffinity of an indefinite kind, appears fifty years later 
 in Linnaeus' s attempts. " In the Natural Classification," 
 he says*, "no d priori rule can be admitted, no part of 
 the fructification can be taken exclusively into considera- 
 tion ; but only the simple symmetry of all its parts." 
 Hence though he proposed Natural Families, and even 
 stated the formation of such Families to be the first and 
 last object of all Methods, he never gave the Characters 
 of those groups, or connected them by any method. He 
 even declared it to be impossible to lay down such a 
 system of characters. This persuasion was the result of 
 his having refused to admit into his mind any Idea more 
 profound than that notion of Resemblance of which he 
 had made so much and such successful use ; he would not 
 attempt to unravel the Ideas of Symmetry and of Func- 
 tion on which the clear establishment of natural relations 
 must depend. He even despised the study of the inner 
 organization of plants; and reckoned f the Anatomici, 
 who studied the anatomy and physiology of plants and 
 the laws of vegetation, among the Botanophili, the mere 
 amateurs of his science. 
 
 The same notion of general resemblance and affinity, 
 
 * Dec., Theor. Elem. art. 42. t Phil Bot., s.44. 
 
METHODS OF NATURAL HISTORY. 501 
 
 accompanied with the same vagueness, is to be found in 
 the writer who least participated in the general admiration 
 of Linnaeus, Buffon. Though it was in a great measure 
 his love of higher views which made him dislike what 
 he considered the pedantry of the Swedish school, he 
 does not seem to have obtained a clearer sight of the 
 principle of the natural method than his rival, except 
 that he did not restrict his Characters to the fructifica- 
 tion. Things must be arranged by their resemblances 
 and differences, (he says in 1750*,) "but the resem- 
 blances and differences must be taken not from one part 
 but from the whole ; and we must attend to the form, 
 the size, the habit, the number and position of the parts, 
 even the substance of the part ; and we must make use 
 of these elements in greater or smaller number, as we 
 have need." 
 
 14. Method of General Comparison. A countryman 
 of Buffon, who shared with him his depreciating esti- 
 mate of the Linnsean system, and his wish to found a 
 natural system upon a broader basis, was Adanson ; and 
 he invented an ingenious method of apparently avoid- 
 ing the vagueness of the practice of following the general 
 feeling of resemblance. This method consisted in making 
 many Artificial Systems, in each of which plants were 
 arranged by some one part; and then collecting those 
 plants which came near each other in the greatest number 
 of those Artificial Systems, as plants naturally the most 
 related. Adanson gives an account f of the manner in 
 which this system arose in his mind. He had gone to 
 Senegal, animated by an intense zeal for natural history; 
 and there, amid the luxuriant vegetation of the torrid 
 zone, he found that the methods of Linnaeus and Tourne- 
 fort failed him altogether as means of arranging his 
 
 * Adanson, p. CLVI'. Buffon, Hist. Nat.^ t. i. p. 21. 
 t Pref. p. cLvii. 
 
502 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 new botanical treasures. He was driven to seek a new 
 system. " For this purpose," he says, " I examined 
 plants in all their parts, without omitting any, from the 
 roots to the embryo, the folding of the leaves in the bud, 
 their mode of sheathing 4 ", the situation and folding of 
 the embryo and of its radicle in the seed, relatively to 
 the fruit ; in short, a number of particulars which few 
 botanists notice. I made in the first place a complete 
 description of each plant, putting each of its parts in 
 separate articles, in all its details ; when new species 
 occurred I put down the points in which they differed, 
 omitting those in which they agreed. By means of the 
 aggregate of these comparative descriptions, I perceived 
 that plants arranged themselves into classes or families 
 which could not be artificial or arbitrary, not being 
 founded upon one or two parts, which might change at 
 certain limits, but on all the parts ; so that the dispropor- 
 tion of one of these parts was corrected and balanced 
 by the introduction of another." Thus the principle of 
 Resemblance was to suffice for the general arrangement, 
 not by means of a new principle, as Symmetry or Organi- 
 zation, which should regulate its application, but by a 
 numeration of the peculiarities in which the resemblance 
 consisted. 
 
 The labour which Adanson underwent in the execu- 
 tion of this thought was immense. By taking each 
 Organ, and considering its situation, figure, number, &c., 
 he framed sixty-five Artificial Systems ; and collected his 
 Natural Families by a numerical combination of these. 
 For example, his sixty-fifth Artificial System f is that 
 which depends upon the situation of the Ovary with re- 
 gard to the Flower ; according to this system he frames 
 ten Artificial Classes, including ninety-three Sections : 
 and of these Sections the resulting Natural Arrange- 
 
 * " Lour maniere de s'cngainer." t Adanson, Prcf., p. cccxii. 
 
METHODS OF NATURAL HISTORY. 503 
 
 ment retains thirty-five, above one-third: the same 
 estimate is applied in other cases. 
 
 But this attempt to make Number supply the defects 
 which the vague notion of Resemblance introduces, how- 
 ever ingenious, must end in failure. For, as Decan- 
 dolle observes*, it supposes that we know, not only all 
 the Organs of plants, but all the points of view in which 
 it is possible to consider them ; and even if this assump- 
 tion were true, which it is, and long must be, very far 
 from being, the principle is altogether vicious ; for it 
 supposes that all these points of view, and all the result- 
 ing artificial systems are of equal importance : a sup- 
 position manifestly erroneous. We are thus led back to 
 the consideration of the Relative Importance of Organs 
 and their qualities, as a basis for the classification of 
 plants, which no Artificial Method can supersede ; and 
 thus we find the necessity of attending to something 
 besides mere external and detached Resemblance. The 
 method of General Comparison cannot, any more than 
 the method of Blind Trial, lead us, with any certainty 
 or clearness, to the Natural Method. . Adanson's Fami- 
 lies are held by the best botanists to be, for the greater 
 part, Natural ; but his hypotheses are unfounded ; and 
 his success is probably more due to the dim feeling of 
 Affinity, by which he was unconsciously guided, than to 
 the help he derived from his numerical processes. 
 
 In a succeeding chapter I shall treat of that Na- 
 tural Affinity on which a Natural System must really be 
 founded. But before proceeding to this higher subject, 
 we must say a few words on some of the other parts of 
 the philosophy of Natural History, the Gradation of 
 Groups, the Nomenclature, the Diagnosis, and the appli- 
 cation of the methods to other subjects. 
 
 * Dec., Thcor. Elern., p. <>7- 
 
504 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 SECT. V. Gradation of Groups. 
 
 15. It has been already noticed (last chapter,) that 
 even that vague application of the idea of resemblance 
 which gives rise to the terms of common language, intro- 
 duces a subordination of classes, as man, animal, body, 
 substance. Such a subordination appears in a more pre- 
 cise form when we employ this idea in a scientific man- 
 ner as we do in Natural History. We have then a series 
 of divisions, each inclusive of the lower ones, which are 
 expressed by various metaphors in different writers. 
 Thus some have gone as far as eight terms of the series*, 
 and have taken, for the most part, military names for 
 them ; as Hosts, Legions, Phalanxes, Centuries, Cohorts, 
 Sections, Genera, Species. But the most received series 
 is Classes, Orders, Genera, and Species ; in which, how- 
 ever, we often have other terms interpolated, as Sub- 
 genera, or Sections of genera. The expressions Family 
 and Tribe, are commonly appropriated to natural groups; 
 and we speak of the Vegetable, Animal, Mineral King- 
 dom; but the other metaphors of Provinces, Districts, 
 &c., which this suggests, have not been commonly used f . 
 It will of course be understood that each ascending 
 step of classification is deduced by the same process 
 from the one below. A Genus is a collection of Species 
 which resemble each other more than they resemble 
 other species ; an Order is a collection of Genera having, 
 in like manner, the first degree of resemblance, and so on. 
 How close or how wide the Degrees of Resemblance are, 
 must depend upon the nature of the objects compared, 
 and cannot possibly be prescribed beforehand. Hence the 
 same term, Class and Order for instance, may imply, in 
 different provinces of nature, very different degrees of 
 
 * Adanson, p. cvi. 
 
 t Sub-Kingdom has recently been employed by some naturalists. 
 
METHODS OF NATURAL HISTORY. 505 
 
 resemblance. The Classes of Animals are Insects, Birds, 
 Fish, Beasts, &c. The Orders of Beasts are Ruminants, 
 Tardigrades, Plantigrades, &c. The two Classes of 
 Plants (according to the Natural Order*,) are Vascular 
 and Cellular, the latter having neither sexes, flowers, 
 nor spiral vessels. The Vascular Plants are divided 
 into Orders, as Umbettiferce, Ranunculacece, &c.; but 
 between this Class and its Orders are interposed two 
 other steps : two Sub-classes, Dicotyledonous and Mono- 
 cotyledonous, and two Tribes of each: Angiospermice, 
 Gymnospermice of the first ; and Petaloidece, Glumacice 
 of the second. Such interpolations are modifications of 
 the general formula of subordination, for the purpose of 
 accommodating it to the most prominent natural affinities. 
 16. Species. As we have already seen in tracing the 
 principles of the Natural Method, when by the intimate 
 study of plants we seek to give fixity and definiteness to 
 the notion of resemblance and affinity on which all these 
 divisions depend, we are led to the study of Organization 
 and Analogy. But we make a reference to physio- 
 logical conditions even from the first, with regard to the 
 lowest step of our arrangement, the Species; for we 
 consider it a proof of the impropriety of separating two 
 Species, if it be shown that they can by any course of 
 propagation, culture, and treatment, the one pass into 
 the other. It is in this way, for example, that it has 
 been supposed to be established that the common Prim- 
 rose, Oxlip, Polyanthus, and Cowslip, are all the same 
 species. Plants which thus, in virtue of external cir- 
 cumstances, as soil, exposure, climate, exhibit differences 
 which may disappear by changing the circumstances, 
 are called Varieties of the species. And thus we cannot 
 say that a Species is a collection of individuals which 
 possess the First Degree of Resemblance ; for it is clear 
 
 * Lindlev. 
 
506 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 that a primrose resembles another primrose more than 
 it does a cowslip ; but this resemblance only constitutes 
 a Variety. And we find that we must necessarily include 
 in our conception of Species, the notion of propagation 
 from- the same stock. And thus a Species has been 
 well defined* : " The collection of the individuals de- 
 scended from one another, or from common parents, 
 and of those which resemble these as much as these 
 resemble each other." And thus the sexual doctrine of 
 plants, or rather the consideration of them as things 
 which propagate their kind, (whether by seed, shoot, or 
 in any other way,) is at the basis of our classifications. 
 
 17. The First permanent Degree of Resemblance 
 among organized beings is thus that which depends on 
 this relation of generation, and we might expect that the 
 groups which are connected by this relation would derive 
 their names from the notion of generation. It is curious 
 that both in Greek and Latin languages and in our own, 
 the words which have this origin (7eW, genus, kind,} 
 do not, in the phraseology of science at least, denote the 
 nearest degree of relationship, but have other terms 
 subordinate to them, which appear etymologically to 
 indicate a mere resemblance of appearance, (elcW, spe- 
 cies, sort;) and these latter terms are appropriated to 
 the groups resulting from propagation. Probably the 
 reason of this is, that the former terms (genus, &c.) had 
 been applied so widely and loosely before the scientific 
 fixation of terms, that to confine them to what we call 
 species would have been to restrict them in a manner 
 too unusual to be convenient. 
 
 18. Varieties. Races. The Species, as we have 
 
 said, is the collection of individuals which resemble 
 
 each other as much as do the offspring of a common 
 
 stock. But within the limits of this boundary, there 
 
 * Guv., Rcgne Animal, p. 10. 
 
METHODS OF NATURAL HISTORY. 507 
 
 are often observable differences permanent enough to 
 attract our notice, though capable of being obliterated 
 by mixture in the course of generation. Such different 
 groups are called Varieties. Thus the Primrose and 
 Cowslip, as has been stated above, are found to be varie- 
 ties of the same plant ; the Poodle and the Greyhound 
 are well marked varieties of the species dog. Such dif- 
 ferences are hereditary, and it may be long doubtful 
 whether such hereditary differences are varieties only, 
 or different species. In such cases the term Race has 
 been applied. 
 
 SECT. VI. Nomenclature. 
 
 19. The Nomenclature of any branch of Natural 
 History is the collection of names of all its species; 
 which, when they become extremely numerous, requires 
 some artifice to make it possible to recollect or apply 
 them. The known species of plants, for example, were 
 10,000 at the time of Linnaeus, and are now probably 
 60,000. It would be useless to endeavour to frame and 
 employ separate names for each of these species. 
 
 The division of the objects into a subordinated sys- 
 tem of classification enables us to introduce a Nomen- 
 clature which does not require this enormous number of 
 names. The artifice employed to avoid this incon- 
 venience is to name a Species by means of two (or it 
 might be more) steps of the successive division. Thus 
 in Botany, each of the genera has its name, and the 
 species are marked by the addition of some epithet to 
 the name of the genus. In this manner about 1,700 
 generic names, with a moderate number of specific 
 names, were found by Linnaeus sufficient to designate 
 with precision all the species of vegetables known at his 
 time. And this Binary Method of Nomenclature has 
 been found so convenient that it has been universally 
 
508 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 adopted in every other department of the Natural His- 
 tory of organized beings. 
 
 Many other modes of Nomenclature have been tried, 
 but no other has at all taken root. Linna?us himself 
 appears at first to have intended marking each species 
 by the Generic Name accompanied by a characteristic 
 Descriptive Phrase ; and to have proposed the employ- 
 ment of a trivial Specific Name, as he termed it, only as 
 a method of occasional convenience. The use of these 
 trivial names, has, however, become universal, as we 
 have said, and is by many persons considered the great- 
 est improvement introduced at the Linnsean reform. 
 
 Both Linnaeus and other writers (as Adanson) have 
 given many maxims with a view of regulating the selec- 
 tion of generic and specific names. The maxims of 
 Linna3us were intended as much as possible to exclude 
 barbarism and confusion, and have, upon the whole, 
 been generally adopted; though many of them were 
 objected to by his contemporaries (Adanson and others*), 
 as capricious or unnecessary innovations. Many of the 
 names, introduced by Linna?us, certainly appear fanciful 
 enough : thus he gives the name of Bauhinia to a plant 
 with leaves in pairs, because the Bauhins were a pair of 
 brothers; Banisteria is the name of a climbing plant, 
 in honour of Banister, who travelled among mountains. 
 But such names, once established by adequate authority, 
 lose all their inconvenience, and easily become per- 
 manent ; and hence the reasonableness of the LinnaBan 
 rulef, that as such a perpetuation of the names of per- 
 sons by the names of plants is the only honour botanists 
 have to bestow, it ought to be used with care and 
 caution. 
 
 The generic name must, as LinnaBus says, be fixed J 
 
 * Pp. cxxix. cLXxii. t Phil. Bot., Sec. 239. 
 
 $ /&., Sec. 222. 
 
METHODS OF NATURAL HISTORY. 509 
 
 before we attempt to form a specific name ; " the latter 
 without the former is like the clapper without the bell." 
 The name of the genus being established, the species 
 may be marked by adding to it " a single word taken at 
 will from any quarter ;" that is, not involving a descrip- 
 tion or any essential property of the plant, but a casual 
 or arbitrary appellation*. Thus the various species of 
 Hieracium-\ are Hieracium Alpinum, H. Halleri, H. 
 Pilosella, H. dubium, H. murorum, &c. where we see 
 how different may be the kind of origin of the words. 
 
 Attempts have been made at various times to form 
 the names of species from those of genera in some more 
 symmetrical manner. Thus some have numbered the 
 species of genus, 1, 2, 3, &c.; but this method is liable to 
 the inconveniences, first, that it offers nothing for the 
 memory to take hold of; and second, that if a new 
 species intermediate between 1 and 2, 2 and 3, &c., be 
 discovered, it cannot be put in its place. It has also 
 been proposed to mark the species by altering the termi- 
 nation of the genus. Thus AdansonJ, denoting a genus 
 by the name Fonna (Lychnidea), conceived he might 
 mark five of its species by altering the last vowel, Fonna, 
 Fonna-e, Fonna-i, Fonna-o, Fonna-u ; then others by 
 Fonna-ba, Fonna-ka, and so on. This course would be 
 liable to the same evils which have been noticed as 
 belonging to the numerical method. 
 
 The names of plants (and the same is true of animals) 
 have in common practice been binary only, consisting of 
 a generic and a specific name. The Class and Order 
 have not been admitted to form part of the appellation 
 of the species. Indeed it is easy to see that a name which 
 must be identical in so many instances as that of an 
 Order would be, would be felt as superfluous and burden- 
 some. Accordingly, Linnaeus makes it a precept $, that 
 
 * Phil Bot., Sec. 260. t Hooker, Fl. Scot., 228. 
 
 $ Pref. cLXXvi. Phil Bot., Sec. 215. 
 
510 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 the name of the Class and the Order must not be ex- 
 pressed but understood : and hence, he says, Royen, who 
 took Lilium for the name of a Class, rightly rejected it as 
 a generic name and substituted Liriuni, with the Greek 
 termination. 
 
 Yet we must not too peremptorily assume such 
 maxims as these to be universal for all classificatory 
 sciences. It is very possible that it may be found 
 advisable to use three terms, that of order, genus and 
 species, in designating minerals, as is done in Mohs's 
 nomenclature ; for example, Rhombohedral Calc Haloide, 
 Paratomous Hal Baryte. 
 
 It is possible also that it may be found useful in the 
 same science to mark some of the steps of classification 
 by the termination. Thus it has been proposed to con- 
 fine the termination ite to the Order Silicides of Nau- 
 mann, as ApophylK^, Stilb^, Leucfe, &c., and to use 
 names of different form in other orders, as Talc Spar for 
 Brennerite, Pyramidal Titanium Oxide for Octahedrite. 
 Some such method appears to be the most likely to 
 give us a tolerable mineralogical nomenclature. 
 
 SECT. VII. Diagnosis. 
 
 20. German Naturalists speak of a part of the general 
 method which they call the Characteristik of Natural 
 History, and which is distinguished from the Systematik 
 of the science. The Systematick arranges the objects 
 by means of all their resemblances, the Characteristic^ 
 enables us to detect their place in the arrangement 
 by means of a few of their characters. What these 
 characters are to be, must be discovered by observation 
 of the groups and divisions of the system when they are 
 formed. To construct a collection of such as shall be 
 clear and fixed, is a useful, and generally a difficult task ; 
 for there is usually no apparent connexion between the 
 marks which are used in discriminating the groups, and 
 
METHODS OF NATURAL HISTORY. 511 
 
 the nature of the groups themselves. They are assumed 
 only because the Naturalist, extensively and exactly 
 acquainted with the groups and the properties of the 
 objects which compose them, sees, by a survey of the 
 field, that these marks divide it properly. 
 
 The Characteristick has been termed by some English 
 Botanists the Diagnosis of plants ; a word which we may 
 conveniently adopt. The Diagnosis of any genus or 
 species is different according to the system we follow. 
 Thus in the Linnaean System the Diagnosis of the Rose 
 is in the first place given by its Class and Order : it is 
 Icosandrous, and Polygynous ; and then the Generic Dis- 
 tinction is that the calyx is five-cleft, the tube urceolate, 
 including many hairy achenia, the receptacle villous*. In 
 the Natural System the Rose-Tribe are distinguished as 
 being f " Polypetalous dicotyledons, with lateral styles, 
 superior simple ovaria, regular perigynous stamens, ex- 
 albuminous definite seeds, and alternate stipulate leaves." 
 And the true Roses are further distinguished by having 
 "Nuts, numerous, hairy, terminated by the persistent 
 lateral style and inclosed within the fleshy tube of the 
 calyx," &c. 
 
 It will be observed that in a rigorous Artificial System 
 the Systematic^ coincides with the Characteristick ; the 
 Diataocis with the Diagnosis ; the reason why a plant is 
 put in a division is identical with the mode by which it is 
 known to be in the division. The Rose is in the class 
 icosandria, because it has many stamens inserted in the 
 calyx ; and when we see such a set of stamens we imme- 
 diately know the class. But this is not the case with 
 the Diagnosis of Natural Families. Thus the genera La- 
 mium and Galeopsis (Dead Nettle and Hemp Nettle), 
 are each formed into a separate group in virtue of their 
 general resemblances and differences, and not because 
 
 * Lindley, Nat. SysL, p. 149. t /&., p. 81. 3. 
 
512 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 the former has one tooth on each side of the lower lip, 
 and the latter a notch in its upper lip, though they are 
 distinguished by these marks. 
 
 Thus so far as our Systems are natural, (which, as we 
 have shown, all systems to a certain extent must be), the 
 Characteristick is distinct both from a Natural and an 
 Artificial System ; and is, in fact, an Artificial Key to a 
 Natural System. As being Artificial, it takes as few 
 characters as possible ; as being Natural, its characters 
 are not selected by any general or prescribed rule, but 
 follow the natural affinities. The Botanists who have 
 made any steps in the formation of a natural method of 
 plants since Linnaeus, have all attempted to give a Diag- 
 nosis corresponding to the Diataxis of their method. 
 
 CHAPTER III. 
 
 APPLICATION OF THE NATURAL HISTORY 
 METHOD TO MINERALOGY. 
 
 1. THE philosophy of the Sciences of Classification has 
 had great light thrown upon it by discussions concerning 
 the methods which are used in Botany : for that science 
 is one of the most complete examples which can be con- 
 ceived of the consistent and successful application of the 
 principles and ideas of Classification ; and this application 
 has been made in general without giving rise to any very 
 startling paradoxes, or disclosing any insurmountable 
 difficulties. But the discussions concerning methods of 
 Mineralogical Classification have been instructive for 
 quite a different reason : they have brought into view the 
 boundaries and the difficulties of the process of Classifi- 
 cation ; and have presented examples in which every 
 possible mode of classifying appeared to involve inex- 
 
APPLICATION TO MINERALOGY. 513 
 
 tricable contradictions. I will notice some of the points 
 of this kind which demand our attention, referring to the 
 works published recently by several mineralogists. 
 
 In the History of Mineralogy we noticed the attempt 
 made by Mohs and other Germans to apply to minerals 
 a method of arrangement similar to that which has been 
 so successfully employed for plants. The survey which 
 we have now taken of the grounds of that method will 
 point out some of the reasons of the very imperfect 
 success of this attempt. We have already said that the 
 Terminology of Mineralogy was materially reformed by 
 Werner ; and including in this branch of the subject (as 
 we must do) the Crystallography of later writers, it may 
 be considered as to a great extent complete. Of the 
 attempts at a Natural arrangement, that of Mohs appears 
 to proceed by the method of blind trial, the undefmable 
 perception of relationship, by which the earliest attempts 
 at a Natural Arrangement of plants were made. Breit- 
 haupt, however, has made (though I do not know that he 
 has published) an essay in a mode which corresponds very 
 nearly to Adanson's process of multiplied comparisons. 
 Having ascertained the specific gravity and hardness of 
 all the species of minerals, he arranged them in a table, 
 representing by two lines at right angles to each other 
 these two numerical quantities. Thus all minerals were 
 distributed according to two co-ordinates representing 
 specific gravity and hardness. He conceived that the 
 groups which were thus brought together were natural 
 groups. On both these methods, and on all similar ones, 
 we might observe, that in minerals as in plants, the 
 mere general notion of Likeness cannot lead us to a real 
 arrangement : this notion requires to have precision and 
 aim given it by some other relation ; by the relation 
 of Chemical Composition in minerals, as by the relation 
 of Organic Function in vegetables. The physical and 
 
 VOL. i. w. P. L L 
 
514 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 crystallographical properties of minerals must be studied 
 with reference to their constitution; and they must be 
 arranged into Groups which have some common Che- 
 mical Character, before we can consider any advance as 
 made towards a Natural Arrangement. 
 
 In reality, it happens in Mineralogy as it happened 
 in Botany, that those speculators are regulated by an 
 obscure perception of this ulterior relation, who do not 
 profess to be regulated by it. Several of the Orders of 
 Mohs have really great unity of chemical character, and 
 thus have good evidence of their being really Natural 
 Orders. 
 
 2. Supposing the Diataxis of minerals thus obtained, 
 Mohs attempted the Diagnosis ; and his Characteristic^ 
 of the Mineral Kingdom, published at Dresden, in 1820, 
 was the first public indication of his having constructed 
 a system. From the nature of a Characteristick, it is 
 necessarily brief, and without any ostensible principle ; 
 but its importance was duly appreciated by the author's 
 countrymen. Since that time, many attempts have been 
 made at improved arrangements of minerals, but none, 
 I think, (except perhaps that of Breithaupt,) professing 
 to proceed rigorously on the principles of Natural His- 
 tory ; to arrange by means of external characters, neg- 
 lecting altogether, or rather postponing, the consideration 
 of chemical properties. By relaxing from this rigour, 
 however, and by combining physical and chemical consi- 
 derations, arrangements have been obtained (for exam- 
 ple, that of Naumann,) which appear more likely than 
 the one of Mohs to be approximations to an ultimate 
 really natural system. Naumann's Classes are Hydro- 
 lytes, Haloides, Silicides, Metal Oxides, Metals, Sul- 
 phurides, Anthracides, with subdivisions of Orders, as 
 Anhydrous unmetallic Silicides. It may be remarked 
 that the designations of these are mostly chemical. As 
 
APPLICATION TO MINERALOGY. 515 
 
 we have observed already, Chemistry, and Mineralogy in 
 its largest sense, are each the necessary supplement of 
 the other. If Chemistry furnish the Nomenclature, 
 Mineralogy must supply the Physiography: if the Ar- 
 rangement be founded on External Characters and the 
 Names be independent of Chemistry, the chemical com- 
 position of each species is an important scientific Truth 
 respecting it. 
 
 3. The inquiry may actually occur, whether any sub- 
 ordination of groups in the mineral kingdom has really 
 been made out. The ancient chemical arrangements, 
 for instance, that of Haiiy, though professing to distri- 
 bute minerals according to Classes, Orders, Genera, and 
 Species, were not only arbitrary, but inapplicable; for 
 the first postulate of any method, that the species should 
 have constant characters of unity and difference, was not 
 satisfied. It was not ascertained that carbonate of lime 
 was really distinguishable in all cases from carbonate of 
 magnesia, or of iron ; yet these species were placed in 
 remote parts of the system : and the above carbonates 
 made just so many species ; although, if they were dis- 
 tinct from one another at all, they were further distin- 
 guishable into additional species. Even now, we may, 
 perhaps, say that the limits of mineralogical species, and 
 their laws of fixity, are not yet clearly seen. For the dis- 
 coveries of the isomorphous relations and of the optical 
 properties of minerals have rather shown us in what 
 direction the object lies, than led us to the goal. It is 
 clear that, in the mineral kingdom, the Definition of 
 Species, borrowed from the laws of the continuation of 
 the kind, which holds throughout the organic world, fails 
 us altogether, and must be replaced by some other con- 
 dition : nor is it difficult to see that the definite atomic 
 relations of the chemical constituents, and the definite 
 crystalline angle, must supply the principles of the 
 
 LL2 
 
516 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 Speficic Identity for minerals. Yet the exact limits of 
 definiteness in both these cases (when we admit the 
 effect of mechanical mixtures, &c.) have not yet been 
 completely disentangled. Moreover, any arbitrary as- 
 sumption (as the allowance of a certain per-centage of 
 mixture, or a certain small deviation in the angle,) is 
 altogether contrary to the philosophy of the Natural 
 System, and can lead to no stable views. It is only by 
 laborious, extensive, and minute research, that we can 
 hope to attain to any solid basis of arrangement. 
 
 4. Still, though there are many doubts respecting 
 mineralogical species, a large number of such species are 
 so far fixed that they may be supposed capable of being- 
 united under the higher divisions of a system with ap- 
 proximate truth. Of these higher divisions, those which 
 have been termed Orders appear to tend to something- 
 like a fixed chemical character. Thus the Haloids of 
 Naumann, and mostly those of Mohs, are combinations 
 of an oxide with an acid, and thus resemble Salts, 
 whence their name. The Silicides contain most of Mohs's 
 Spaths : and the Orders Pyrites, Glance, and Blende, 
 are common to Naumann and Mohs ; being established 
 by the latter on a difference of external character, which 
 difference is, indeed, very manifest ; and being included 
 by the former in one chemical Class, Sulphurides. The 
 distinctions of Hydrous and Anhydrous, Metallic and 
 Unmetallic, are, of course, chemical distinctions, but 
 occur as the differences of Orders in Naumann's mixed 
 system. 
 
 We may observe that some French writers, following 
 Haiiy's last edition, use, instead of metallic and unmetal- 
 lic, autopside metallic and heteropside metallic ; meaning 
 by this phraseology to acknowledge the discovery that 
 earths, &c., are metallic, though they do not appear to 
 be so, while metals both are and appear metallic. But 
 
APPLICATION TO MINERALOGY. 517 
 
 this seems to be a refinement not only useless but ab- 
 surd. For what is gained by adding the word metallic, 
 which is common to all, and therefore makes no dis- 
 tinction? If certain metals are distinguished by their 
 appearing to be metals, this appearance is a reason for 
 giving them the peculiar name, metals. Nothing is 
 gained by first bringing earths and metals together, and 
 then immediately separating them again by new and 
 inconvenient names. No proposition can be expressed 
 better by calling earths heteropside metallic substances, 
 and therefore such nomenclature is to be rejected. 
 
 Granting, then, that the Orders of the best recent 
 mineralogical systems approximate to natural groups, 
 we are led to ask whether the same can be said of the 
 Genera of the Natural History systems, such as those of 
 Mohs and Breithaupt. And here I must confess that I 
 see no principle in these Genera ; I have failed to appre- 
 hend the conceptions by the application of which they 
 have been constructed : I shall therefore not pass any 
 further judgment upon them. The subordination of 
 Mineralogical Species to Orders is a manifest gain to 
 science : in the interposition of Genera I see nothing 
 but a source of confusion. 
 
 5. In Mineralogy, as in other branches of natural 
 history, a reformed arrangement ought to give rise to a 
 reformed Nomenclature ; and for this, there is more occa- 
 sion at present in Mineralogy than there was in Botany 
 at the worst period, at least as far as the extent of the 
 subject allows. The characters of minerals are much 
 more dimly and unfrequently developed than those of 
 plants; hence arbitrary chemical arrangements, which 
 could not lead to any natural groups, and therefore not to 
 any good names, prevailed till recently ; and this state of 
 things produced an anarchy in which every man did what 
 seemed right in his own eyes, proposed species without 
 
518 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 any ascertained distinction, and without a thought of 
 subordination, and gave them arbitrary names ; and thus 
 with only about two or three hundred known species, we 
 have thousands upon thousands of names, of anomalous 
 form and uncertain application. 
 
 Mohs has attempted to reform the Nomenclature of 
 the subject in a mode consistent with his attempt to 
 reform the System. In doing this, he has fatally trans- 
 gressed a rule always insisted upon by the legislators of 
 Botany, of altering usual names as little as possible ; and 
 his names are both so novel and so cumbrous, that they 
 appear to have little chance of permanent currency. They 
 are, perhaps, more unweildy than they need to be, by 
 referring, as we have said, to three of the steps of his 
 classification, the Species, Genus, and Order. We may, 
 however, assert confidently, from the whole analogy of 
 natural history, that no good names can be found which 
 do not refer to at least two terms of the arrangement. 
 This rule has been practically adopted to a great extent 
 by Naumann, who gives to most of his Haloids the name 
 Spar, as Calc spar, Iron spar, &c. ; to all his Oxides the 
 terminal word Erz (Ore); and to the species of the orders 
 Kies (Pyrites), Glance, and Blende, these names. It has 
 also been theoretically assented to by Beudant, who pro- 
 poses that we should say silicate stilbite, silicate chabasie; 
 carbonate calcaire, carbonate mtherite ; sulphate coupe- 
 rose, &c. One great difficulty in this case would arise 
 from the great number of silicides ; it is not likely that 
 any names would obtain a footing which tacked the term 
 silicide to another word for each of these species. The 
 artifice which I have proposed, in order to obviate this 
 difficulty, is that we should make the names of the sili- 
 cides, and those alone, end in ite or lite, which a large 
 proportion of them do already. 
 
 By this and a few similar contrivances, we might, 
 
APPLICATION TO MINERALOGY. 519 
 
 I conceive, without any inconvenient change, introduce 
 into Mineralogy a systematic nomenclature. 
 
 6. I shall now proceed to make a few remarks on a 
 work on Mineralogy more recent than those which I 
 have above noticed, and written with express reference 
 to such difficulties as I have been discussing. I allude to 
 the treatise of M. Necker, Le Regne Mineral ramene 
 aux Methodes d'Histoire Naturelle*, which also contains 
 various dissertations on the Philosophy of Classification 
 in general, and its application to Mineralogy in particular. 
 M. Necker remarks very justly, that Mineralogy, as it 
 has hitherto been treated, differs from all other branches 
 of Natural History in this : that while it is invested 
 with all the forms of the sciences of classification, 
 Classes, Divisions, Genera, and the like, the properties 
 of those bodies to which the mineralogical student's 
 attention is directed have no bearing whatever on the 
 classification. A person, he remarks f, might be perfectly 
 well acquainted with all the characters of minerals which 
 Werner or Haiiy examined so carefully, and might yet 
 be quite unable to assign to any mineral its place in the 
 divisions of their methods. There isj a complete sepa- 
 ration between the study of mineralogical characters and 
 the recognition of the name and systematic place of a 
 mineral. Those who know mineralogy well, may know 
 minerals ill, or hardly at all ; the systematist may be in 
 such knowledge vastly inferior to the mineral-dealer or 
 the miner. In this respect there is a complete contrast 
 between this science and other classificatory sciences. 
 
 Again, in the best-known systems of Mineralogy, (as 
 those of Werner and Haiiy,) the bodies which are 
 grouped together as belonging to the same division, have 
 not, as they have in other classificatory sciences, any 
 resemblance. The different members of the larger 
 
 * Paris, 1835. t Regne Mineral, p. 3. { Ib., p. 8. 
 
520 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 classes are united by the common possession of some 
 abstract property, as, that they all contain iron. This 
 is a property to which no common circumstance in the 
 bodies themselves corresponds. What is there common 
 to the minerals named oxidulous iron, sulphuret of iron, 
 carbonate of iron, sulphate of iron, except that they all 
 contain iron? And when we have classed these bodies 
 together, what general assertion can we make concern- 
 ing them, except that which is the ground of our classi- 
 fication, that they contain iron? They have nothing in 
 common with iron or with each other in any other way. 
 
 Again, as these classes have no general properties, 
 all the properties are particular to the species ; and the 
 descriptions of these necessarily become both tediously 
 long, and inconveniently insulated. 
 
 7. These inconveniences arise from making Chemical 
 Composition the basis of Mineralogical Classification 
 without giving Chemical Analysis the first place among 
 Mineral Properties. Shall we, then, correct this omis- 
 sion, so far as it has affected mineralogical systems ? 
 Shall we teach the student the chemical analysis of 
 minerals, and then direct him to classify them according 
 to the results of his analysis*? 
 
 But why should we do this? To what purpose, or 
 on what ground, do we arrange the results of chemical 
 analysis according to the forms and subordination of 
 natural history? Is not chemistry a science distinct from 
 natural history? Are not the sciences opposed? Is not 
 natural history confined to organic bodies? Can mere 
 chemical elements and their combinations be, with any 
 propriety or consistency, arranged into species, genera, 
 and families ? What is the principle on which genera and 
 species depend? Do not species imply individuals? What 
 is an individual in the case of a chemical substance ? 
 
 * Regne Mineral, p. 18. 
 
APPLICATION TO MINERALOGY. 521 
 
 8. We thus find some of the widest and deepest 
 questions of the philosophy of classification brought under 
 our consideration when we would provide a method for 
 the classification of minerals. The answers to these 
 questions are given by M. Necker; and I shall state 
 some of his opinions ; taking the liberty of adding such 
 remarks as are suggested by referring the subject to 
 those principles which have already been established in 
 this work. 
 
 M. Necker asserts* that the distinctions of different 
 sciences depend, not on the objects they consider, but on 
 the different and independent points of view on which 
 they proceed. Each science has its logic, that is, its 
 mode of applying the general rules of human reason to 
 its own special case. It has been said by somef, that 
 in minerals, natural history and chemistry contemplate 
 common objects, and thus form a single science. But 
 do chemistry and natural history consider minerals in 
 the same point of view ? 
 
 The answer is, that they do not. Physics and che- 
 mistry consider the properties of bodies in an abstract 
 manner ; as, their composition, their elements, their 
 mutual actions, with the laws of these ; their forces, as 
 attraction, affinity ; all which objects are abstract ideas. 
 In these cases we have nothing to do with bodies them- 
 selves, but as the vehicles of the powers and properties 
 which we contemplate. 
 
 Natural history, on the other hand, has to do with 
 natural bodies : their properties are not considered ab- 
 stractedly, but only as characters. If the properties are 
 abstracted, it is but for a moment. Natural history 
 has to describe and class bodies as they are. All which 
 cannot be perceived by the senses, belongs not to its 
 domain, as molecules, atoms, elements. 
 
 * Regne Mineral, p. 23. t /6., p. 27- 
 
522 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 Natural history* may have recourse to physics or 
 chemistry in order to recognize those properties of 
 bodies which serve as characters ; but natural history is 
 not, on that account, physics or chemistry. Classifica- 
 tion is the essential business of the natural historian f, 
 to which task chemistry and physics are only instru- 
 mental, and the further account of properties only com- 
 plementary. 
 
 It has been said, in support of the doctrine that 
 chemistry and mineralogy are identical, that chemistry 
 does not neglect external characters. " The chemist in 
 describing sulphur, mentions its colour, taste, odour, 
 hardness, transparence, crystalline form, specific gravity; 
 how does he then differ from the mineralogist ?" But 
 to this it is replied, that these notices of the external 
 characters of this or any substance are introduced in 
 chemistry merely as convenient marks of recognition ; 
 whereas they are essential in mineralogy. If we had 
 taken the account given of several substances instead of 
 one, we should have seen that the chemist and the natu- 
 ralist consider them in ways altogether different. The 
 chemist will make it his business to discover the mutual 
 action of the substances; he will combine them, form 
 new products, determine the proportions of the elements. 
 The mineralogist will divide the substances into groups 
 according to their properties, and then subdivide these 
 groups, till he refers each substance to its species. Ex- 
 terior and physical characters are merely accessory and 
 subordinate for the chemist ; chemistry is merely instru- 
 mental for the mineralogist. 
 
 This view agrees with that to which we have been 
 
 led by our previous reasonings ; and may, according to 
 
 our principles, be expressed briefly by saying, that the 
 
 Idea which chemistry has to apply is the Idea of Ele- 
 
 * Regne Mineral, p. 37- t 76., p. 41. 
 
APPLICATION TO MINERALOGY. 523 
 
 mentary Composition, while natural history applies the 
 Idea of Graduated Resemblances, and thus performs the 
 task of classification. 
 
 9. The question occurs*, whether Natural History 
 can be applied to Inorganic Substances ? And the an- 
 swer to this question is, that it can be applied, if there 
 are such things as inorganic individuals, since the resem- 
 blances and differences with which natural history has to 
 do are the resemblances and differences of individuals. 
 
 What is an Individual ? It certainly is not that which 
 is so simple that it cannot be divided. Individual animals 
 are composed of many parts. But if we examine, we 
 shall find that our I4ea of an Individual is, that it is a 
 whole composed of parts, which are not similar to the 
 whole, and have not an independent existence, while the 
 whole has an independent existence and a definite formf. 
 
 What then is the Mineralogical Individual ? At first, 
 while minerals were studied for their use, the most pre- 
 cious of the substances which they contained was looked 
 upon as the characteristic of the mineral. The smallest 
 trace of silver made a mineral an ore of silver. Thus 
 forms and properties were disregarded, and substance 
 was considered as identical with mineral. And hence \ 
 Daubenton refused to recognize species in the mineral 
 kingdom, because he recognized no individuals. He 
 proposed to call sorts what we call species. In this way 
 of considering minerals, there are no individuals. 
 
 10. But still this is not satisfactory: for if we take 
 a well formed and distinct crystal, this clearly is an 
 individual $. 
 
 It may be objected, that the crystal is divisible 
 (according to the theory of crystallography) into smaller 
 solids ; that these small solids are really the simple ob- 
 jects; and that actual crystals are formed by combina- 
 tions of these molecules according to certain laws. 
 * Regne Mineral, p. 46. t Ib., p. 52. % Ib., p. 54. /&., p. 56. 
 
524 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 But, as we have already said, an individual is such, 
 not because it cannot be divided, but because it cannot 
 be divided into parts similar to the whole. As to the 
 division of the form into its component laws, this is an 
 abstract proceeding, foreign to natural history*. There- 
 fore there is so far nothing to prevent a crystal from 
 being an individual. 
 
 11. We cannot (M. Necker goes on to remark) con- 
 sider the Integrant Molecules as individuals. These are 
 useful abstractions, but abstractions only, which we must 
 not deal with as real objects. Haiiy himself warns usf 
 that his doctrine of increments is a purely abstract 
 conception, and that nature, in fact, follows a different 
 process. Accordingly, Weiss and Mohs express laws 
 identical with those of Haliy, without even speaking of 
 molecules ; and Wollaston and Davy have deemed it 
 probable that the molecules are not polyhedrons, but 
 spheres or spheroids. Such mere creations of the mind 
 can never be treated as individuals. If the maxim of 
 natural history, that the Species is a collection of Indi- 
 viduals be applied so as to make those individuals 
 mere abstractions ; or if, instead of Individuals, we take 
 such an abstraction as Substance or Matter, the course 
 of natural history is altogether violated. And yet this 
 errour has hitherto generally prevailed ; and minera- 
 logists have classified, not things, but abstract ideas J. 
 
 12. But it may be said$, will not the small solids 
 obtained by Cleavage better answer the idea of indi- 
 viduals? To this it is replied, that these small solids 
 have no independent existence. They are only the result 
 of a mode of division. They are never found separate 
 and independent. The secondary forms which they 
 compose are determined by various circumstances (the 
 nature of the solution, &c.) ; and the cleavage which pro- 
 
 * Regne Mineral, p. 58. t 76., p. 61. J 76., p. 67. 
 
 Ib., p. 69. 
 
APPLICATION TO MINERALOGY. 525 
 
 duces these small solids is only one result among many 
 from the crystalline forces *. 
 
 Thus neither Integrant Molecules, nor Solids ob- 
 tained by Cleavage, can be such mineralogical Individuals 
 as the spirit of natural history requires. Hence it ap- 
 pears that we must take the real Crystals for Indivi- 
 duals f. 
 
 13. We must, however, reject crystals (generally 
 large ones) which are obviously formed of several smaller 
 ones of a similar form (as occurs so often in quartz and 
 calc spar.) We must also distinguish cases in which a 
 large regular form is composed of smaller but different 
 regular forms (as octahedrons of fluor spar made up of 
 cubes). Here the small component forms are the indi- 
 viduals. Also we must notice the cases j in which we 
 have a natural crystal, similar to the primary form. 
 Here the face will show whether the body is a result 
 obtained by cleavage or a natural individual. 
 
 14. It will be objected $, that the crystalline form 
 ought not to be made the dominant character in mine- 
 ralogy, since it rarely occurs perfect. To this it is 
 replied, that even if the application of the principle be 
 difficult, still it has been shown to be the only true prin- 
 ciple, and therefore we have no alternative. But fur- 
 ther ||, it is not true that amorphous substances are more 
 numerous than crystals. In Leonhard's Manual of Oryc- 
 tognosy, there are 377 mineral substances. Of these, 
 281 have a crystalline structure, and 96 only have not 
 been found in a regular form. 
 
 Again, the 281 crystalline forms have each its varie- 
 ties, some of which are crystalline, and some are not so. 
 Now the crystalline varieties amount to 1453, and the 
 uncrystalline to 186 only. Thus mineralogy, according 
 
 * Regne Mineral, p. 71. t Ib., p. 73. J Ib., p. 75. 
 
 Ib., p. 79. || Ib., p. 82. 
 
526 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 to the view of it here presented, has a sufficiently wide 
 field*. 
 
 15. It will be objected-)-, that according to this mode 
 of proceeding, we must reject from our system all non- 
 crystalline minerals. But we reply, that if the mass be 
 composed of crystals, the size of the crystals makes no 
 difference. Now lamellar and other compact masses are 
 very generally groups of crystals in various positions. 
 Individuals mutilated and mixed together are not the less 
 individuals ; and therefore such masses may be treated 
 as objects of natural history. 
 
 If we cannot refer all rocks to crystalline species, 
 those which elude our method may appear as an appen- 
 dix, corresponding to those which botanists call genera 
 incertce sedis\. 
 
 But these genera and species will often be afterwards 
 removed into the cystalline part of the system, by being 
 identified with crystalline species. Thus pyrope, &c., 
 have been referred to garnet, and basalt, wacke, &c., to 
 compound rocks. Thus veins of Dolerite, visibly com- 
 posed of two or three elements, pass to an apparently 
 simple state by becoming fine-grained $. 
 
 16. Finally II, we have to ask, are artificial crystals to 
 enter into our classification ? M. Necker answers, No ; 
 because they are the result of art, like mules, mestizos, 
 hybrids, and the like. 
 
 17. Upon these opinions, we may observe, that they 
 appear to be, in the main, consistent with the soundest 
 philosophy. That each natural crystal is an individual, 
 is a doctrine which is the only basis of mineralogy as a 
 Natural Historical science ; yet the imperfections and 
 confused unions of crystals make this principle difficult 
 to apply. Perhaps it may be expressed in a more pre- 
 
 * Regne Mineral., p. 84. t Ib, p. 86. J /&., p. 91. 
 
 Ib., p. 93. || /., p. 95. 
 
APPLICATION TO MINERALOGY. 527 
 
 else manner by referring to the crystalline forces, and to 
 the axes by which their operation is determined, rather 
 than to the external form. That portion of a mineral 
 substance is a mineralogical individual which is deter- 
 mined by crystalline forces acting to the same axes. In 
 this way we avoid the difficulty arising from the absence 
 of faces, and enable ourselves to use either cleavage, or 
 optical properties, or any others, as indications of the 
 identity of the individual. The individual extends so 
 far as the polar forces extend by which crystalline form 
 is determined, whether or not those forces produce their 
 full effect, namely, a perfectly circumscribed polyhedron. 
 18. There is only one material point on which our 
 principles lead us to differ from M. Necker ; the pro- 
 priety of including artificial crystals in our mineralo- 
 gical classification. To exclude them, as he does, is a 
 conclusion so entirely at variance with the whole course 
 of his own reasonings, that it is difficult to conceive that 
 he would persist in his conclusion, if his attention were 
 drawn to the question more steadily. For, as he justly 
 says'", each science has its appropriate domain, deter- 
 mined by its peculiar point of view. Now artificial and 
 natural crystals are considered in the same point of 
 view, (namely, with reference to crystalline, physical, 
 and optical properties, as subservient to classification,) 
 and ought, therefore, to belong to the same science. 
 Again, he saysf, that Chemistry would reject as useless 
 all notice of the physical properties and external cha- 
 racters of substances, if a special science were to take 
 charge of the description and classification of these pro- 
 ducts. But such a special science must be Mineralogy ; 
 for we cannot well make one science of the classification 
 of natural, and another of that of artificial substances : or 
 if we do, the two sciences will be identical in method and 
 
 * Eegne Mineral, p. 23. t /&., p. 36. 
 
528 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 principles, and will extend over each other's boundaries, 
 so that it will be neither useful nor possible to distin- 
 guish them. Again, M. Necker's own reasonings on the 
 selection of the individual in mineralogy are supported 
 by well chosen examples * ; but these examples are taken 
 from artificial salts; as, for instance, common salt cry- 
 stallizing in different mixtures. Again, the analogy of 
 mules and mestizos, as products of art, with chemical 
 compounds, is not just. Chemical compounds corre- 
 spond rather to natural species, propagated by man under 
 the most natural circumstances, in order that he may 
 study the laws of their production f. 
 
 19. But the decisive argument against the separation 
 of natural and artificial crystals in our schemes of classi- 
 fication is, that we cannot make such a separation. Sub- 
 stances which were long known only as the products of 
 the laboratory, are often discovered, after a time, in 
 natural deposits. Are the crystals which are found in a 
 forgotten retort or solution to be considered as belong- 
 ing to a different science from those which occur in a 
 deserted mine? And are the crystals which are pro- 
 duced where man has turned a stream of water or air 
 out of its course, to be separated from natural crystals, 
 when the composition, growth, and properties, are exactly 
 the same in both? And again: How many natural cry- 
 stals can we already produce by synthesis ! How many 
 more may we hope to imitate hereafter ! M. Necker 
 himself states^;, that Mitscherlich found, in the scoria3 
 of the mines of Sweden and Germany, artificial minerals 
 having the same composition and the same crystalline 
 
 * Regne Mineral, p. 71 
 
 t We may remark that M. Necker, in his own arrangement of 
 minerals, inserts among his species iron and lead, which do not occur 
 native. 
 
 % Regne Mineral, p. 151. 
 
APPLICATION TO MINERALOGY. 529 
 
 form with natural minerals : as silicates of iron, lime, 
 and magnesia, agreeing with peridot ; bisilicate of iron, 
 lime, and magnesia, agreeing with pyroxene ; red oxide 
 of copper ; oxide of zinc ; protoxide of iron (fer oxydule] ; 
 sulphurets of iron, zinc, lead ; arseniuret of nickel ; black 
 mica. These were accidental results of fusion. But 
 M. Berthier, by bringing together the elements in pro- 
 per quantities, has succeeded in composing similar mine- 
 rals, and has thus obtained artificial silicates, with the 
 same forms and the same characters as natural silicates. 
 Other chemists (M. Haldat, M. Becquerel) have, in like 
 manner, obtained, by artificial processes, other crystals, 
 known previously as occurring naturally. How are 
 these crystals, thus identical with natural minerals, to 
 be removed out of the domain of mineralogy, and trans- 
 ferred to a science which shall classify artificial crystals 
 only ? If this be done, the mineralogist will not be able 
 to classify any specimen till he has human testimony 
 whether it was found naturally occurring or produced 
 by chemical art. Or is the other alternative to be 
 taken, and are these crystals to be given up to mine- 
 ralogy because they occur naturally also? But what 
 can be more unphilosophical than to refer to separate 
 sciences the results of chemical processes closely allied, 
 and all but identical? The chemist constructs bisili- 
 cates, and these are classified by the mineralogist : but 
 if he constructs a trisilicate, it belongs to another 
 science. All these intolerable incongruities are avoided 
 by acknowledging that artificial, as well as natural, 
 crystals belong to the domain of mineralogy. It is, in 
 fact, the name only of Mineralogy which appears to dis- 
 cover any inconsistency in this mode of proceeding. 
 Mineralogy is the representative of a science which has 
 a wider office than mineralogists first contemplated ; but 
 which must exist, in order that the body of science may 
 VOL. i. w. p. M M 
 
530 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 be complete. There must, as we have already said, be 
 a Science, the object of which is to classify bodies by 
 their physical characters, in order that we may have 
 some means of asserting chemical truths concerning 
 bodies ; some language in which we may express the 
 propositions which chemical analysis discovers. And 
 this Science will have its object prescribed, not by any 
 accidental or arbitrary difference of the story belonging 
 to each specimen ; not by knowing whether the speci- 
 men was found in the mine or in the laboratory ; pro- 
 duced by attempting to imitate nature, or to do violence 
 to her : but will have its course determined by its own 
 character. The range and boundaries of this Science 
 will be regulated by the Ideas with which it deals. 
 Like all other sciences, it must extend to everything to 
 which its' principles apply. The limits of the province 
 which it includes are fixed by the consideration that it 
 must be a connected whole. No previous definition, no 
 historical accident, no casual phrase, can at all stand in 
 the way of philosophical consistency; can make this 
 Science exclude what that includes, or oblige it to admit 
 what that rejects. And thus, whatever we call our 
 Science ; whether we term it External Chemistry, 
 Mineralogy, the Natural History of Inorganic Bodies; 
 since it can be nothing but the Science of the Classi- 
 fication of Inorganic Bodies of definite forms and pro- 
 perties, it must classify all such bodies, whether or not 
 they be minerals, and whether or not they be natural. 
 
 20. In the application of the principles of classifica- 
 tion to minerals, the question occurs, What are to be 
 considered as mineral Species f By Species we are to 
 understand, according to the usage of other parts of 
 natural history, the lowest step of our subordinate divi- 
 sions ; the most limited of the groups which have defi- 
 nite distinctions. What definite distinctions of groups 
 
APPLICATION TO MINERALOGY. 531 
 
 of objects of any kind really occur in nature, is to be 
 learnt from an examination of nature : and the result 
 of our inquiries will be some general principle which 
 connects the members of each group, and distinguishes 
 the members of groups which, though contiguous, are 
 different. In the classification of organized bodies, the 
 rule which thus presides over the formation of Species 
 is the principle of reproduction. Those animals and 
 those plants are of the same Species which are produced 
 from a common stock, or which resemble each other as 
 much as the progeny of a common stock. Accordingly 
 in practice, if any questions arise whether two varieties 
 of form be of the same or different species, it is settled 
 by reference to the fact of reproduction ; and when it is 
 ascertained that the two forms come within the habitual 
 and regular limits of a common circle of reproduction, 
 they are held to be of the same species. Now in cry- 
 stals, this principle of reproduction disappears altogether, 
 and the basis of the formation of species must be sought 
 elsewhere. We must have some other principle to 
 replace the reproduction which belongs only to organic 
 life. This principle will be, we may expect, one which 
 secures the permanence and regularity of mineral forms, 
 as the reproductive power does of animal and vegetable. 
 Such a principle is the Power of Crystallization. The 
 forces of which solidity, cohesion, and crystallization are 
 the result, are those which give to minerals their perma- 
 nent existence and their physical properties ; and ever 
 since the discovery of the distinctions of Crystalline 
 Forms and Crystalline Systems, it is certain that this 
 force distinguishes groups of crystals in the most pre- 
 cise and definite manner. The rhombohedral carbonates 
 of lime and of iron, for instance, are distinguished ex- 
 actly by the angles of their rhombohedrons. And if, in 
 the case of any proposed crystal, we should doubt to 
 
 MM 2 
 
532 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 which kind the specimen belongs, the measurement of 
 the angles of cleavage would at once decide the ques- 
 tion. The principle of Crystallization therefore appears, 
 from analogy, to be exactly fitted to take the place of 
 the principle of animal Generation. The forces which 
 make the individual permanent and its properties 
 definite, here stand in the place of the forces which 
 preserve the race, while individuals are generated and 
 die. 
 
 21. According to this view, the different modifica- 
 tions of the same crystalline form would be Varieties 
 only of the same species. All the various solids, for 
 example, which are produced by the different laws of 
 derivation of rhombohedral carbonate of lime, would 
 fall within the same Species. And this appears to be 
 required by the general analogy of Natural History. For 
 these differences of form, produced by the laws of crys- 
 talline derivation, are not definite. The faces which are 
 added to one form in order to produce another, may be 
 of any size, small or large, and thus the crystal which 
 represents one modification passes by insensible degrees 
 to another. The forms of calc spar, which we call dog- 
 tooth spar, cannon spar, nail-head spar, and the like, 
 appear at first, no doubt, distinct enough ; but so do 
 the races of dogs. And we find, in the mineral as in 
 the animal, that the distinction is obliterated by taking- 
 such intermediate steps as really occur. And if a frag- 
 ment of any of these crystals is given us, we can deter- 
 mine that it is rhombohedral carbonate of lime ; but it 
 is not possible, in general, to determine to which of the 
 kinds of crystal it has belonged. 
 
 22. Notwithstanding these considerations, M. Necker 
 has taken for his basis of mineral species * the Secon- 
 dary Modifications, and not the Primary Forms. Thus 
 
 * Regne Mineral, p. 396. 
 
APPLICATION TO MINERALOGY. 533 
 
 cubical galena, octahedral galena, and triform galena, 
 are, with him, three species of crystals. 
 
 On this I have to observe, as I have already done, 
 that on this principle we have no definite distinction of 
 species; for these forms may and do pass into each 
 other : among cubo-octahedrons of galena occur cubes 
 and octahedrons, as one face or another vanishes, and 
 the transition is insensible. We shall, on this principle, 
 find almost always three or four species in the same tuft 
 of crystals ; for almost every individual in such assem- 
 blages may exhibit a different combination of secondary 
 faces. Again, in cases where the secondary laws are 
 numerous, it would be impracticable to enumerate all 
 their combinations, and impossible therefore to give a 
 list of species. Accordingly M. Necker* gives seventy- 
 one Species of spaih calcaire, and then says, "Nous 
 n'avons pas enumere la dixieme partie des especes con- 
 nues de ce genre, qui se montent a plus de huit cents." 
 Again, in many substances, of which few crystals are 
 found, every new specimen would be a new species ; if 
 indeed it were perfect enough to be referred to a species 
 at all. But from a specimen without perfect external 
 form, however perfect in crystalline character, although 
 everything else might be known, angles, optical pro- 
 perties, physical properties, and chemical constitution, 
 the species could not be determined. Thus M. Necker 
 saysf of the micas, " Quant aux especes propre a chaque 
 genre, la lacune sera presque complete ; car jusqu'ici 
 les cristaux entiers de Mica et de Talc n'ont pas ete fort 
 communs." 
 
 These inconveniences arise from neglecting the lead- 
 ing rule of natural history, that the predominant prin- 
 ciple of the existence of an object must determine the 
 Species ; whether this principle be Reproduction operat- 
 
 * Regnc Mineral, p. 36'4. t Ib., n. 414. 
 
534 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 ing for Developement, or Crystallization operating for 
 Permanence of form. We may add to the above state- 
 ment of inconveniences this ; that if M. Necker's view 
 of mineralogical species be adopted, the distinction of 
 Species is vague and indefinite, while that of Genera is 
 perfectly precise and rigorous ; an aspect of the system 
 entirely at variance with other parts of Natural History ; 
 for in all these the Species is a more definite group than 
 the Genus. 
 
 This result follows, as has already been said, from 
 M. Necker's wish to have individuals marked by ex- 
 ternal form. If, instead of this, we are contented to 
 take for an individual that portion of a mass, of whatever 
 form, which is connected by the continuous influence of 
 the same crystalline forces, by whatever incidents these 
 forces may be manifested, (as cleavage, physical and 
 optical properties, and the like,) our mode of proceeding 
 avoids all the above inconveniences, applies alike to the 
 most perfect and most imperfect specimens, and gives 
 a result agreeable to the general analogy of natural his- 
 tory, and the rules of its methods""". 
 
 I now quit the subject of mere Resemblance, and 
 proceed to treat of that natural affinity which Natural 
 Systems of Classification for organic bodies must in- 
 volve. 
 
 * I will not again enter into the subject of Nomenclature ; but 
 I may remark that M. Necker has adopted (i. 415) the Nomenclature 
 of Beudant, latinizing the names, and thus converting each into a single 
 word. He has also introduced, besides the names of Genera, names of 
 Families taken from the typical Genus. Thus the Family of Carhu- 
 nidiens contains the following genora : CalcispalhUm, Magnesispathvm, 
 Dolomispalhum, Ferrispaihum, &c., Malachita, Azuria, Gaylusacia. 
 
H|;A OF NATURAL AFFINITY. 535 
 
 CHAPTER IV. 
 OF THE IDEA OF NATURAL AFFINITY. 
 
 1. IN the Second Chapter of this Book it was 
 shown that although the Classificatory Sciences proceed 
 ostensibly upon the Idea of Resemblance as their main 
 foundation, they necessarily take for granted in the course 
 of their progress a further Idea of Natural Affinity. 
 This appeared"'" by a general consideration of the nature 
 of Science, by the recognition of natural species and 
 genera, even in Artificial Systems of Classification f, and 
 by the attempts of botanists to form a Natural System. 
 It further appeared that among the processes by which 
 endeavours have been made to frame a Natural System, 
 some, as the method of Blind Trial and the method or 
 General Comparison, have been altogether unsuccessful 
 being founded only upon a collection of resemblances, 
 casual in the one case and arbitrary in the other. In 
 neither of these processes is there employed any general 
 principle by which we may be definitely directed as to 
 what resemblances we should employ, or by which the 
 result at which we arrive may be verified and confirmed. 
 Our object in the present chapter is to show that the 
 Idea of Natural Affinity supplies us with a principle 
 which may answer such purposes. 
 
 I shall first consider the Idea of Affinity as exempli- 
 fied in organized beings. In doing this, we may appear 
 to take for granted Ideas which have not yet come under 
 our discussion, as the Ideas of Organization, and Vital 
 Function ; but it will be found that the principle to which 
 we are led is independent of these additional Ideas. 
 
 2. We have already seen that the attempts to dis- 
 cover the divisions which results from this Natural 
 Affinity have led to the consideration of the Subordina- 
 
 Art. 5. t Art, 7- 
 
536 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 tion of Characters. It is easy to see that some organs 
 are more essential than others to the existence of an 
 organized being ; the organs of nutrition, for example, 
 more essential than those of locomotion. But at the 
 same time it is clear that any arbitrary assumption of a 
 certain scale of relative values of different kinds of cha- 
 racters will lead only to an Artificial System. This will 
 happen, if, for example, we begin by declaring the nutri- 
 tive to be superior in importance to the reproductive 
 functions. It is clear that this relation of importance 
 of organs and functions must be collected by the study 
 of the organized beings ; and cannot be determined d 
 priori, without depriving us of all right to expect a 
 general accordance between our system and the arrange- 
 ment of nature. We see, therefore, that our notion of 
 Natural Affinity involves in it this consequence ; that 
 it is not to be made out by an arbitrary subordination 
 of characters. 
 
 3. The functions and actions of living things which 
 we separate from each other in our consideration, cannot 
 be severed in nature. Each function is essential ; Life 
 implies a collection of movements, and ceases when any 
 of these movements is stopped. A change in the or- 
 ganization subservient to one set of functions may lead 
 necessarily to a change in the organization belonging to 
 others. We can often see this necessary connexion; and 
 from a comparison of the forms of organized beings, 
 from the way in which their structure changes in pass- 
 ing from one class to another, we are led to the convic- 
 tion that there is some general principle which connects 
 and graduates all such changes. When the circulatory 
 system changes, the nervous system changes also : when 
 the mode of locomotion changes, the respiration is also 
 modified. 
 
 4. These corresponding changes may be considered 
 
IDEA OF NATURAL AFFINITY. 537 
 
 as ways in which the living thing it fitted to its mode 
 of life ; as marks of adaptation to a purpose ; or, as it 
 has been otherwise expressed, as results of the condi- 
 tions of existence. But at the present moment, we put 
 forward these correspondencies in a different light. We 
 adduce them as illustrations of what we mean by Affinity, 
 and what we consider as the tendency of a Natural 
 Classification. It has sometimes been asserted that 
 if we were to classify any of the departments of or- 
 ganized nature by means of one function, and then 
 by means of another, the two classifications, if each 
 strictly consistent with itself, would be consistent with 
 each other. Such an assertion is perhaps more than 
 we are entitled to make with confidence ; but it shows 
 very well what is meant by Affinity. The disposition to 
 believe such a general identity of all partial natural clas- 
 sifications, shows how readily we fix upon the notion of 
 Affinity, as a general result of the causes which deter- 
 mine the forms of living things. When these causes or 
 principles, of whatever nature they are conceived to be, 
 vary so as to modify one part of the organization of the 
 being, they also modify another: and thus the groups 
 which exhibit this variation of the fundamental princi- 
 ples of form, are the same, whether the manifestation of 
 the change be sought in one part or in another of the 
 organized structure. The groups thus formed are re- 
 lated by Affinity; and in proportion as we find the 
 evidence of more functions and more organs to the pro- 
 priety of our groups, we are more and more satisfied 
 that they are Natural Classes. It appears, then, that 
 our Idea of Affinity involves the conviction of the coin- 
 cidence of natural arrangements formed on different 
 functions ; and this, rather than the principle of the sub- 
 ordination of some characters to others, is the true 
 ground of the natural method of Classification. 
 
538 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 5. For example, Cuvier, after speaking of the Sub- 
 ordination of Characters as the guide which he intends 
 to follow in his arrangement of animals, interprets this 
 principle in such a manner"" as to make it agree nearly 
 with the one just stated. "In pursuance of what has 
 been said on methods in general, we now require to 
 know what characters in animals are the most influen- 
 tial, and therefore those which must be made the grounds 
 of the primary divisions." " These," he says, " it is clear 
 must be those which are taken from the animal func- 
 tions ; sensation and motion :" But how does he con- 
 firm this? Not by showing that the animal functions 
 are independent of, or predominant over, the vegetative, 
 but by observing that they follow the same gradations. 
 "Observation," he continues, "confirms this view, by 
 showing that the degrees of developement and compli- 
 cation of the animal functions agree with those of the 
 vegetative. The heart and the organs of the circulation 
 are a sort of center for the vegetative functions, as the 
 brain and the trunk of the nervous system are for the 
 animal functions. Now we see these two systems de- 
 scend in the scale, and disappear the one with the other. 
 In the lowest animals, when there are no longer any 
 distinct nerves, there are also no longer distinct fibres, 
 and the organs of digestion are simply hollowed out in 
 the homogeneous mass of the body. The muscular 
 system disappears even before the nervous, in insects; 
 but in general the distribution of the medullary masses 
 corresponds to that of the muscular instruments ; a spi- 
 nal cord, on which knots or ganglions represent so many 
 brains, corresponds to a body divided into numerous 
 rings and supported on pairs of members placed at dif- 
 ferent points of the length, and so on. 
 
 "This correspondence of the general forms which 
 
 * Regnc Animal, p. 55. 
 
IDEA OF NATURAL AFFINITY. 539 
 
 result from the arrangement of the motive organs, from 
 the distribution of the nervous masses, and from the 
 energy of the circulatory system, must therefore form 
 the ground of the first great sections by which we divide 
 the animal kingdom." 
 
 6. Decandolle takes the same view. There must be, 
 he says, an equilibrium of the different functions""". 
 And he exemplifies this by the case of the distinction of 
 monocotyledonous and dicotyledonous plants, which 
 being at first established by means of the organs of 
 reproduction, was afterwards found to coincide with 
 the distinction of endogenous and exogenous, which 
 depends on the process of nutrition. " Thus," he adds, 
 " the natural classes founded on one of the great func- 
 tions of the vegetable are necessarily the same as those 
 which are founded upon the other function ; and I find 
 here a very useful criterion to ascertain whether a class 
 is natural : namely, in order to announce that it is so, 
 it must be arrived at by the two roads which vegetable 
 organization presents. Thus I affirm," he says, "that 
 the division of monocotyledons from dicotyledons, and 
 the distinction of Graminese from Cyperacese, are real, 
 because in these cases, I arrive at the same result by 
 the reproductive and the nutritive organs; while the 
 distinction of monopetalous and polypetalous, of Rho- 
 doracese and Ericineae appears to me artificial, because 
 I can arrive at it only by the reproductive organs." 
 
 Thus the correspondence of the indications of different 
 functions is the criterion of Natural Classes; and this 
 correspondence may be considered as one of 'the best 
 and most characteristic marks of the fundamental Idea 
 of Affinity. And the Maxim by which all Systems pro- 
 fessing to be natural must be tested is this : that the 
 arrangement obtained from one set of characters coin- 
 cides with tltr arraitgcnK'nt obtained from another set. 
 
 * Theor. Elcm., p. 79. 
 
540 PHILOSOPHY OF THE CLASSIFICATOKY SCIENCES. 
 
 This Idea of Affinity, as a natural connexion among 
 various species, of which connexion all particular resem- 
 blances are indications, has principally influenced the 
 attempts at classifying the animal kingdom. The reason 
 why the classification in this branch of Natural History 
 has been more easy and certain than that of the vege- 
 table world is, as Decandolle says*, that besides the 
 functions of nutrition and reproduction, which animals 
 have in common with plants, they have also in addition 
 the function of sensation ; and thus have a new means 
 of verification and concordance. But we may add, as a 
 further reason, that the functions of animals are neces- 
 sarily much more obvious and intelligible to us than 
 those of vegetables, from their clear resemblance to the 
 operations which take place in our own bodies, to which 
 our attention has necessarily been strongly directed. 
 
 7. The question here offers itself, whether this Idea 
 of Natural Affinity is applicable to inorganic as well as 
 to organic bodies ; whether there be Natural Affinities 
 among Minerals. And to this we are now enabled to 
 reply by considering whether or not the principle just 
 stated is applicable in such cases. And the conclusion 
 to which our principle leads us is, that there are such 
 Natural Affinities among Minerals, since there are dif- 
 ferent sets of characters which may be taken, (and have 
 by different writers been taken,) as the basis of classifi- 
 cation. The hardness, specific gravity, colour, lustre, 
 crystallization, and other external characters, as they 
 are termed, form one body of properties according to 
 which minerals may be classified ; as has in fact been 
 done by Mohs, Breithaupt, and others. The chemical 
 constitution of the substances, on the other hand, may 
 be made the principle of their arrangement, as was done 
 by Hauy, and more recently, and on a different scheme, 
 by Berzelius. Which of these is the true and natural 
 * Theor. Elem., p. 80. 
 
IDEA OF NATURAL AFFINITY. 541 
 
 classification? To this we answer, that each of these 
 arrangements is true and natural, then, and then only, 
 when it coincides with the other. An arrangement by 
 external characters which gives us classes possessing a 
 common chemical character; a chemical order which 
 brings together like and separates unlike minerals; 
 such classifications have the evidence of truth in their 
 agreement with one another. Every classification of 
 minerals which does not aim at and tend to such a 
 result, is so far merely arbitrary; and cannot be sub- 
 servient to the expression of general chemical and mine- 
 ralogical truths, which is the proper purpose of such a 
 classification. 
 
 8. In the History of Mineralogy I have related the 
 advances which have been made among mineralogists 
 and chemists in modern times towards a System possess- 
 ing this character of truth. I have there described 
 the mixed systems of Werner and Haiiy ; the attempt 
 made by Mohs to form a pure Natural History system ; 
 the first and second attempt of Berzelius to form a 
 pure chemical system ; and the failure of both these 
 attempts. But the distinct separation of the two ele- 
 ments of which science requires the coincidence threw a 
 very useful light upon the subject ; and the succeeding 
 mixed systems, such as that of Naumann, approached 
 much nearer to the true conditions of the problem than 
 any of the preceding ones had done. Thus, as I have 
 stated, several of Naumann's groups have both a com- 
 mon chemical character and great external resemblances. 
 Such are his Anhydrous Unmetallic Haloids his Anhy- 
 drous Metallic Haloids Hydrous Metallic Haloids- 
 Oxides of metals Pyrites Glances Blendes. The 
 existence of such groups shows that we may hope ulti- 
 mately to obtain a classification of minerals which shall 
 be both chemically significant and agreeable to the 
 
542 PHILOSOPHY OF THE CLASSIFICATORY SCIENCES. 
 
 methods of Natural History : although when we con- 
 sider how very imperfect as yet our knowledge of the 
 chemical composition of minerals is, we can hardly flat- 
 ter ourselves that we shall arrive at such a result very 
 soon. 
 
 We have thus seen that in Mineralogy, as well as in 
 the sciences which treat of organized bodies, we may 
 apply the Idea of Natural Affinity ; of which the funda- 
 mental maxim is, that arrangements obtained from dif- 
 ferent sets of characters must coincide. 
 
 Since the notion of Affinity is thus applicable to 
 inorganic as well as to organic bodies, it is plain that it 
 is not a mere modification of the Idea of Organization 
 or Function, although it may in some of its aspects 
 appear to approach near to these other Ideas. But 
 these Ideas, or others which are the foundation of them, 
 necessarily enter in a very prominent and fundamental 
 manner into all the other parts of Natural History. To 
 the consideration of these, therefore, we shall now 
 proceed. 
 
BOOK IX. 
 
 THE PHILOSOPHY OF BIOLOGY. 
 
 CHAPTER I. 
 ANALOGY OF BIOLOGY WITH OTHER SCIENCES. 
 
 1. IN the History of the Sciences, after treating of 
 the Sciences of Classification, we proceeded to what are 
 there termed the Organical Sciences, including in this 
 term Physiology and Comparative Anatomy. A peculiar 
 feature in this group of sciences is that they involve the 
 notion of living things. The notion of Life, however 
 vague and obscure it may be in men's minds, is appre- 
 hended as a peculiar Idea, not resolvable into any other 
 Ideas, such, for instance, as Matter and Motion. The 
 separation between living creatures and inert matter, 
 between organized and unorganized beings, is conceived 
 as a positive and insurmountable barrier. The two 
 classes of objects are considered as of a distinct kind, 
 produced and preserved by different forces. Whether 
 the Idea of Life is really thus original and fundamental, 
 and whether, if so, it be one Idea only, or involve 
 several, it must be the province of true philosophy to 
 determine. What we shall here offer may be considered 
 as an attempt to contribute something to the determina- 
 tion of these questions ; but we shall perhaps be able 
 to make it appear that science is at present only in the 
 course of its progress towards a complete solution of 
 such problems. 
 
544 PHILOSOPHY OF BIOLOGY. 
 
 Since the main feature of those sciences of which 
 we have now to examine the philosophy is, that they 
 involve the Idea of Life, it would be desirable to have 
 them designated by a name expressive of that circum- 
 stance. The word Physiology, by which they have most 
 commonly been described, means the Science of Nature ; 
 and though it would be easy to explain, by reference to 
 history, the train of thought by which the word was 
 latterly restricted to Living Nature, it is plain that the 
 name is, etymologically speaking, loose and improper. 
 The term Biology, which means exactly what we wish 
 to express, the Science of Life, has often been used, and 
 has of late become not uncommon among good writers. 
 I shall therefore venture to employ it, in most cases, 
 rather than the word Physiology. 
 
 2. As I have already intimated, one main inquiry 
 belonging to the Philosophy of Biology, is concerning the 
 Fundamental Idea or Ideas which the science involves. 
 If we look back at the course and the results of our dis- 
 quisitions respecting other sciences in this work, and 
 assume, as we may philosophically do, that there will be 
 some general analogy between those sciences and this, 
 in their developement and progress, we shall be enabled 
 to anticipate in some measure the nature of the view 
 which we shall now have to take. We have seen that 
 in other subjects the Fundamental Ideas on which sci- 
 ence depended, and the Conceptions derived from these, 
 were at first vague, obscure, and confused; that by 
 gradual steps, by a constant union of thought and obser- 
 vation, these conceptions become more and more clear, 
 more and more definite; and that when they approached 
 complete distinctness and precision, there were made 
 great positive discoveries into which these conceptions 
 entered, and thus the new precision of thought was 
 fixed and perpetuated in some conspicuous and lasting 
 
ANALOGY OF BIOLOGY WITH OTHER SCIENCES. 545 
 
 truths. Thus we have seen how the first confused me- 
 chanical conceptions (Force, and the like,) were, from 
 time to time, growing clearer, down to the epoch of 
 Newton ; how true conceptions of Genera and of wider 
 classes, gradually unfolded themselves among the botan- 
 ists of the sixteenth and seventeenth centuries ; how 
 the idea of Substance became steady enough to govern 
 the theories of chemists only at the epoch of Lavoisier ; 
 how the Idea of Polarity, although often used by phy- 
 sicists and chemists, is even now somewhat vague and 
 indistinct in the minds of the greater part of speculators. 
 In like manner we may expect to find that the Idea of 
 Life, if indeed that be the governing Idea of the Science 
 which treats of Living Things, will be found to have 
 been gradually approaching towards a distinct and defi- 
 nite form among the physiologists of all ages up to the 
 present day. And if this be the case, it may not be 
 considered superfluous, with reference to so interesting 
 a subject, if we employ some space in tracing historically 
 the steps of this progress; the changes by which the 
 originally loose notion of Life, or of Vital Powers, 
 became more nearly an Idea suited to the purposes of 
 science. 
 
 3. But we may safely carry this analogy between 
 Biology and other sciences somewhat further. We have 
 seen, in other sciences, that while men in their specula- 
 tions were thus tending towards a certain peculiar Idea, 
 but before they as yet saw clearly that it was peculiar 
 and independent, they naturally and inevitably clothed 
 their speculations in conceptions borrowed from some 
 other extraneous idea. And the unsatisfactoriness of 
 all such attempts, and the necessary consequence of this, 
 a constant alteration and succession of such inappro- 
 priate hypotheses, were indications and aids of the pro- 
 gress which was going on towards a more genuine form 
 VOL. i. w. P. N N 
 
540 PHILOSOPHY OF BIOLOGY. 
 
 of the science. For instance, we have seen that in che- 
 mistry, so long as men refused to recognize a peculiar 
 and distinct kind of power in the Affinity which binds 
 together the elements of bodies, they framed to them- 
 selves a series of hypotheses, each constructed according 
 to the prevalent ideas of the time, by which they tried 
 to represent the relation of the compound to the ingre- 
 dients : first, supposing that the elements bestowed 
 upon the whole qualities resembling their own : then 
 giving up this supposition, and imagining that the pro- 
 perties of the body depended upon the shape of the 
 component particles; then, as their view expanded, 
 assuming that it was not the shape, but the mechanical 
 forces of the particles which gave the body its attributes; 
 and finally acquiescing in, or rather reluctantly admit- 
 ting, the idea of Affinity, conceived as a peculiar power, 
 different not only from material contact, but from any 
 mechanical or dynamical attraction. 
 
 Now we cannot but think it very natural, if we find 
 that the history of Biology offers a series of occurrences 
 of the same nature. The notions of Life in general, 
 or of any Vital Functions or Vital Forces in particular, 
 are obviously very loose and vague as they exist in the 
 minds of most men. The discrepancies and contro- 
 versies respecting the definitions of all such terms, which 
 are found in all works on physiology, afford us abundant 
 evidence that these notions are not, at least not gene- 
 rally, apprehended with complete clearness and steadi- 
 ness. We shall therefore find approaches and advances, 
 intermediate steps, gradually leading up to the greatest 
 degree of distinctness which has yet been attained. And 
 in those stages of imperfect apprehension in which the 
 notions of Life and of Vital Powers are still too loose 
 and unformed to be applied independently, we may 
 expect to find them supported and embodied by means 
 
ANALOGY OF BIOLOGY WITH OTHER SCIENCES. 547 
 
 of hypotheses borrowed from other subjects, and thus, 
 made so distinct and substantial as to supply at least a 
 temporary possibility of scientific reasoning upon the 
 laws of life. 
 
 4. For example, if we suppose that men begin to 
 speculate upon the properties of living things, not 
 acknowledging a peculiar Vital Power, but making use 
 successively of the knowledge supplied by the study of 
 other subjects, we may easily imagine a series of hypo- 
 theses along which they would pass. 
 
 They would probably, first, in this as in other sciences, 
 have their thoughts occupied by vague and mystical no- 
 tions in which material and spiritual agency, natural and 
 supernatural events, were mixed together without discri- 
 mination, and without any clear notion at all. But as 
 they acquired a more genuine perception of the nature 
 of knowledge, they would naturally try to explain vital 
 motions and processes by means of such forces as they 
 had learnt the existence of from other sciences. They 
 might first have a mechanical hypothesis, in which the 
 mechanical forces of the solids and fluids which compose 
 organized bodies should be referred to, as the most im- 
 portant influences in the process of life. They might 
 then attend to the actions which the fluids exercise in 
 virtue of their affinity, and might thus form a chemical 
 theory. When they had proved the insufficience of these 
 hypotheses, borrowed from the powers which matter 
 exhibits in other cases, they might think themselves 
 authorized to assume some peculiar power or agency, 
 still material, and thus they would have the hypothesis 
 of a vital fluid. And if they were driven to reject this, 
 they might think that there was no resource but to 
 assume an immaterial principle of life, and thus they 
 would arrive at the doctrine of an animal soul. 
 
 Now, through the cycle of hypotheses which we have 
 
 N N 2 
 
548 PHILOSOPHY OF BIOLOGY. 
 
 thus supposed, physiology has actually passed. The con- 
 clusions to which the most philosophical minds have been 
 led by a survey of this progress is, that by the failure of 
 all these theories, men have exhausted this path of in- 
 quiry, and shown that scientific truth is to be sought in 
 some other manner. But before I proceed further to 
 illustrate this result, it will be proper, as I have already 
 stated, to exhibit historically the various hypotheses 
 which I have described. In doing this I shall princi- 
 pally follow the History of Medicine of Sprengel. It 
 is only by taking for my guide a physiologist of acknow- 
 ledged science and judgment, that I can hope, on such 
 a subject, to avoid errours of detail. I proceed now 
 to give in succession an account of the Mystical, the 
 latrochemical, the latromathematical, and the Vital- 
 Fluid Schools ; and finally of the Psychical School, who 
 hold the Vital Powers to be derived from the Soul 
 (Psyche}. 
 
 CHAPTER II. 
 SUCCESSIVE BIOLOGICAL HYPOTHESES. 
 
 SECT. I. The Mystical School. 
 
 IN order to abbreviate as much as can conveniently 
 be done the historical view which I have now to take, I 
 shall altogether pass over the physiological speculations 
 of the ancients, and begin my survey with the general 
 revival of science in modern times. 
 
 We need not dwell long on the fantastical and unsub- 
 stantial doctrines concerning physiology which prevailed 
 in the sixteenth century, and which flowed in a great 
 measure from the fertile but ill-regulated imaginations of 
 the cultivators of Alchemy and Magic. One of the pro- 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 549 
 
 minent doctors of this school is the celebrated Paracelsus, 
 whose doctrines contained a combination of biblical in- 
 terpretations, visionary religious notions, fanciful ana- 
 logies, and bold experiments in practical medicine. The 
 opinion of a close but mystical resemblance of parts be- 
 tween the universe and the human body, the Macrocosm 
 and the Microcosm, as these two things, thus compared, 
 were termed, had probably come down from the Neopla- 
 tonists; it was adopted by the Paracelsists*, and con- 
 nected with various astrological dreams and cabbalistic 
 riddles. A succession of later Paracelsists f, Rosicrucians, 
 and other fanatics of the same kind, continued into the 
 seventeenth century. Upon their notions was founded 
 the pretension of curing wounds by a sympathetic powder, 
 which Sir Kenelm Digby, among others, asserted ; while 
 animal magnetism, and the transfer of diseases from one 
 person to another;];, were maintained by others of this 
 school. They held, too, the doctrines of astral bodies 
 corresponding to each terrestrial body ; and of the sig- 
 natures of plants, that is, certain features in their exter- 
 nal form by which their virtues might be known. How 
 little advantage or progress real physiology could derive 
 from speculations of this kind may be seen from this, 
 that their tendency was to obliterate the distinction 
 between living and lifeless things : according to Para- 
 celsus, all things are alive, eat, drink, and excrete ; even 
 minerals and fluids $. According to him and his school, 
 besides material and immaterial beings, there are ele- 
 mentary Spirits which hold an intermediate place, 
 Sylvans, Nymphs, Gnomes, Salamanders, &c. by whose 
 agency various processes of enchantment may be achiev- 
 ed, and things apparently supernatural explained. Thus 
 this spiritualist scheme dealt with a world of its own by 
 
 * Spr., in. 456. t /&., iv. 270. J /., iv. 276. 
 
 //>., in. 458. Parac. De Vita Re-rum Naturalium, p. 889. 
 
550 PHILOSOPHY OF BIOLOGY. 
 
 means of fanciful inventions and mystical visions, instead 
 of making any step in the study of nature. 
 
 Perhaps, however, one of the most fantastical of the 
 inventions of Paracelsus may be considered as indicating 
 a perception of a peculiar character in the vital powers. 
 According to him, the business of digestion is performed 
 by a certain demon whom he calls Archceus, who has his 
 abode in the stomach, and who, by means of his alche- 
 mical processes, separates the nutritive from the harm- 
 ful part of our food, and makes it capable of assimila- 
 tion*. This fanciful notion was afterwards adopted and 
 expanded by Van Helmontf. According to him the 
 stomach and spleen are both under the direction of this 
 Master-spirit, and these two organs form a sort of Duum- 
 virate in the body. 
 
 But though we may see in such writers occasional 
 gleams of physiological thought, the absence of definite 
 physical relations in the speculations thus promulgated 
 was necessarily intolerable to men of sound understand- 
 ing and scientific tendencies. Such men naturally took 
 hold of that part of the phenomena of life which could 
 be most distinctly conceived, and which could be appa- 
 rently explained by means of the sciences then culti- 
 vated; and this was the part which appeared to be 
 reducible to chemical conceptions and doctrines. It will 
 readily be supposed that the processes of chemistry 
 have a considerable bearing upon physiological pro- 
 cesses, and might, till their range was limited by a 
 sound investigation, be supposed to have still more than 
 they really had ; and thus a Physiology was formed 
 which depended mainly upon Chemistry, and the school 
 which held this doctrine has been called the latrochemi- 
 cal School. 
 
 * Spr., in. 468. t /^., iv. 302. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 551 
 
 SECT. II. The latrochemical School. 
 
 That all physical properties, and therefore chemical 
 relations, have a material influence on physiological 
 results, was already recognized, though dimly, in the 
 Galenic doctrine of the "four elementary qualities." 
 But at the time of Paracelsus, chemical action was more 
 distinctly than before separated from other kinds of 
 physical action ; and therefore a physiological doctrine, 
 founded upon chemistry, and freed from the extrava- 
 gance and mysticism of the Paracelsists, was a very 
 promising path of speculation. Andrew Libavius* of 
 Halle, in Saxony, Physician and Teacher in the Gym- 
 nasium at Koberg, is pointed out by Sprengel as the 
 person who began to cultivate chemistry, as distinct from 
 the theosophic fantasies of his predecessors; and Angelus 
 Sala of Vienna f, as his successor. The latter has the 
 laudable distinction of having rejected the prevalent 
 conceits about potable gold, a universal medicine, and 
 the likej. In Germany already at the beginning of the 
 seventeenth century a peculiar chair of Chymiatria was 
 already created at Marpurg : and many in various places 
 pursued the same studies, till, in the middle of the seven- 
 teenth century, we come to Lemery, the principal 
 reformer of pharmaceutical chemistry. But we are not 
 here so much concerned with the practical as with the 
 theoretical parts of latrochemistry ; and hence we pass 
 on to Sylvius || and his system. 
 
 The opinion that chemistry had an important bearing 
 upon physiology did not, however, begin with Sylvius. 
 Paracelsus, among his extravagant absurdities, did some 
 service to medicine by drawing attention to this important 
 truth. He used If chemical principles for the explanation 
 
 * Spr., in. 550. t /A., iv. 281. $ 76., iv. 283. 
 
 76., iv. 291. || 76., iv. 33fi. IF 76., m. 472. 
 
552 PHILOSOPHY OF BIOLOGY. 
 
 of particular diseases ; most or all diseases according to 
 him, arise from the effervescence of salts, from the com- 
 bustion of sulphur, or from the coagulation of mercury. 
 His medicines were chemical preparations; and it was* 
 an undeniable advantage of the Paracelsian doctrine that 
 chemistry thus became indispensable to the physician. 
 We stil] retain a remnant of the chemical nomenclature 
 of Paracelsus in the term tartar, denoting the stony con- 
 cretion which forms on the teeth f. According to him 
 there is a certain substance, the basis of all diseases which 
 arise from a thickening of the juices and a collection of 
 earthy matter ; and this substance he calls Tartarus, 
 because it " burns like the fire of hell." Helmont, the 
 successor of Paracelsus in many absurdities, also followed 
 him in the attempt to give a chemical account, however 
 loose and wild, of the functions of the human body ; and 
 is by Sprengel considered, with all his extravagancies, as 
 a meritorious and important discoverer. The notion of 
 the fermentation of fluids J, and of the aerial product 
 thence resulting, to which he gave the name of Gas, forms 
 an important part of his doctrines ; and of the six diges- 
 tions which he assumes, t\\e first prepares an acid, which 
 is neutralized by the gall when it reaches the duodenum, 
 and this constitutes the second digestion. 
 
 I have already, in the History of Chemistry , stated, 
 that the doctrine of the opposition of acid and alkali, the 
 great step which theoretical chemistry owes to Sylvius, 
 was first brought into view as a physiological tenet, 
 although we had then to trace its consequences in an- 
 other science. The explanation of all the functions of the 
 animal system, both healthy and morbid, by means of 
 this and other chemical doctrines, and the prescription 
 of methods of cure founded upon such explanations, 
 
 * Spr., in. 482. t lb., in. 475. 
 
 t Vol. v., 315. Hist. Ind, Sci., B. xm. c. 2. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 553 
 
 form the scheme of the iatrochemical school ; a school 
 which almost engrossed the favour of European phy- 
 sicians during the greater part of the seventeenth cen- 
 tury. 
 
 Sylvius taught medicine at Ley den, from the year 
 1658, with so much success, that Boerhaave alone sur- 
 passed him *. His notions, although he piqued himself 
 on their originality, were manifestly suggested in no 
 small degree (as all such supposed novelties are) by the 
 speculations of his predecessors, and the spirit of the 
 times. Like Helmontf, he considers digestion as con- 
 sisting in a fermentation ; but he states it more definitely 
 as the effervescence of an acid, supplied by the saliva 
 and the pancreatic juice, with the alkali of the gall. By 
 various other hypothetical processes, all of a chemical 
 nature, the blood becomes a collection of various juices, 
 which are the subjects of the speculations of the iatro- 
 chemists, to the entire neglect of the solid parts of 
 the body. Diseases were accounted for by a supposed 
 prevalence of one or the other of the acrid principles, 
 the acid or the alkaline : and Sylvius J was bold enough 
 to found upon these hypotheses practical methods of 
 cure, which were in the highest degree mischievous. 
 
 The Sylvian doctrine was often combined with some 
 of the notions of the Cartesian system of philosophy ; 
 but this mixture I shall not notice, since my present 
 object is to trace the history of a mere chemical physio- 
 logy as one of the unsuccessful attempts at a philosophy 
 of life. With various modifications, this doctrine was 
 diffused over Europe. It gave rise to several contro- 
 versies, which turned upon the questions of the novelty 
 of the doctrine, and the use of chemical remedies to 
 which it pointed, as well as upon its theoretical truth. 
 We need not dwell long upon these controversies, al- 
 
 * Spr., iv. 336. t Jfe., 338. J /ft., iv. 345. 
 
554 PHILOSOPHY OF BIOLOGY. 
 
 though they were carried on with no small vehemence 
 in their time. Thus the school of Paris opposed all 
 innovation, remained true to the Galenic dogmatism, and 
 declared itself earnestly against all combination of che- 
 mistry with medicine ; and even against the chemical 
 preparation of medicaments. Guy Patin, a celebrated 
 and learned professor of that day, declares* that the 
 chemists are no better than forgers, and ought to be 
 punished as such. The use of antimonial medicines was 
 a main point of dispute between the iatrochemists and 
 their opponents; Patin maintained that more men had 
 been destroyed by antimony than by the thirty years' war 
 of Germany; and endeavoured to substantiate this asser- 
 tion by collecting all such cases in his Martyrologium 
 Antimonii. It must have been a severe blow to Patin 
 whenf, in 1666, the Doctors of the Faculty of Paris, 
 assembled by command of the parliament, declared, by a 
 majority of ninety-two voices, that the use of antimonial 
 medicines was allowable and laudable, and when all 
 attempts to set aside this decision failed. 
 
 Florentius Schuyl of Leyden sought to recommend 
 the iatrochemical doctrines, by maintaining that they 
 were to be found in the Hippocratic writings ; nor was 
 it difficult to give a chemical interpretation of the 
 humoral pathology of the ancients. The Italian J phy- 
 sicians also, for the most part, took this line, and 
 attempted to show the agreement of the principles of 
 the ancient school of medicine with the new chemical 
 notions. This, indeed, is the usual manner in which the 
 diffusion of new theoretical ideas becomes universal. 
 
 The progress of the chemical school of medicine in 
 
 England requires our more especial notice. Willis was 
 
 the most celebrated champion of this sect. He assumed, 
 
 but with modifications of his own, the three Paracelsian 
 
 * Spr., 349. t lb., iv. 350. J /&., 368. /ft., 353. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 555 
 
 principles, Salt, Sulphur, and Mercury ; considered diges- 
 tion as the effect of an acid, and explained other parts of 
 the animal economy by distillation, fermentation, and the 
 like. All diseases arise from the want of the requisite 
 ferment i and the physician, he says*, may be compared to 
 a vintner, since both the one and the other have to take 
 care that the necessary fermentations go on, that no 
 foreign matter mixes itself with the wine of life, to inter- 
 rupt or derange those operations. In the middle of the 
 seventeenth century, medicine had reached a point in 
 which the life of the animal body was considered as 
 merely a chemical process ; the wish to explain every- 
 thing on known principles left no recognized difference 
 between organized and unorganized bodies, and diseases 
 were treated according to this delusive notion. The 
 condition of chemistry itself during this period, though 
 not one of brilliant progress, was sufficiently stable and 
 flourishing to give a plausibility to any speculation which 
 was founded on chemical principles ; and the real influ- 
 ence of these principles in the animal frame could not be 
 denied. 
 
 The iatrochemists were at first resisted, as we have 
 seen, by the adherents of the ancient schools ; they were 
 attacked on various grounds, and finally deposed from 
 their ascendency by another sect, which we have to 
 speak of, as the iatromathematical, or mechanical school. 
 This sect was no less unsatisfactory and erroneous in its 
 positive doctrines than the chemists had been ; for the 
 animal frame is no more a mere machine than a mere 
 laboratory : but it promoted the cause of truth, by detect- 
 ing and exposing the insufficient explanations and im- 
 proved assertions of the reigning theory. 
 
 Boyle was one of the persons who first raised doubts 
 against the current chemical doctrines of his time, as we 
 
 * Spr., 354. 
 
556 PHILOSOPHY OF BIOLOGY. 
 
 have elsewhere noted; but his objections had no pe- 
 culiar physiological import. Hermann Corn-ing*, the 
 most learned physician of his time, a contemporary 
 with Sylvius, took a view more pertinent to our present 
 object; for he not only rejected the alchemical and 
 hermetical medicines, but taught expressly that che- 
 mistry, in its then existing condition, was better fitted 
 to be of use in the practice of pharmacy, than in the 
 theories of physiology and pathology. He made the 
 important assertion, also, that chemical principles do 
 not pre-exist as such in the animal body ; and that there 
 are higher powers which operate in the organic world, 
 and which do not depend on the form and mixture of 
 matter. 
 
 Attempts were made to prove the acid and alkaline 
 nature of the fluids of the human body by means of 
 experiments, as by John Viridet of Geneva f, and by 
 Raimond Vieussensj, the latter of whom maintained 
 that he had extracted an acid from the blood, and de- 
 tected a ferment in the stomach. In opposition to him, 
 Hecquet, a disciple of the iatromathematical school, 
 endeavoured to prove that digestion was performed, not 
 by means of fermentation, but by trituration. Hecquet's 
 own opinions cannot be defended ; but his objections to 
 the chemical doctrines, and his assertion of the difference 
 of chemical and organical processes, are evidences of 
 just thought $. 
 
 The most important opponents of the iatrochemical 
 school were Pitcairn in England, Bohn and Hoffman in 
 Germany, and Boerhaave in Holland. These eminent 
 physicians, about the end of the seventeenth century, 
 argued on the same grounds of observation, that diges- 
 tion is not fermentation, and that the Sylvian accounts 
 
 * Spr., iv. 361. t //,., iv. 329. 
 
 J /6., 350, (1715.) M., 401. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 557 
 
 of the origin of diseases by means of acid and alkali are 
 false. The arguments and authority of these and other 
 persons finally gained an ascendancy in the medical 
 world, and soon after this period we may consider the 
 reign of the chemical school of physiology as past. In 
 fact, the attempts to prove its assertions experimentally 
 were of the feeblest kind, and it had no solid basis on 
 which it could rest, so as to resist the shock of the next 
 hypothesis which the progress of the physical sciences 
 might impel against it. We may, therefore, now con- 
 sider the opinion of the mere chemical nature of the 
 vital processes as disproved, and we proceed next to 
 notice the history of another unsuccessful essay to reduce 
 vital actions to known actions of another kind. 
 
 SECT. III. The latromathematical School. 
 
 In the first Section of this chapter, we enumerated 
 the biological hypotheses which at first present them- 
 selves, as the mystical, the mechanical, the chemical. 
 We might have expected that they should occur to 
 men's minds in the order thus stated : and in fact they 
 did so ; for the physiology of the ancient materialists, 
 as Democritus and Lucretius, is mechanical so far as it 
 is at all distinct in its views, and thus the mechanical 
 preceded the chemical doctrine. But in modern times, 
 the fluid or chemical physiology was developed before 
 the solid or mechanical : of which the reason appears to 
 have been this ; that Mechanics and Chemistry began 
 to assume a scientific character about the same time; 
 and that of the two, Chemistry not only appeared at 
 first sight more applicable to the functions of the body, 
 because all the more rapid changes appear to be con- 
 nected with modifications of the fluids of the animal 
 system, but also, by its wider range of facts and more 
 indefinite principles, afforded a better temporary refuge 
 
558 PHILOSOPHY OF BIOLOGY. 
 
 for the mind when perplexed by the difficulties and mys- 
 teries which spring out of the speculations concerning 
 life. But if Chemistry was thus at first a more inviting 
 field for the physiologist, Mechanics soon became more 
 attractive in virtue of the splendid results obtained by 
 the schools of Galileo and Newton. And when the 
 insufficiency of chemical physiology was discovered by 
 trial, as we have seen it was, the hope naturally arose, 
 that the mechanical principles which had explained so 
 many of the phenomena of the external universe might 
 also be found applicable to the smaller world of material 
 life ; that the microcosm as well as the macrocosm 
 might have its mechanical principles. From this hope 
 sprung the latromathematical School, or school of Me- 
 chanical Physiologists. 
 
 We may, however, divide this school into two parts, 
 the Italian, and the Cartesio-Newtonian sect. The 
 former employed themselves in calculating and analyz- 
 ing a number of the properties of the animal frame 
 which are undoubtedly mechanical ; the latter, somewhat 
 intoxicated by the supposed triumphs of the corpuscular 
 philosophy, endeavoured to extend these to physiology, 
 and for this purpose introduced into the subject many 
 arbitrary and baseless hypotheses. I will very briefly 
 mention some of the writers of both these sects. 
 
 The main points to which the Italian or genuine 
 Mechanical Physiologists attended, were the application 
 of mechanical calculations to the force of the muscles, 
 and of hydraulical reasonings to the motion of the fluids 
 of the animal system. The success with which Galileo 
 and his disciples had pursued these branches of mecha- 
 nical philosophy, and the ascendency which they had 
 obtained, first in Italy, and then in other lands, made 
 such speculations highly interesting. Borelli may be 
 considered as the first great name in his line, and his 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 559 
 
 book, De Motu Animalium, (Opus Posthumum, Roma?, 
 1 680,) is even now a very instructive treatise on the force 
 and action of the bones and muscles. This, certainly 
 one of the most valuable portions of mechanical phy- 
 siology, has not even yet been so fully developed as it 
 deserves, although John Bernoulli* and his son Danielf 
 applied to it the resources of analysis, and PembertonJ, 
 in England, pursued the same subject. Other of these 
 mechanico-physiological problems consisted in referring 
 the pressure of the blood and of the breath to hydro- 
 statical principles. In this manner Borelli was led to 
 assert that the muscles of the heart exert a force of 
 180,000 pounds $. But a little later, Keill reduced this 
 force to a few ounces If. Keill and others attempted to 
 determine, on similar principles, the velocity of the 
 blood ; we need not notice the controversies which thus 
 arose, since there is not involved in them any peculiar 
 physiological principle. 
 
 The peculiar character of the iatromathematical 
 school, as an attempt at physiological theory, is more 
 manifest in its other section, which we have called the 
 Cartesio-Newtonian. The Cartesian system pretended 
 to account for the appearances and changes of bodies by 
 means of the size, figure, and motion of their minute 
 particles. And though this system in its progress 
 towards the intellectual empire of Europe was suddenly 
 overturned by the rise of the Newtonian philosophy, 
 these corpuscular doctrines rather gained than lost by 
 the revolution ; for the Newtonian philosophy enlarged 
 the powers of the corpuscular hypothesis, by adding the 
 effects of the attractive and repulsive forces of particles 
 to those of their form and motion. By this means, 
 although Newton's discoveries did not in fact augment 
 
 * DC Motu Musculorum. t Act. Acad. Petrop., i. 170. 
 
 Course of Physiology, 1773. Spr., iv. 110. || Ib., 443. 
 
560 PHILOSOPHY OF BIOLOGY. 
 
 the probability of the corpuscular hypothesis, they so far 
 increased its plausibility, that this hypothesis found 
 favour both with Newton himself and his contempora- 
 ries, no less than it had done with the Cartesians. 
 
 The attempt to apply this corpuscular hypothesis to 
 physiology was made by Des Cartes himself. The gene- 
 ral character of such speculations may easily be guessed*. 
 The secretions are effected by the organs operating after 
 the manner of sieves. Round particles pass through 
 cylindrical tubes, pyramidal ones through triangular 
 pores, cubical particles through square apertures, and 
 thus different kinds of matter are separated. Similar 
 speculations were pursued by other mathematicians : 
 the various diameter of the vessels f, their curvatures, 
 folds, and angles, were made subjects of calculation. 
 Bellini, Donzellini, Gulielmini, in Italy; Perrault, Dodart, 
 in France; Cole, Keill, Jurin, in England, were the 
 principal cultivators of such studies. In the earlier part 
 of the eighteenth century, physiological theorists con- 
 sidered it as almost self-evident that their science 
 required them to reason concerning the size and shape 
 of the particles of the fluids, the diameter and form of 
 the invisible vessels. Such was, for instance, the opinion 
 of Cheyne^;, who held that acute fevers arise from the 
 obstruction of the glands, which occasions a more vehe- 
 ment motion of the blood. Mead, the physician of the 
 King, and the friend of Newton, in like manner explained 
 the effects of poisons by hypotheses concerning the form 
 of their particles , as we have already seen in speaking 
 of chemistry. 
 
 It is not necessary for us to dwell longer on this 
 subject, or to point out the total insufficiency of the mere 
 mechanical physiology. The iatrochemists had neglected 
 
 * Spr., iv. 329. t J6., 432. J /6., 223. 
 
 Mechanical Account of Poisons. 1702. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 561 
 
 the effect of the solids of the living frame ; the iatro- 
 mathematicians attended only to these*. And even 
 these were considered only as canals, as cords, as levers, 
 as lifeless machines. These reasoners never looked for 
 any powers of a higher order than the cohesion, the 
 resistance, the gravity, the attraction, which operate in 
 inert matter. If the chemical school assimilated the 
 physician to a vintner or brewer, the mechanical physio- 
 logists made him an hydraulic engineer; and, in fact, 
 several of the iatromathematicians were at the same 
 time teachers of engineering and of medicine. 
 
 Several of the reasoners of this school combined che- 
 mical with their mechanical principles; but it would 
 throw no additional light upon the subject to give any 
 account of these, and I shall therefore go on to speak of 
 the next form of the attempt to explain the processes of 
 life. 
 
 SECT. IV. The Vital-Fluid School. 
 
 I speak here, not of that opinion which assumes 
 some kind of fluid or ether as the means of communica- 
 tion along the nerves in particular, but of the hypothesis 
 that all the peculiar functions of life depend upon some 
 subtile ethereal substance diffused through the frame ; 
 not of a Nervous Fluid, but of a Vital Fluid. Again, I 
 distinguish this opinion from the doctrine of an imma- 
 terial vital power or principle, an Animal Soul, which 
 will be the subject of the next Section : nor is this dis- 
 tinction insignificant; for a material element, however 
 subtile, however much spiritualized, must still act every- 
 where according to the same laws ; whereas we do not 
 conceive an immaterial spirit or soul to be subject to 
 this necessity. 
 
 The iatromathematical school could explain to their 
 * Spr., iv. 419. 
 
 VOL. i. w. P. O o 
 
562 PHILOSOPHY OF BIOLOGY. 
 
 own satisfaction how motions, once begun, were trans- 
 ferred and modified ; but in many organs of the living 
 frame there seemed to be a power of beginning motion, 
 which is beyond all mere mechanical action. This led 
 to the assumption of a Principle of a higher kind, though 
 still material. Such a Principle was asserted by Frede- 
 rick Hoffmann, who was born at Halle, in 1660"*, and 
 became Professor of Medicine at the newly-established 
 University there in 1694. According to himf, the rea- 
 son of the greater activity of organized bodies lies in 
 the influence of a material substance of extreme sub- 
 tilty, volatility, and energy. This is, he holds, no other 
 than the Ether, which, diffused through all nature, 
 produces in plants the bud, the secretion and motion of 
 the juices, and is separated from the blood and lodged 
 in the brain of animals J. From this, acting through 
 the nerves, must be derived all the actions of the organs 
 in the animal frame ; for when the influence of the nerve 
 upon the muscle ceases, muscular motion ceases also. 
 
 The mode of operation of this vital fluid was, how- 
 ever, by no means steadily apprehended by Hoffmann 
 and his followers. Its operations are so far mecha- 
 nical that all effects are reduced to motion, yet they 
 cannot be explained according to known mechanical 
 laws. At one time the effects are said to take place 
 according to laws of a Higher Mechanics which are still 
 to be discovered || . At another time, in complete con- 
 tradiction of the general spirit of the system, meta- 
 physical conceptions are introduced: each particle of 
 the vital fluid is said to have a determined idea of the 
 whole mechanism and organism IF, and according to this, 
 
 * Spr., v. 254. t Ib., v. 257. 
 
 J De Differentia Organismi et Mechanismi, pp. 48, 67. 
 Spr., v. 262, 3. || Hoffmann, Opp., Vol. v. p. 123. 
 
 f De Diff. Organ, et Mechan., p. 81. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 
 
 it forms the body and preserves it by its motion. By 
 means of this fluid the soul operates upon the body, and 
 the instincts and the passions have their source in this 
 material sensitive soul. Thfs attribution of ideas to the 
 particles of the fluid is less unaccountable when we 
 recollect that something of the same kind is admitted 
 into Leibnitz's system, whose Monads have also ideas. 
 
 Notwithstanding its inconsistencies, Hoffmann's sys- 
 tem was received with very general favour both in 
 Germany and in the rest of Europe ; the more so, inas- 
 much as it fell in very well with the philosophy both of 
 Leibnitz and of Newton. The Newtonians were generally 
 inclined to identify the Vital Fluid with the Ether, of 
 which their master was so strongly disposed to assume 
 the existence : and indeed he himself suggested this 
 identification. 
 
 When the discoveries made respecting Electricity in 
 the course of the eighteenth century had familiarized 
 men with the notion of a pervading subtile agent, invi- 
 sible, intangible, yet producing very powerful effects in 
 every part of nature, physiologists also caught at the 
 suggestion of such an agent, and tried, by borrowing or 
 imitating it, to aid the imperfection of their notions of 
 the vital powers. The Vital Principle* was imagined to 
 be a substance of the same kind, by some to be the same 
 substance, with the Electric Fluid. By its agency all 
 these processes in organized bodies were accounted for 
 which cannot be explained by mechanical or chemical 
 laws, as the secretion of various matters (tears, milk, 
 bile, &c.) from an homogeneous fluid, the blood; the 
 production of animal heat, digestion, and the like. 
 According to John Hunter, this attenuated substance 
 pervaded the blood itself, as well as the solid organic 
 frame ; and .the changes which take place in the blood 
 
 * Pricbard, On the Doctrine of a Vital Principle, p. 12. 
 
 OO2 
 
564 PHILOSOPHY OF BIOLOGY. 
 
 which has flowed out of the veins into a basin are ex- 
 plained by saying that it is, for a time, till this vital fluid 
 evaporates, truly alive. 
 
 The notion of a Vital Fluid appears also to be favour- 
 ably looked upon by Cuvier; although with him this 
 doctrine is mainly put forwards in the form of a Nervous 
 Fluid. Yet in the following passage he extends the 
 operation of such an agent to all the vital functions*. 
 " We have only to suppose that all the medullary and 
 nervous parts produce the Nervous Agent, and that they 
 alone conduct it ; that is, that it can only be transmitted 
 by them, and that it is changed or consumed by their 
 actions. Then everything appears simple. A detached 
 portion of muscle preserves for some time its irritability, 
 on account of the portion of nerve which always adheres 
 to it. The sensibility and the irritability reciprocally 
 exhaust each other by their exercise, because they change 
 or consume the same agent. All the interior motions of 
 digestion, secretion, excretion, participate in this ex- 
 haustion, or may produce it. All local excitation of the 
 nerves brings thither more blood by augmenting the 
 irritability of the arteries, and the afflux of blood aug- 
 ments the real sensibility by augmenting the production 
 of the nervous agent. Hence the pleasures of titilla- 
 tions, the pains of inflammation. The particular sensa- 
 tions increase in the same manner and by the same 
 causes; and the imagination exercises, (still by means 
 of the nerves,) upon the internal fibres of the arteries 
 or other parts, and through them on the sensations, 
 an action analogous to that of the will upon the volun- 
 tary motions. As each exterior sense is exclusively 
 disposed to admit the substances which it is to perceive, 
 so each interior organ, secretory or other, is also more 
 excitable by some one agent than by another: and 
 * Hist. Sci. Nat. depuis 1789, i. 214. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 565 
 
 hence arises what has been called the proper sensi- 
 bility or proper life of the organs ; and the influence of 
 specifics which, introduced into the general circulation, 
 affect only certain parts. In fine, if the nervous agent 
 cannot become sensible to us, the reason is that all 
 sensation requires that this agent should be altered in 
 some way or other ; and it cannot alter itself. 
 
 " Such is the summary idea which we may at present 
 form of the mutual and general working of the vital 
 powers in animals." 
 
 Against the doctrine of a Vital Fluid as one uniform 
 material agent pervading the organic frame, an argument 
 has been stated which points out extremely well the 
 philosophical objection to such an hypothesis*. If the 
 Vital Principle be the same in all parts of the body, how 
 does it happen, it is asked, that the secretions are so 
 different? How do the particles in the blood, separated 
 from their old compounds and united into new ones, 
 under the same influence, give origin to all the different 
 fluids which are produced by the glands? The liver 
 secretes bile, the lacrymal gland, tears, and so on. Is the 
 Vital Principle different in all these organs? To assert 
 this, is to multiply nominal principles without limit, and 
 without any advance in the explanation of facts. Is the 
 Vital Principle the same, but its operation modified by 
 the structure of the organ ? We have then two unknown 
 causes, the Vital Principle and the Organic Structure, 
 to account for the effect. By such a multiplication of 
 hypotheses nothing is gained. We may as well say at 
 once, that the structure of the organ, acting by laws yet 
 unknown, is the cause of the peculiar secretion. It is 
 as easy to imagine this structure acting to produce the 
 whole effect, as it is to imagine it modifying the activity 
 of another agent. Thus the hypothesis of the Vital Fluid 
 
 * Prichard, On a Vital Principle, p. 98. 
 
566 PHILOSOPHY OF BIOLOGY. 
 
 in this form explains nothing, and does not in any way 
 help onwards the progress of real biological knowledge. 
 The hypothesis of an immaterial vital principle must 
 now be considered. 
 
 SECT. V. The Psychical School. 
 
 The doctrine of an Animal Soul as the principle 
 which makes the operations of organic different from 
 those of inorganic matter, is quite distinct from, and we 
 may say independent of, the doctrine of the soul as the 
 intelligent, moral, responsible part of man's nature. It 
 is the former doctrine alone of which we have here to 
 speak, and those who thus hold the existence of an 
 immaterial agent as the cause of the phenomena of life, 
 I term the Psychical School. 
 
 Such a view of the constitution of living things is 
 very ancient. For instance, Aristotle's Treatise "on the 
 Soul" goes entirely upon the supposition that the Soul 
 is the cause of motion, and he arrives at the conclusion 
 that there are different parts in the Soul ; the nutritive 
 or vegetative, the sensitive, and the rational*. 
 
 But this doctrine is more instructive to us, when it 
 appears as the antagonist of other opinions concerning 
 the nature of life. In this form it comes before us as 
 promulgated by Stahl, whom we have already noticed as 
 one of the great discoverers in chemistry. Born in the 
 same year as Hoffmann, and appointed at his suggestion 
 professor at the same time in the same new university of 
 Halle, he soon published a rival physiological theory. In 
 a Letter to Lucas Schrock, the president of the Academy 
 of Naturalists, he describes the manner in which he was 
 led to form a system for himselff. Educated in the 
 tenets of Sylvius and Willis, according to which all dis- 
 eases are derived from the acidity of the fluids, Stahl, 
 
 * Arist. Ue ft \ Vvxfc, n. 2. t Spr., v. 303. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 567 
 
 when a young student, often wondered how these fluids, 
 so liable to be polluted and corrupted, are so wonder- 
 fully preserved through innumerable external influences, 
 and seem to be far less affected by these than by age, 
 constitution, passion. No material cause could, he 
 thought, produce such effects. No attention to mechan- 
 ism or chemistry alone could teach us the true nature 
 and laws of organization. 
 
 So far as Stahl recognized the influence, in living 
 bodies, of something beyond the range of mechanics and 
 chemistry, there can be no doubt of the sound philosophy 
 of his views ; but when he proceeds to found a positive 
 system of physiology, his tenets become more precarious. 
 The basis of his theory is this '* : the body has, as body, 
 no power to move itself, and must always be put in 
 motion by immaterial substances. All motion is a spi- 
 ritual actf. The source of all activity in the organic 
 body, from which its preservation, the permanency of its 
 composition, and all its other functions proceed, is an 
 immaterial being, which Stahl calls the Soul; because, 
 as he says, when the effects are so similar, he will not 
 multiply powers without necessity. Of this principle, he 
 says, as the. Hippocratians said of Nature, that " it does 
 without teaching what it ought to doj," and does it 
 " without consideration $." These ancient tenets Stahl 
 interprets in such a manner that even the involuntary 
 motions proceed from the soul, though without reflection 
 or clear consciousness. It is indeed evident, that there 
 are many customary motions and sensations which are 
 perfectly rational, yet not the objects of distinct conscious- 
 ness : and thus instinctive motions, and those of which 
 we are quite unconscious, may still be connected with 
 reason. The questions which in this view offer them- 
 
 * Spr., v. 308. t Ib., v. 314. 
 
568 PHILOSOPHY OF BIOLOGY. 
 
 selves, as, how the soul passes from the mother to the 
 child, he dismisses as unprofitable""". He considers nu- 
 trition and secretion as the work of the soul. The cor- 
 puscular theory and the doctrine of animal spirits are, 
 he rightly observes, mere hypotheses, which are arbitrary 
 in their character, and only shift the difficulty. For, if 
 the animal spirits are not matter, how can they explain 
 the action of an immaterial substance on the body ; and 
 if they are matter, how are they themselves acted on ? 
 
 This doctrine of the action of the soul on the body, 
 was accepted by many persons, especially by the iatro- 
 mathematicians, who could not but feel the insufficiency 
 of their system without some such supplement : such 
 were Cheyne and Mead. In Germany, StahTs disciples 
 in physiology were for the most part inconsiderable per- 
 sons f. Several Englishmen who speculated concerning 
 the metaphysics as well as the physiology of Sensation 
 and Motion, inclined to this psychical view, as Porterfield 
 and Whytt. Among the French, Boissier de Sauvages 
 was the most zealous defender of the Stahlian system. 
 Actions, he saysj, which belong to the preservation of 
 life are determined by a moral not a mechanical neces- 
 sity. They proceed from the soul, but cannot be con- 
 trolled by it, as the starting from fear, or the trembling 
 at danger. Unzer, a physician at Altonaf, was also a 
 philosophical Stahlian ||. 
 
 We need not dwell on the opposition which was 
 offered to this theory, first by Hoffmann, and afterwards 
 by Haller. The former of these had promulgated, as we 
 have seen, the rival theory of a Nervous Fluid, the latter 
 
 * This was of course an obvious problem. Harvey, On Genera- 
 tion^ Exercise 27, p. 148, teaches, " That the egg is not the production 
 of the womb, but of the soul." 
 
 t Spr., v. 339, &c. J /*., 358. 
 
 A. D. 1799. || Spr., v. 360. 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 569 
 
 was the principal assertor of the doctrine of Irritability, 
 an important theory on which we may afterwards have to 
 touch. Haller's animosity against the Stahlian hypo- 
 thesis is a remarkable feature in one who is in general so 
 tolerant in his judgment of opinions. His arguments are 
 taken from the absence of the control of the will over 
 the vital actions, from the want of consciousness accom- 
 panying these actions, from the uniformity of them in dif- 
 ferent conditions of the mind, and from the small sensi- 
 bility of the heart which is the source of the vital actions. 
 These objections, and the too decided distinction which 
 Haller made between voluntary and involuntary muscles, 
 were very satisfactorily answered by Whytt and Platner. 
 In particular, it was urged that the instinctive actions of 
 brutes are inexplicable by means of mechanism, and may 
 be compared with the necessary vital actions of the 
 human body. Neither kind are accidental, neither kind 
 are voluntary, both are performed without reflection. 
 
 Without tracing further the progress of the Psychical 
 Doctrine, I shall borrow a few reflections upon it from 
 Sprengel * : 
 
 " When the opponents of the Stahlian system repeat 
 incessantly that the assumption of a psychical cause in 
 corporeal effects is a metaphysical speculation which does 
 not belong to medicine, they talk to no purpose. The 
 states of the soul are objects of our internal experience, 
 and interest the physician too nearly to allow him to. 
 neglect them. The innumerable unconscious efforts of 
 the soul, the powerful and daily effects of the passions 
 upon the body, too often put to confusion those who 
 would expel into the region of metaphysics the disposi- 
 tions of the mind. The connexion of our knowledge of 
 the soul, as gathered from experience, with our know- 
 
 * Spr., v. 383. 
 
570 PHILOSOPHY OF BIOLOGY. 
 
 ledge of the human body, is far closer than the mecha- 
 nical and chemical physiologists suspect. 
 
 "The strongest objection against the psychical sys- 
 tem, and one which has never been sufficiently answered 
 by any of its advocates, is the universality of organic 
 effects in the vegetable kingdom. The comparison of 
 the physiology of plants with the physiology of animals 
 puts the latter in its true light. Without absolutely 
 trifling with the word soul, we cannot possibly derive 
 from a soul the organic operations of vegetables. But 
 just as little can we, as some Stahlians have done, draw 
 a sharp line between plants and animals, and ascribe the 
 processes of the former to mere mechanism, while we 
 derive the operations of the latter from an intellectual 
 principle. Not to mention that such a line is not pos- 
 sible, the rise of the sap and the alteration of the fluids 
 of plants cannot be derived entirely from material causes 
 as their highest origin." 
 
 Thus, I may add, this psychical theory, however diffi- 
 cult to defend in its detail, does in its generalities express 
 some important truths respecting the vital powers. It 
 not only, like the last theory, gives unity to the living 
 body, but it marks, more clearly than any other theory, 
 the wide interval which separates mechanical and che- 
 mical from vital action, and fixes our attention upon the 
 new powers which the consideration of life compels us to 
 assume. It not only reminds us that these powers are 
 elevated above the known laws of the material world, but 
 also that they are closely connected with the world of 
 thought and feeling, of will and reason; and thus it 
 carries us, in a manner in which none of the preceding 
 theories have done, to a true conception of a living, 
 conscious, sentient, active individual. 
 
 At the same time we cannot but allow that the life 
 
SUCCESSIVE BIOLOGICAL HYPOTHESES. 571 
 
 of plants and of the lower orders of animals shows us 
 very clearly that, in order to arrive at any sound and 
 consistent knowledge respecting life, we must form some 
 conception of it from which all the higher attributes 
 which the term " soul " involves, are utterly and care- 
 fully excluded ; and therefore we cannot but come to the 
 conclusion that the psychical school are right mainly in 
 this; that in ascribing the functions of life to a soul, 
 they mark strongly and justly the impossibility of ascrib- 
 ing them to any known attributes of body. 
 
 CHAPTER III. 
 ATTEMPTS TO ANALYZE THE IDEA OF LIFE. 
 
 1 . Definitions of Life. WE have seen in the pre- 
 ceding chapter that all attempts to obtain a distinct 
 conception of the nature of Life in general have ended 
 in failure, and produced nothing beyond a negative 
 result. And the conjecture may now naturally occur, 
 that the cause of this failure resides in an erroneous 
 mode of propounding to ourselves the problem. Instead 
 of contemplating Life as a single Idea, it may perhaps 
 be proper to separate it into several component notions : 
 instead of seeking for one cause of all vital operations, it 
 may be well to look at the separate vital functions, and 
 to seek their causes. When the view of this possibility 
 opens upon us, how shall we endeavour to verify it, and 
 to take advantage of it ? 
 
 Let us, as one obvious course, take some of the 
 attempts which have been made to define Life, and let 
 us see whether they appear to oifer to us any analysis 
 of the idea into component parts. Such definitions, 
 when they proceed from men of philosophical minds 
 
572 PHILOSOPHY OF BIOLOGY. 
 
 are the ultimate result of a long course of thought and 
 observation ; and by no means deserve to be slighted as 
 arbitrary selections of conditions, or empty forms of words. 
 
 2. Life has been defined by Stahl*, "The con- 
 dition by which a body resists a natural tendency to che- 
 mical changes, such as putrefaction." In like manner, 
 M. von Humboldtf defines living bodies to be "those 
 which, notwithstanding the constant operation of causes 
 tending to change their form, are hindered by a certain 
 inward power from undergoing such change." The first 
 of these definitions amounts only to the assertion, that 
 vital processes are not chemical ; a negative result, which 
 we may accept as true, but which is, as we have seen, a 
 barren truth. The second appears to be, in its import, 
 identical with the first. An inward principle can only 
 be understood as distinguished from known external 
 powers, such as mechanical and chemical agencies. Or 
 if, by an internal principle, we mean such a principle as 
 that of which we are conscious within ourselves, we 
 ascribe a soul to all living things : an hypothesis which 
 we have seen is not more effective than the former in 
 promoting the progress of biological science. Nearly 
 the same criticism applies to such definitions as that 
 of Kant: that "Life is an internal faculty producing 
 change, motion, and action." 
 
 Other definitions refer us, not to some property 
 residing in the whole of an organized mass, but to the 
 connexion and relation of its parts. Thus M. von Hum- 
 boldtj has given another definition of a living body: 
 that " it is a whole whose parts, arbitrarily separated, no 
 longer resist chemical changes." But this additional 
 assertion concerning the parts, adds nothing of any 
 
 * Treviranus, Biologic, p. 19. Stahlii, Theor. Med., p. 254. 
 t Aphorismen aus d. Chem. Physiol. der Pflanzen, s. 1 . 
 % Versuchc uber die gereitzte Muskcl und Nervenfaser, Book n., 
 p. 433. 
 
ATTEMPTS TO ANALYZE THE IDEA OF LIFE. 573 
 
 value to the definition of the whole. And in some of 
 the lower kinds of plants and animals it is hardly true 
 as a fact. 
 
 3. Another definition * places the character of Life in 
 "motions serviceable to the body moved." To this it 
 has been objected f, that, on this definition, the earth and 
 the planets are living bodies. Perhaps it would be more 
 philosophical to object to the introduction of so loose a 
 notion as that of a property being serviceable to a body. 
 We might also add, that if we speak of all vital func- 
 tions as motions, we make an assumption quite unautho- 
 rized, and probably false. 
 
 Other definitions refer the idea of Life to the idea of 
 Organization. " Life is the activity of matter according 
 to laws of organization J." We are then naturally led to 
 ask what is Organization. In reply to this is given us 
 the Kantian definition of Organization, which I have 
 already quoted elsewhere , "An organized product of 
 nature is that in which all the parts are mutually ends 
 and means ||." That this definition involves exact fun- 
 damental ideas, and is capable of being made the basis of 
 sound knowledge, I shall hereafter endeavour to show. 
 But I may observe that such a definition leads us some- 
 what further. If the parts of organized bodies are known 
 to be means to certain ends, this must be known because 
 they fulfil these ends, and produce certain effects by the 
 operation of a certain cause or causes. The question then 
 recurs, what is the cause which produces such effects as 
 take place in organized or living bodies? and this is iden- 
 tical with the problem of which in the last chapter we 
 
 * Erhard, Roschlaub's Magazin der Heilkunde, B. i., st. 1, p 69. 
 
 t Treviranus, Biologie,p. 41. 
 
 ^ Schmid, Physiologic, B. u., p. 274. 
 
 Hist. Ind. Sc., B. xvn. c. viii. sect. 2. 
 
 || Kant, Urtheilskraft, p. 296. 
 
574 PHILOSOPHY OF BIOLOGY. 
 
 traced the history, and related the failure of physiologists 
 in all attempts at its solution. 
 
 4. But what has been just said suggests to us 
 that it may be an improvement to put our problem in 
 another shape : not to take for granted that the cause 
 of all vital processes is one, but to suppose that there 
 may be several separate causes at work in a living body. 
 If this be so, life is no longer one kind of activity, but 
 several. We have a number of operations which are 
 somehow bound together, and life is the totality of all 
 these : in short, life is not one Function, but a System of 
 Functions. 
 
 5. We are thus brought very near to the celebrated 
 definition of life given by Bichat * : " Life is the sum of 
 the functions by which death is resisted." But upon the 
 definition thus stated, we may venture to observe ; first, 
 that the introduction of the notion of death in order to 
 define the notion of life appears to be unphilosophical. 
 We may more naturally define death with reference to 
 life, as the cessation of life ; or at least we may consider 
 life and death as correlative and interdependent notions. 
 Again, the word " sum," used in the way in which it here 
 occurs, appears to be likely to convey an erroneous con- 
 ception, as if the functions here spoken of were simply 
 added to each other, and connected by co-existence. It 
 is plain that our idea of life involves more than this : the 
 functions are all clearly connected, and mutually depend 
 on each other ; nutrition, circulation, locomotion, repro- 
 duction, each has its influence upon all the others. 
 These functions not merely co-exist, but exist with many 
 mutual relations and connexions ; they are continued so 
 as to form, not merely a sum, but a system. And thus 
 we are led to modify Bichat's definition, and to say that 
 Life is the system of vital functions. 
 
 * Physiological Researches on Life and Death. 
 
ATTEMPTS TO ANALYZE THE IDEA OF LIFE. 575 
 
 6. But it will be objected that by such a definition 
 we explain nothing : the notion of vital functions, it may 
 be said, involves the idea of life, and thus brings us 
 round again to our starting point. Or if not, at least 
 it is as necessary to define Vital Functions as to define 
 Life itself, so that we have made little progress in our 
 task. 
 
 To this we reply, that if any one seeks, upon such 
 subjects, some ultimate and independent definition from 
 which he can, by mere reasoning, deduce a series of con- 
 clusions, he seeks that which cannot be found. In the 
 Inductive Sciences, a Definition does not form the basis 
 of reasoning, but points out the course of investigation. 
 The definition must include words ; and the meaning of 
 these words must be sought in the progress and results 
 of observations, as I have elsewhere said*. "The mean- 
 ing of words is to be sought in the progress of thought ; 
 the history of science is our dictionary; the steps of 
 scientific induction are our definitions." It will appear, 
 I think, that it is more easy for us to form an idea of a 
 separate Function of the animal frame, as Nutrition or 
 Reproduction, than to comprehend Life in general under 
 any single idea. And when we say that Life is a system 
 of Vital Functions, we are of course directed to study 
 these functions separately, and (as in all other subjects 
 of scientific research) to endeavour to form of them such 
 clear and definite ideas as may enable us to discover 
 their laws. 
 
 7. The view to which we are thus led, of the most 
 promising mode of conducting the researches of Biology, 
 is one which the greatest and most philosophical physi- 
 ologists of modern times have adopted. Thus Cuvier 
 considers this as the true office of physiology at present. 
 " It belongs to modern times," he says, " to form a just 
 
 * Hist. hid. Set., B. xin. c. ix. 
 
576 PHILOSOPHY OF BIOLOGY. 
 
 classification of the vital phenomena; the task of the 
 present time is to analyze the forces which belong to 
 each organic element, and upon the zeal and activity 
 which are given to this task, depends, according to my 
 judgment, the fortune of physiology*." This classifica- 
 tion of the phenomena of life involves, of course, a dis- 
 tinction and arrangement of the vital functions ; and the 
 investigation of the powers by which these functions are 
 carried on, is a natural sequel to such a classification. 
 
 8. Classifications of Functions. Attempts to classify 
 the Vital Functions of man were made at an early period, 
 and have been repeated in great number up to modern 
 times. The task of classification is exposed to the same 
 difficulties, and governed by the same conditions, in this 
 as in other subjects. Here, as in the case of other things, 
 there may be many classifications which are moderately 
 good and natural, but there is only one which is the best 
 and the true natural system. Here, as in other cases, 
 one classification brings into view one set of relations ; 
 another, another ; and each may be valuable for its spe- 
 cial purpose. Here, as in other cases, the classes may be 
 well constituted, though the boundary lines which divide 
 them be somewhat indistinct, and the order doubtful. 
 Here, as in other cases, we may have approached to the 
 natural classification without having attained it ; and 
 here, as in other cases, to define our classes is the last 
 and hardest of our problems. 
 
 The most ancient classification of the Functions of 
 living things f, is the division of them into Vital, Natural, 
 and Animal. The Vital Functions are those which can- 
 not be interrupted without loss of life, as Circulation, 
 Respiration, and Nervous Communication. The Natural 
 Functions are those which without the intervention of 
 
 * Hist. Sc. Nat. dep. 1789, i. 218. 
 
 t Diet, des Sciences Nat., art. Fonctiom. 
 
ATTEMPTS TO ANALYZE THE IDEA OF LIFE. 577 
 
 the will operate on their proper occasions to preserve 
 the bodies of animals ; they are Digestion, Absorption, 
 Nutrition; to which was added Generation. The Animal 
 Functions are those which involve perception and will, 
 by which the animal is distinguished from the vegetable ; 
 they are Sensibility, Locomotion, and Voice. 
 
 The two great grounds of this division, the distinction 
 of functions which operate continually, and those which 
 operate occasionally ; and again, the distinction of func- 
 tions which involve sensation and voluntary motion from 
 those which do not, are turly of fundamental import- 
 ance, and gave a real value to this classification. It 
 was, however, liable to obvious objections: namely, First, 
 that the names of the classes were ill chosen ; for all the 
 functions are natural, all are vital : Second, that the lines 
 of demarcation between the classes are indefinite and 
 ambiguous ; Respiration is a vital function, as being 
 continually necessary to life ; but it is also a natural 
 function, since it concurs in the formation of the nutri- 
 tive fluid, and an animal function, since it depends in 
 part on the will. But these objections were not fatal, 
 for a classification may be really sound and philosophi- 
 cal, though its boundary lines are vague, and its nomen- 
 clature ill selected. The division of the functions we 
 have mentioned kept its ground long ; or was employed 
 with a subdivision of one class, so as to make them four; 
 the vital, natural, animal and sexual functions. 
 
 10. I pass over many intermediate attempts to clas- 
 sify the functions, and proceed to that of Bichat as that 
 which is, I believe, the one most generally assented to in 
 modern times. The leading principle in the scheme of 
 this celebrated physiologist is the distinction between 
 organic and animal life. This separation is nearly iden- 
 tical with the one just noticed between the vital and 
 animal functions ; but Bichat, by the contrasts which he 
 VOL. i. w. P. P p 
 
578 PHILOSOPHY OF BIOLOGY. 
 
 pointed out between these classes of functions, gave a 
 decided prominence and permanence to the distinction. 
 The Organic Life, which in animals is analogous to the 
 life of vegetables, and the Animal Life, which implies 
 sensation and voluntary motion, have each its system of 
 organs. The center of the animal life is the brain, of the 
 organic life, the heart. The former is carried on by a 
 symmetrical, the latter, by an unsymmetrical system of 
 organs : the former produces intermitting, the latter con- 
 tinuous actions : and, in addition to these, other differ- 
 ences are pointed out. This distinction of the two lives, 
 being uIUS e5t^lishfifj. ea-ch i subdivided into two orders 
 of Functions. The Animal Functions are passive, as 
 Sensation: or active, as Locomotion and Voice ; ^ again, 
 the Organic Functions are those of composition, which are 
 concerned in taking matter into the system ; Digestion, 
 Absorption, Respiration, Circulation, Assimilation ; and 
 those of decomposition, which reject the materials when 
 they have discharged their office in the system ; and these 
 are again, Absorption, Circulation, and Secretion. To 
 these are added Calorification, or the production of 
 animal heat. It appears, from what has been said, 
 that Absorption and Circulation, (and we may add Assi- 
 milation and Secretion, which are difficult to separate,) 
 belong alike to the processes of composition and decom- 
 position ; nor in truth, can we, with any rigour, separate 
 the centripetal and centrifugal movements in that vor- 
 tex which, as we shall see, is an apt image of organic 
 life. 
 
 Several objections have been made to this classifica- 
 tion ; and in particular, to the terms thus employed. It 
 has been asserted to be a perversion of language to 
 ascribe to animals two lives, and to call the higher facul- 
 ties in man, perception and volition, the animal func- 
 tions. But, as we have already said, when a classification 
 
ATTEMPTS TO ANALYZE THE IDEA OF LIFE. 579 
 
 is really good, such objections, which bear only upon the 
 mode in which it is presented, are by no means fatal : 
 and it is generally acknowledged, by all the most philo- 
 sophical cultivators of biology, that this arrangement of 
 the functions is better suited to the purposes of the 
 science than those which preceded it. 
 
 11. But according to the principles which we have 
 already laid down, the solidity of such a classification is 
 to be verified by its serving as a useful guide in biologi- 
 cal researches. If the arrangement which we have ex- 
 plained be really founded in natural relations, it will be 
 found that in proportion as physiologists have studied 
 the separate functions above enumerated, their ideas of 
 these functions, and of the powers by which they are 
 carried on, have become more and more clear ; have 
 tended more and more to the character of exact and 
 rigorous science. 
 
 To examine how far this has been the case with 
 regard to all the separate functions, would be to attempt 
 to estimate the value of all the principal physiological 
 speculations of modern times ; a task far too vast and 
 too arduous for any one to undertake who has not 
 devoted his life to such studies. But it may properly 
 come within the compass of our present plan to shew 
 how, with regard to the broader lines of the above clas- 
 sification, there has been such a progress as we have 
 above described, from more loose and inaccurate notions 
 of some of the vital functions to more definite and pre- 
 cise ideas. This I shall attempt to point out in one or 
 two instances. 
 
 PP 2 
 
580 
 
 CHAPTER IV. 
 
 ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL 
 
 FORCES, AND FIRST OF ASSIMILATION 
 
 AND SECRETION. 
 
 SECT. I. Course of Biological Research. 
 1. IT is to be observed that at present I do not speak 
 of the progress of our knowledge with regard to the 
 detail of the processes which take place in the human 
 body, but of the approach made to some distinct Idea of 
 the specially vital part of each process. In the History 
 of Physiology, it has been seen* that all the great dis- 
 coveries made respecting the organs and motions of the 
 animal frame have been followed by speculations and 
 hypotheses connected with such discoveries. The dis- 
 covery of the circulation of the blood led to theories of 
 animal heat ; the discovery of the motion of the chyle 
 led to theories of digestion; the close examination of 
 the process of reproduction in plants and animals led to 
 theories of generation. In all these cases, the discovery 
 brought to light some portion of the process which was 
 mechanical or chemical, but it also, in each instance, 
 served to show that the process was something more 
 than mechanical or chemical. The theory attempted to 
 explain the process by the application of known causes ; 
 but there always remained some part of it which must 
 unavoidably be referred to an unknown cause. But 
 though unknown, such a cause was not a hopeless object 
 of study. As the vital functions became better and 
 better understood, it was seen more and more clearly at 
 what precise points of the process it was necessary to 
 assume a peculiar vital energy, and what sort of pro- 
 * Hist. Ind. Sci., B. xvn. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 581 
 
 perties this energy must be conceived to possess. It 
 was perceived where, in what manner, in what degree, 
 mechanical and chemical agencies were modified, over- 
 ruled, or counteracted, by agencies which must be 
 hyper-mechanical and hyper-chemical. And thus the 
 discoveries made in anatomy by a laborious examination 
 of facts, pointed out the necessity of introducing new 
 ideas, in order that the facts might be intelligible. 
 Observation taught much ; and among other things, she 
 taught that there was something which could not be 
 observed, but which must, if possible, be conceived. I 
 shall notice a few instances of this. 
 
 SECT. II. Attempts to form a distinct Conception of 
 Assimilation and Secretion. 
 
 2. The Ancients. That plants and animals grow by 
 taking into their substance matter previously extraneous, 
 is obvious to all ; but as soon as we attempt to conceive 
 this process distinctly in detail, we find that it involves 
 no inconsiderable mystery. How does the same food 
 become blood and flesh, bone and hair? Perhaps the 
 earliest attempt to explain this mystery, is that recorded 
 by Lucretius* as the opinion of Anaxagoras, that food 
 contains some bony, some fleshy particles, some of blood, 
 and so on. We might, on this supposition, conceive 
 that the mechanism of the body appropriates each kind 
 of particle to its suitable place. 
 
 But it is easy to refute this essay at philosophizing 
 (as Lucretius refutes it) by remarking that we do not 
 find milk in grass, or blood in fruit, though such food 
 gives such products in cattle and in men. In opposition 
 to this " Homoiomereia," the opinion that is forced upon 
 us by the facts is, that the process of nutrition is not a 
 selection merely, but an assimilation ; the organized 
 
 * Lucr., i. 855. Nunc et Anaxa^one ecrutemur 
 
582 PHILOSOPHY OF BIOLOGY. 
 
 system does not find, but make, the additions to its 
 structure. 
 
 3. Buff on. This notion of assimilation may be vari- 
 ously expressed and illustrated ; and all that we can do 
 here, in order to show the progress of thought, is to 
 adduce the speculations of those writers who have been 
 most successful in seizing and marking its peculiar cha- 
 racter. Buffon may be taken as an example of the 
 philosophy of his time on this subject. " The body of 
 the animal," says he*, "is a kind of interior mould, in 
 which the matter subservient to its increase is modelled 
 and assimilated to the whole, in such a way that, with- 
 out occasioning any change in the order and proportion 
 of the parts, there results an augmentation in each part 
 taken separately. This increase, this developement, if 
 we would have a dear idea of it, how can we obtain it, 
 except by considering the body of the animal, and each 
 of the parts which is to be developed, as so many interior 
 moulds which only receive the accessory matter in the 
 order which results from the position of all their parts ? 
 This developement cannot take place, as persons some- 
 times persuade themselves, by an addition to the outside ; 
 on the contrary, it goes on by an intimate susception 
 which penetrates the mass ; for, in the part thus deve- 
 loped, the size increases in all parts proportionally, so 
 that the new matter must penetrate it in all its dimen- 
 sions : and it is quite necessary that this penetration of 
 substance must take place in a certain order, and accord- 
 ing to a certain measure ; for if this were not so, some 
 parts would develope themselves more than others. 
 Now what can there be which shall prescribe such a 
 rule to the accessory matter except the interior mould." 
 
 To speak of a mould simply, would convey a coarse 
 mechanical notion, which could not be received as any 
 
 * Hut. Nat., B. i. c. iii. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 583 
 
 useful contribution to physiological speculation. But 
 this interior mould is, of course, to be understood 
 figuratively, not as an assemblage of cavities, but as a 
 collection of laws, shaping, directing, and modifying the 
 new matter; giving it not only form, but motion and 
 activity, such as belong to the parts of an organic being. 
 
 4. It must be allowed, however, that even with this 
 explanation, the comparison is very loose and insuffi- 
 cient. A mould may be permitted to mean a collection 
 of laws, but still it can convey no conception except 
 that of laws regulated by relations of space ; and such a 
 conception is very plainly quite inadequate to the pur- 
 pose. What can we conceive of the interior mould by 
 which chyle is separated from the aliments at the pores 
 of the lacteals, or tears secreted in the lacrymatory 
 gland ? 
 
 An additional objection to this mode of expression of 
 Buffbn is, that it suggests to us only a single marked 
 change in the assimilated matter, not a continuous series 
 of changes. Yet the animal fluids and other substances 
 are, in fact, undergoing a constant series of changes. 
 Food becomes chyme, and chyme becomes chyle ; chyle 
 is poured into the blood ; from the blood secretions take 
 place, as the bile ; the bile is poured into the digestive 
 canal, and a portion of the matter previously introduced 
 is rejected out of the system. Here we must have a 
 series of "interior moulds;" and these must impress 
 matter at its ejection from the organic system as well as 
 at its reception. But, moreover, it is probable that none 
 of the above transformations are quite abrupt. Change 
 is going on between the beginning and the end of each 
 stage of the nutritive circulation. To express the laws 
 of this continuous change, the image of an interior 
 mould is quite unsuited. We must seek a better mode 
 of conception. 
 
584 PHILOSOPHY OF BIOLOGY. 
 
 5. Vegetable and animal nutrition is, as we have 
 said, a constant circulation. The matter so assumed is 
 not all retained : a perpetual subtraction accompanies a 
 perpetual addition. There is an excretion as well as an 
 intussusception. The matter which is assumed by the 
 living creature is retained only for a while, and is then 
 parted with. The individual is the same, but its parts 
 are in a perpetual flux : they come and go. For a time 
 the matter which belongs to the organic body is bound 
 to it by certain laws : but before it is thus bound, and 
 after it is loose, this matter may circulate about the uni- 
 verse in any other form. Life consists in a permanent 
 influence over a perpetually changing set of particles. 
 
 Cuvier. This condition also has been happily ex- 
 pressed, by means of a comparison, by another great 
 naturalist. "If," says Cuvier"", "if, in order to obtain a 
 just idea of the essence of life, we consider it in the 
 beings where its effects are most simple, we shall soon 
 perceive that it consists in the faculty which belongs to 
 certain bodily combinations to continue during a deter- 
 minate time under a determinate form ; constantly at- 
 tracting into their composition a part of the surround- 
 ing substances, and giving up in return some part of 
 their own substance. 
 
 "Life is thus a vortex, more or less rapid, more or 
 less complex, which has a constant direction, and which 
 always carries along its stream particles of the same 
 kinds ; but in which the individual particles are con- 
 stantly entering in and departing out ; so that the form 
 of the living body is more essential to it than its matter. 
 
 " So long as this motion subsists, the body in which 
 it takes place is alive ; it lives. When the motion stops 
 finally, the body dies. After death, the elements which 
 compose the body, given up to the ordinary chemical 
 
 * Regne Animal, i. 11. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 585 
 
 affinities, soon separate, and the body which was alive is 
 dissolved." 
 
 This notion of a vortex* which is permanent while 
 the matter which composes it constantly changes, of 
 peculiar forces which act in this vortex so long as it 
 exists, and which give place to chemical forces when the 
 circulatory motion ceases, appears to express some of 
 the leading conditions of the assimilative power of living- 
 things in a simple and general manner, and thus tends 
 to give distinctness to the notion of this vital function. 
 
 6. But we may observe that this notion of a vortex 
 is still insufficient. Particles are not only taken into the 
 system and circulated through it for a time, but, as we 
 have seen, they are altered in character in a manner to 
 us unintelligible, both at their first admission into the 
 system and at every period of their progress through it. 
 In the vortex each particle is constantly transformed 
 while it whirls. 
 
 It may be said, perhaps, that this transformation of 
 the kinds of matter may be conceived to be merely a 
 new arrangement of their particles, and that thus all the 
 changes which take place in the circulating substances 
 are merely so many additional windings in the course of 
 the whirling current. But to say this, is to take for 
 granted the atomic hypothesis in its rudest form. What 
 right have we to assume that blood and tears, bile and 
 milk, consist of like particles of matter differently ar- 
 ranged? What can arrangement, a mere relation of 
 
 * The definition of life given by M. de Blainville appears to me 
 not to differ essentially from that of Cuvier. " Un corps vivant est 
 une sorte de foyer chimique ou il-y-a a tous momens apport de nou- 
 velles molecules et depart de molecules anciennes ; ou la composition 
 n'est jamais fixe (si ce n'est d'un certain nombre de parties verita- 
 blement mortes ou en depot), mais totijours pour ainsi dire in nisu, 
 d'oii mouvement plus ou moins lent et quelquefois dialeur." Principcs 
 d'Anat. Comp., 1822, 1. 1. p. 16. 
 
586 PHILOSOPHY OF BIOLOGY. 
 
 space, do towards explaining such differences? Is not 
 the insufficiency, the absurdity of such an assumption 
 proved by the whole course of science ? Are not even 
 chemical changes, according to the best views hitherto 
 obtained, something more than a mere new arrangement 
 of particles? And are not vital as much beyond che- 
 mical, as chemical are beyond geometrical modifications? 
 It is not enough, then, to conceive life as a vortex. The 
 particles which are taken into the organic frame do 
 more than circulate there. They are, at every point of 
 their circulation, acted upon by laws of an unknown 
 kind, changing the nature of the substance which they 
 compose. Life is a vortex in which vital forces act at 
 every point of the stream : it is not only a current of 
 whirling matter, but a cycle of recurring powers. 
 
 7. Matter and Form. This image of a vortex is 
 closely connected with the representation of life offered 
 us by writers of a very different school. In Schell ing's 
 Lectures on Academic Study, he takes a survey of the 
 various branches of human knowledge, determining 
 according to his own principles the shape which each 
 science must necessarily assume. The peculiar charac- 
 ter of organization, according to him *, is that the matter 
 is only an accident of the thing itself, and the organiza- 
 tion consists in Form alone. But this Form, by its very 
 opposition to Matter, ceases to be independent of it, and 
 is only ideally separable. In organization, therefore, 
 substance and accident, matter and form, are completely 
 identical f. This notion, that in organization the form 
 is essential and the matter accidental, or, in other words, 
 that the form is permanent and the matter fluctuating 
 and transitory, agrees, if taken in the grossest sense of 
 
 * Lect. xiii. p. 288. 
 
 f I have not translated Schelling's words, but iven their import as 
 far as I could- 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 587 
 
 matter and form, with Cuvier's image of a vortex. In a 
 whirlpool, or in a waterfall, the form remains, the mat- 
 ter constantly passes away and is renewed. But we 
 have already seen* that in metaphysical speculations in 
 which matter and form are opposed, the word form is 
 used in a far more extensive sense than that which 
 denotes a relation of space. It may indeed designate 
 any change which matter can undergo ; and we may 
 very allowably say that food and blood are the same 
 matter under different forms. Hence if we assert that 
 Life is a constant Form of a circulating Matter, we 
 express Cuvier's notion in a mode free from the false 
 suggestion which "vortex" conveys. 
 
 8. We may, however, still add something to this 
 account of life. The circulating parts of the system not 
 only circulate, but they form the non-circulating parts. 
 Or rather, there are no non-circulating parts: all por- 
 tions of the frame circulate more or less rapidly. The 
 food which we take circulates rapidly in the fluids, more 
 slowly in the flesh, still more slowly in the bones ; but 
 in all these parts it is taken into the system, retained 
 there for some time, and finally replaced by other mat- 
 ter. But while it remains in the body, it exercises upon 
 the other circulating parts the powers by which their 
 motion is produced. Nutriment forms and supports the 
 organs, and the organs carry fresh nutriment to its des- 
 tination. The peculiar forces of the living body, and 
 its peculiar structure, are thus connected in an inde- 
 scribable manner. The forces produce the structure ; 
 the structure, again, is requisite for the exertion of the 
 forces. The Idea of an Organic or Living Being includes 
 this peculiar condition that its construction and powers 
 are such, that it* constantly appropriates to itself new 
 portions of substance which, so appropriated, become 
 
 * Book t. 
 
588 PHILOSOPHY OF BIOLOGY. 
 
 indistinguishable parts of the whole, and serve to carry 
 on subsequently the same functions by which they were 
 assimilated. And thus Organic Life is a constant Form 
 of a circulating Matter, in which the Matter and the 
 Form determine each other by peculiar laws (that is, by 
 Vital Forces). 
 
 SECT. HI. Attempts to conceive the forces of Assimi- 
 'lation and Secretion. 
 
 9. I have already stated that in our attempts to ob- 
 tain clear and scientific Ideas of Vital Forces, we have, 
 in the first place, to seek to understand the course of 
 change and motion in each function, so as to see at what 
 points of the process peculiar causes come into play; 
 and next, to endeavour to obtain some insight into the 
 peculiar character and attributes of these causes. Having 
 spoken of the first part of this mode of investigation in 
 regard to the general nutrition of organic bodies, I must 
 now say a few words on the second part. 
 
 The Forces here spoken of are Vital Forces. From 
 what has been said, we may see in some measure the dis- 
 tinction between forces of this kind and mechanical or 
 chemical forces ; the latter tend constantly to produce a 
 final condition, after which there is no further cause of 
 change : mechanical forces tend to produce equilibrium ; 
 chemical forces tend to produce composition or decompo- 
 sition ; and this point once reached, the matter in which 
 these forces reside is altogether inert. But an organic 
 body tends to a constant motion, and the highest activity 
 of organic forces shows itself in continuous change. 
 Again, in mechanical arid chemical forces, the force of 
 any aggregate is the sum of the forces of all the parts : 
 the sum of the forces corresponds to 4 the sum of the 
 matter. But in organic bodies, the amount of effect does 
 not depend on the matter, but on the form : the particles 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 589 
 
 lose their separate energy, in order to share in that of 
 the system ; they are not added, they are assimilated. 
 
 10. It is difficult to say whether anything has been 
 gained to science by the various attempts to assign a 
 fixed name to the vital force which is thus the immediate 
 cause of Assimilation. It has been called Organic At- 
 traction or Vital Attraction, Organic Affinity or Vital 
 Affinity, being thus compared with mechanical Attraction 
 or chemical Affinity. But, perhaps, as the process is 
 certainly neither mechanical nor chemical, it is desirable 
 to appropriate to it a peculiar name ; and the name Assi- 
 milation, or Organic Assimilation, by the usage of good 
 biological writers, is generally employed for this purpose, 
 and may be taken as the standard name of this Vital 
 Force. To illustrate this, I will quote a passage from 
 the excellent Elements of Physiology of Professor Miiller. 
 "In the process of nutrition is exemplified the funda- 
 mental principle of organic assimilation. Each elemen- 
 tary particle of an organ attracts similar particles from 
 the blood, and by the changes it produces in them, 
 causes them to participate in the vital principle of the 
 organ itself. Nerves take up nervous substance, muscles, 
 muscular substance : even morbid structures have the 
 assimilating power; warts in the skin grow with their 
 own peculiar structure ; in an ulcer, the base and border 
 are nourished in a way conformable to the mode of 
 action and secretion determined by the disease." 
 
 11. The Force of Organic Assimilation spoken of in 
 the last paragraph denotes peculiarly the force by which 
 each organ appropriates to itself a part of the nutriment 
 received into the system, and thus is maintained and aug- 
 mented with the growth of the whole. But the growth 
 of the solid parts is only one portion of the function of 
 nutrition ; besides this, we must consider the motion and 
 changes of the fluids, and must ask what kind of forces 
 
590 PHILOSOPHY OF BIOLOGY. 
 
 may be conceived to produce these. What are the 
 powers by which chyle is absorbed from the food, by 
 which bile is secreted from the blood, by which the cir- 
 culating motion of these and all other fluids of the body 
 are constantly maintained? To the questions, What 
 are the forces by which absorption, secretion, and the 
 vital motions, of fluids are produced? no satisfactory 
 answer has been returned. Yet still some steps have 
 been made, which it may be instructive to point out. 
 
 12. In Absorption it would appear that a part of the 
 agency is inorganic ; for not only dead membranes, but 
 inorganic substances, absorb fluids, and even absorb them 
 with elective forces, according to the ingredients of the 
 fluid. A force which is of this kind, and which has been 
 termed Endosmose, has been found to produce very curi- 
 ous effects. When a membrane separates two fluids, 
 holding in solution different ingredients, the fluids pass 
 through the membrane in an imperceptible manner, and 
 mix or exchange their elements. The force which pro- 
 duces these effects is capable of balancing a very consi- 
 derable pressure. It appears, moreover, to depend, at 
 least among other causes, upon attractions operating 
 between the elements of the solids and the fluids, as 
 well as between the different fluids; and this force, 
 though thus apparently of a mechanical and chemical 
 nature, probably has considerable influence in vital 
 phenomena. 
 
 13. But still, though Endosmose may account in part 
 for absorption in some cases, it is certain that there is 
 some other vital force at work in this process. There 
 must be, as Miiller says*, "an organic attraction of a 
 kind hitherto unknown." " If absorption," he addsf, "is 
 to be explained in a manner analogous to the laws of 
 endosmose, it must be supposed that a chemical affinity, 
 
 * Physiology, p. 299. t 76., p. 301. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 591 
 
 resulting from the vital process itself, is exerted between 
 the chyme in the intestines and the chyle in the lacteals, 
 by which the chyle is enabled to attract the chyme with- 
 out being itself attracted by it. But such affinity or 
 attraction would be of a vital nature, since it does not 
 exist after death." 
 
 14. If the force of absorption be thus mysterious in 
 its nature, the force of Secretion is still more so. In this 
 case we have an organ filled with a fine net- work of 
 blood-vessels, and in the cavities of some gland, or open 
 part, we have a new fluid formed, of a kind altogether 
 different from the blood itself. It is easily shown that 
 this cannot be explained by any action of pores or capil- 
 lary tubes. But what conception can we form of the 
 forces by which such a change is produced ? Here, again, 
 I shall borrow the expressions of Miiller, as presenting 
 the last result of modern physiology. He says *, " The 
 more probable supposition is, that by virtue of imbibition, 
 or the general organic porosity, the fluid portion of the 
 blood becomes diffused through the tissue of the secreting 
 organ ; that the external surface of the glandular canals 
 exerts a chemical attraction on the elements of the fluid, 
 infusing into them at the same time a tendency to unite 
 in new combinations ; and then repels them in a manner 
 which is certainly quite inexplicable, towards the inner 
 surface of the secreting membrane, or glandular canals." 
 " Although quite unsupported by facts," he adds, " this 
 theory of attraction and repulsion is not without its ana- 
 logy in physical phenomena ; and it would appear that 
 very similar powers effect the elimination of the fluid in 
 secretion, and cause it to be taken up by the lymphatics 
 in absorption." He elsewhere saysf, "Absorption seems 
 to depend on an attraction the nature of which is un- 
 known, but of which the very counterpart, as it were, 
 * Physiology, p. 464. t //>., p. 301. 
 
592 PHILOSOPHY OF BIOLOGY. 
 
 takes place in secretion ; the fluids altered by the se- 
 creting action being repelled towards the free side or 
 open surface only of the secreting membranes, and then 
 pressed forwards by the successive portions of the fluids 
 secreted." 
 
 15. With regard to the forces which produce the 
 Motion of absorbed or secreted fluids along their destined 
 course, it may be seen, from the last quoted sentence, 
 that the same vital force which changes the nature, also 
 produces the movement of the substance. The fluids are 
 pressed forwards by the successive portions absorbed or 
 secreted. That this is the sole cause, or at least a very 
 powerful cause, of the motion of the nutritive fluids in 
 organic bodies, is easily shown by experience. It is found* 
 that the organs which effect the ascent of the sap in trees 
 during the spring are the terminal parts of the roots; 
 that the whole force by which the sap is impelled upwards 
 is the vis a tergo, as it has been called, the force pushing 
 from behind, exerted in the roots. And thus the force 
 which produces this motion is exerted exactly at those 
 points where the organic body selects from the contiguous 
 mass those particles which it absorbs and appropriates. 
 And the same may most probably be taken for the cause 
 of the motion of the lymph and chyle ; at least, Miiller 
 saysf that no other motive power has been detected 
 which impels those fluids in their course. 
 
 Thus, though we must confess the Vital Force con- 
 cerned in Assimilation and Secretion to be unknown in 
 its nature, we still obtain a view of some of the attributes 
 which it involves. It has mechanical efficacy, producing 
 motions, often such as would require great mechanical 
 force. But it exerts at the same point both an attraction 
 and a repulsion, attracting matter on one side, and repel- 
 ling it on the other ; and in this circumstance it differs 
 * Muller, p. 300. t /&., p. 254. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 593 
 
 entirely from mechanical forces. Again, it is not only 
 mechanical but chemical, producing a complete change 
 in the nature of the substance on which it acts ; to which 
 we must add that the changes produced by the vital 
 forces are such as, for the most part, our artificial che- 
 mistry cannot imitate. But, again, by the action of the 
 vital force at any point of an organ, not only are fluids 
 made to pass, and changed as they pass, but the organ 
 itself is maintained and strengthened, so as to continue 
 or to increase its operation : and thus the vital energy 
 supports its activity by its action, and is augmented by 
 being exerted. 
 
 We have thus endeavoured to obtain a view of some 
 of the peculiar characters which belong to the Force of 
 Organic Assimilation; the Force by which life is kept 
 up, conceived in the most elementary form to which we 
 can reduce it by observation and contemplation. It ap- 
 pears that it is a force which not only produces motion 
 and chemical change, but also vitalizes the matter on 
 which it acts, giving to it the power of producing like 
 changes on other matter, and so on indefinitely. It not 
 only circulates the particles of matter, but puts them in 
 a stream of which the flow is developement as well as 
 movement. 
 
 The force of Organic Assimilation being thus con- 
 ceived, it becomes instructive to compare it with the 
 force concerned in Generation, which we shall therefore 
 endeavour to do. 
 
 SECT. IV. Attempts to conceive the Process of Gene- 
 ration. 
 
 16. At first sight the function of Nutrition appears 
 very different from the function of Generation. In the 
 former case we have merely the existing organs main- 
 tained or enlarged, and their action continued ; in the 
 VOL. i. w. P. Q Q 
 
594 PHILOSOPHY OF BIOLOGY. 
 
 latter, we have a new individual produced and extricated 
 from the parent. The term Reproduction has, no doubt, 
 been applied, by different writers, to both these func- 
 tions ; to the processes by which an organ when muti- 
 lated, is restored by the forces of the living body, and to 
 the process by which a new generation of individuals is 
 produced which may be considered as taking the place 
 of the old generation, as these are gradually removed by 
 death. But these are obviously different senses of the 
 word. In the latter case, the term Reproduction is 
 figuratively used ; for the same individuals are not repro- 
 duced ; but the species is kept up by the propagation of 
 new individuals, as in nutrition the organ is kept up by 
 the assimilation of new matter. To escape ambiguity, I 
 shall avoid using the term Reproduction in the sense of 
 Propagation. 
 
 17. In Nutrition, as we have seen, the matter, which 
 from being at first extraneous, is appropriated by the 
 living system, and directed to the sustentation of the 
 organs, undergoes a series of changes of which the detail 
 eludes our observation and apprehension. The nutriment 
 which we receive contributes to the growth of flesh and 
 bone, viscera and organs of sense. But we cannot trace 
 in its gradual changes a visible preparation for its final 
 office. The portion of matter which is destined to repair 
 the waste of the eye or the skin, is not found assuming a 
 likeness to the parts of the eye or the structure of the 
 skin, as it comes near the place where it is moulded into 
 its ultimate form. The new parts are insinuated among 
 the old ones, in an obscure and imperceptible matter. 
 We can trace their progress only by their effects. The 
 organs are nourished, and that is almost all we can learn : 
 we cannot discover how this is done. We cannot follow 
 nature through a series of manifest preparations and 
 processes to this result. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 595 
 
 18. In Generation the case is quite different. The 
 young being is formed gradually and by a series of dis- 
 tinguishable processes. It is included within the parent 
 before it is extruded, and approaches more or less to the 
 likeness of the parent before it is detached. While it is 
 still an embryo, it shares in the nutriment which circu- 
 lates through the system of the mother ; but its destina- 
 tion is already clear. While the new and the old parts, in 
 every other portion of the mother, are undistinguishably 
 mixed together, this new part, the foetus, is clearly dis- 
 tinct from the rest of the system, and becomes rapidly 
 more and more so, as the time goes on. And thus there 
 is formed, not a new part, but a new whole ; it is not an 
 organ which is kept up, but an offspring which is pre- 
 pared. The progeny is included in the parent, and is 
 gradually fitted to be separated from it. The young is at 
 first only the developement of a part of the organization 
 of the mother ; of a germ, an ovule. But it is not 
 developed like other organs, retaining its general form. 
 It does not become merely a larger bud, a larger ovule ; it 
 is entirely changed; it becomes from a bud a blossom, 
 a flower, a fruit, a seed ; from an ovule it becomes an 
 egg, a chick, a bird ; or it may be, a foetus, a child. The 
 original rudiment is not merely nourished, but unfolded 
 and transformed through the most marked and remote 
 changes, gradually tending to the form of the new indi- 
 vidual. 
 
 19. But this is not all. The foetus is, as we have 
 said, a developement of a portion of the mother's organi- 
 zation. But the foetus (supposing it female) is a likeness 
 of the mother. The mother, even before conception, 
 contains within herself the germs of her progeny ; the 
 female foetus, therefore, at a certain stage of develope- 
 ment, will contain also the germs of possible progeny ; 
 and thus we may have the germs of future generations, 
 
 QQ2 
 
596 PHILOSOPHY OF BIOLOGY. 
 
 pre-existing and included successively within one another. 
 And this state of things, which thus suggests itself to us 
 as possible, is found to be the case in facts which obser- 
 vation supplies. Anatomists have traced ovules in the 
 unborn foetus, and thus we have three generations in- 
 cluded one within another. 
 
 20. Supposing we were to stop here, the process of 
 propagation might appear to be altogether different from 
 that of nutrition. The latter, as we have seen, may be 
 in some measure illustrated by the image of a vortex ; 
 the former has been represented by the image of a series 
 of germs, sheathed one within another successively, and 
 this without any limit. This view of the subject has 
 been termed the doctrine of the P re-existence of germs ; 
 and has been designated by German writers by a term 
 "Einschachtelungs-theorie" descriptive of the successive 
 sheathing of which I have spoken. Imitating this term, 
 we may call it the Theory of successive inclusion. It has 
 always had many adherents ; and has been, perhaps, up 
 to the present time, the most current opinion on the 
 subject of generation. Cuvier inclines to this opinion*. 
 " Fixed forms perpetuating themselves by generation dis- 
 tinguish the species of living things. These forms do 
 not produce themselves, do not change themselves. Life 
 supposes them to exist already ; its flame can be lighted 
 only in organization previously prepared ; and the most 
 profound meditations and the most delicate researches 
 terminate alike in the mystery of the pre-existence of 
 germs." 
 
 21. Yet this doctrine is full of difficulty. It is, as 
 Cuvier says, a mysterious view of the subject ; so mys- 
 terious, that it can hardly be accepted by us, who seek 
 distinct conceptions as the basis of our philosophy. Can 
 it be true, not only that the germ of the offspring is 
 
 * Regne Animal^ p. 20. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 597 
 
 originally included in the parent, but also the germs of 
 its progeny, and so on without limit : So that each 
 fruitful individual contains in itself an infinite collection 
 of future possible individuals ; a reserve of infinite suc- 
 ceeding generations? This is hard to admit. Have we 
 no alternative ? What is the opposite doctrine ? 
 
 22. The opposite doctrine deserves at least some 
 notice. It extends, to the production of a new individual, 
 the conception of growth by nutrition. According to 
 this view, we suppose propagation to take place, not as 
 in the view just spoken of, by inclusion and extrusion, 
 but by assimilation and developement ; not by the 
 material pre-existence^ of germs, but by the communica- 
 tion of vital forces to new matter. This opinion appears 
 to be entertained by some of the most eminent physio- 
 logists of the present time. Thus, Miiller says, " The 
 organic force is also creative. The organic force which 
 resides in the whole, and on which the existence of each 
 part depends, has also the property of generating, from 
 organic matter, the parts necessary to the whole." Life, 
 he adds, is not merely a harmony of the parts. On the 
 contrary, the harmonious action of the parts subsists 
 only by the influence of a force pervading all parts of 
 the body. "This force exists before the harmonizing 
 parts, which are in fact formed by it during the deve- 
 lopement of the embryo." And again ; " The creative 
 force exists in the germ, and creates in it the essential 
 force of the future animal. The germ is potentially the 
 whole animal : during the developement of the germ the 
 parts which constitute the actual whole are produced." 
 
 23. In this view, we extend to the reproduction of 
 an individual the same conception of organic assimilation 
 which we have already arrived at, as the best notion we 
 can form of the force by which the reproduction and 
 sustentation of parts takes place. And is not such an 
 
598 PHILOSOPHY OF BIOLOGY. 
 
 extension really very consistent ? If a living thing can 
 appropriate to itself extraneous matter, invest it with its 
 own functions, and thus put it in the stream of constant 
 developement, may we not conceive the developement of a 
 new whole to take place in this way as well as of apart? 
 If the organized being can infuse into new matter its 
 vital forces, is there any contradiction in supposing this 
 infusion to take place in the full measure which is re- 
 quisite for the production of a new individual? The 
 force of organic assimilation is transferred to the very 
 matter on which it acts ; it may be transferred so that 
 the operation of the forces produces not only an organ, 
 but a system of organs. 
 
 24. This identification of the forces which operate 
 in Nutrition and Generation may at first seem forced 
 and obscure, in consequence of the very strong apparent 
 differences of the two processes which we have already 
 noticed. But this defect in the doctrine is remedied by 
 the consideration of what may be considered as inter- 
 mediate cases. It is not true that, in the nutrition of 
 special organs, the matter is always conveyed to its ulti- 
 mate destination without being on its way moulded into 
 the form which it is finally to bear, as the embryo is 
 moulded into the form of the future individual. On the 
 contrary, there are cases in which the waste of the organs 
 is supplied by the growth of new ones, which are pre- 
 pared and formed before they are used, just as the off- 
 spring is prepared and formed before it is separated 
 from the parent. This is the case with the teeth of 
 many animals, and especially with the teeth of animals 
 of the crocodile kind. Young teeth grow near the root 
 of the old ones, like buds on the stem of a plant ; and as 
 these become fully developed, they take the place of the 
 parent tooth when that dies and is cast away. And 
 these new teeth in their turn are succeeded by others 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 599 
 
 which germinate from them. Several generations of 
 such teeth, it is said as many as four, have been detected 
 by anatomists, visibly existing at the same time; just 
 as several generations of germs of individuals have been, 
 as we already stated, observed included in one another. 
 But this case of the teeth appears to show very strikingly 
 how insufficient such observations are to establish the 
 doctrine of successive inclusion, or of the pre-existence 
 of germs. Are we to suppose that every crocodile's 
 tooth includes in itself the germs of an infinite number 
 of possible teeth, as in the theory of pre-existing germs, 
 every individual includes an infinite number of indi- 
 viduals ? If this be true of teeth, we must suppose that 
 organ to follow laws entirely different from almost every 
 other organ ; for no one would apply to the other organs 
 in general such a theory of reproduction. But if such a 
 theory be not maintained respecting the teeth, how can 
 we maintain the theory of the pre-existing germs of 
 individuals, which has no recommendation except that 
 of accounting for exactly the same phenomena ? 
 
 It would seem, then, that we are, by the closest con- 
 sideration of the subject, led to conceive the forces by 
 which generation is produced as forces which vitalize 
 certain portions of matter, and thus prepare them for 
 developement according to organic forms ; and thus the 
 conception of this Generative Force is identified with 
 the conception of the Force of Organic Assimilation, to 
 which we were led by the consideration of the process 
 of nutrition. 
 
 I shall not attempt to give further distinctness and 
 fixity to this conception of one of the vital forces ; but 
 I shall proceed to exemplify the same analysis of life 
 by some remarks upon another Vital Process, and the 
 Forces of which it exhibits the operation. 
 
600 PHILOSOPHY OF BIOLOGY. 
 
 CHAPTER V. 
 
 ATTEMPTS TO FORM IDEAS OF SEPARATE 
 VITAL FORCES, Continued.- 
 VOLUNTARY MOTION. 
 
 1. WE formerly noticed the distinctions of organic 
 and animal functions, organic and animal forces, as one 
 of the most marked distinctions to which physiologists 
 have been led in their analysis of the vital powers. I 
 have now taken one of the former, the organic class of 
 functions, namely, nutrition; and have endeavoured to 
 point out in some measure the peculiar nature of the 
 vital forces by which this function is carried on. It may 
 serve to show the extent and the difficulty of this sub- 
 ject, if, before quitting it, I offer a few remarks sug- 
 gested by a function belonging to the other class, the 
 animal functions. This I shall briefly do with respect 
 to Voluntary Motion. 
 
 2. In the History of Physiology, I have already 
 related the progress of the researches by which the 
 organs employed in voluntary motion became known to 
 anatomists. It was ascertained to the satisfaction of all 
 physiologists, that the immediate agents in such motion 
 are the muscles ; that the muscles are in some way con- 
 tracted, when the nerves convey to them the agency of 
 the will; and that thus the limbs are moved. It was 
 ascertained, also, that the nerves convey sensations from 
 the organs of sense inwards, so as to make these sensa- 
 tions the object of the animal's consciousness. In man 
 and the higher animals, these impressions upon the 
 nerves are all conveyed to one internal organ, the brain ; 
 and from this organ all impressions of the will appear to 
 proceed ; and thus the brain is the center of animal life, 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 601 
 
 towards which sensations converge, and from which voli- 
 tions diverge. 
 
 But this being the process, we are led to inquire how 
 far we can obtain any knowledge, or form any concep- 
 tion of the vital forces by means of which the process is 
 carried on. And here I have further stated in the His- 
 tory 5 ", that the transfer of sensations and volitions along 
 the nerves was often represented as consisting in the 
 motion of a Nervous Fluid. I have related that the 
 hypothesis of such a fluid, conveying its impressions 
 either by motions of translation or of vibration, was 
 countenanced by many great names, as Newton, Haller, 
 and even Cuvier. But I have ventured to express my 
 doubt whether this hypothesis can have much value : 
 "for," I have said, "this principle cannot be mechanical, 
 chemical, or physical, and therefore cannot be better 
 understood by embodying it in a fluid. The difficulty 
 we have in conceiving what the force is, is not got rid 
 of by explaining the machinery by which it is trans- 
 ferred" 
 
 3. I may add, that no succeeding biological researches 
 appear to have diminished the force of these considera- 
 tions. In modern times, attempts have repeatedly been 
 made to identify the nervous fluid with electricity or 
 galvanism. But these attempts have not been satisfac- 
 tory or conclusive of the truth of such an identity : and 
 Professor Miiller probably speaks the judgment of the 
 most judicious physiologists, when he states it as his 
 opinion, after examining the evidence f, "That the vital 
 actions of the nerves are not attended with the deve- 
 lopement of any galvanic currents which our instruments 
 can detect ; and that the laws of action of the nervous 
 principle are totally different from those of electricity." 
 
 That the powers by which the nerves are the instru- 
 * Hist. 2nd. Scl. B. xvn. c. v. sect. 2. t Elem. Phys., p. 640. 
 
602 PHILOSOPHY OF BIOLOGY. 
 
 ments of sensation, and the muscles of motion, are vital 
 endowments, incapable of being expressed or explained 
 by any comparison with mechanical, chemical, and elec- 
 trical forces, is the result which we should expect to 
 find, judging from the whole analogy of science; and 
 which thus is confirmed by the history of physiology up 
 to the present time. We naturally, then, turn to inquire 
 whether such peculiar vital powers have been brought 
 into view with any distinctness and clearness. 
 
 4. The property by which muscles, under proper sti- 
 mulation, contract and produce motion, has been termed 
 Irritability or Contractility; the property by which 
 nerves are susceptible of their appropriate impressions 
 has been termed Sensibility. A very few words on each 
 of these subjects must suffice. 
 
 Irritability. I have, in the History of Physiology""", 
 noticed that Glisson, a Cambridge professor, distin- 
 guished the Irritation of muscles as a peculiar property, 
 different from any merely mechanical or physical action. 
 I have mentioned, also, that he divides Irritation into 
 natural, vital, and animal; and points out, though 
 briefly, the graduated differences of Irritability in differ- 
 ent organs. Although these opinions did not at first 
 attract much notice, about seventy years afterwards 
 attention was powerfully called to this vital force, Irri- 
 tability, by Haller. I shall borrow Sprengel's reflections 
 on this subject. 
 
 " Hitherto men had been led to see more and more 
 clearly that the cause of the bodily functions, the funda- 
 mental power of the animal frame, is not to be sought 
 in the mechanism, and still less in the mixture of the 
 parts. In this conviction, they had had recourse partly 
 to the quite supersensuous principle of the Soul, partly 
 to the half-material principle of the Animal Spirits, in 
 * Hist. Ind. Sci., B. xvn. c. v. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 603 
 
 order to explain the bodily motions. Glisson alone saw 
 the necessity of assuming an Original Power in the 
 fibres, which, independent of the influence of the animal 
 spirits, should produce contraction in them. And Gor- 
 ter first held that this Original Power was not to be 
 confined to the muscles, but to be extended to all parts 
 of the living body. 
 
 " But as yet the laws of this Power were not known, 
 nor had men come to an understanding whether it were 
 fully distinct from the elasticity of the parts, or by what 
 causes it was put in action. They had neither instituted 
 observations nor experiments which established its rela- 
 tion to other assumed forces of the body. There was 
 still wanting a determination of the peculiar seat of this 
 power, and experiments to trace its gradual differences 
 in different parts of the body. In addition to other 
 causes, the necessity of the assumption of such a power 
 was felt the more, in consequence of the prevalence of 
 Leibnitz's doctrine of the activity of matter; but it 
 was an occult quality, and remained so till Haller, by 
 numerous experiments and solid observations, placed in 
 a clear light the peculiarities of the powers of the ani- 
 mal body." 
 
 5. Perhaps, however, Haller did more in the way of 
 determining experimentally the limits and details of the 
 application of this idea of Irritability as a peculiar attri- 
 bute, than in developing the Idea itself. In this way his 
 merits were great. As early as the year 1739, he pub- 
 lished his opinion upon Irritability as the cause of mus- 
 cular motion, which he promulgated again in 1743. 
 But from the year 1747 he was more attentive to the 
 peculiarities of Irritability, and its difference from the 
 effect of the nerves. In the first edition of his Phy- 
 siology, which appeared in 1747, he distinguished three 
 kinds of Force in muscles, the Dead Force, the Innate 
 
604 PHILOSOPHY OF BIOLOGY. 
 
 Force, and the Nervous Power. The first is identical 
 with the elastic force of dead matter, and remains even 
 after death. The innate force continues only a short 
 time after death, and discloses itself especially by alter- 
 nate oscillations ; the motions which arise from this are 
 much more lively than those which arise from mere 
 elasticity : they are not excited by tension, nor by pres- 
 sure, nor by any mechanical alteration, but only by irri- 
 tation. The nervous force of the muscle is imparted to 
 it from without by the nerves ; it preserves the irrita- 
 bility, which cannot long subsist without the influence 
 of the nervous force, but is not identical with it. 
 
 In the year 1752, Haller laid before the Society of 
 Gottingen the result of one hundred and ninety experi- 
 ments ; from which it appears to what parts of the 
 animal system Irritability and Nervous Power belong. 
 These I need not enumerate. He also investigated with 
 care its gradations in those parts which do possess it. 
 Thus the heart possesses it in the highest degree, and 
 other organs follow in their order. 
 
 6. Haller's doctrine was, that there resides in the 
 muscles a peculiar vital power by which they contract, 
 and that this power is distinct from the attributes of the 
 nerves. And this doctrine has been accepted by the 
 best physiologists of modern times. But this distinc- 
 tion of the irritability of the muscles from the sensi- 
 bility of the nerves became somewhat clearer by giving 
 to the former attribute the name of Contractility. This 
 accordingly was done ; it is, for example, the phraseo- 
 logy used by Bichat. By speaking of animal sensibility 
 and animal contractility, the passive and the active 
 element of the processes of animal life are clearly sepa- 
 rated and opposed to each other. The sensations which 
 we feel, and the muscular action which we exert, may 
 be closely and inseparably connected, yet still they are 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. G05 
 
 clearly distinguishable. We can easily in our apprehen- 
 sion separate the titillation felt in the nose on taking 
 snuff, from the action of the muscles in sneezing ; or the 
 perception of an object falling towards the eye, from the 
 exertion which shuts the eye-lid ; although in these 
 cases the passive and active part of the process are 
 almost or quite inseparable in fact. And this clear 
 separation of the active from the passive power is some- 
 thing, it would seem, peculiar to the Animal Vital 
 Powers ; it is a character by which they differ, not only 
 from mechanical, chemical, and all other merely physical 
 forces, but even from Organic Vital Powers. 
 
 7. But this difference between the Animal and the 
 Organic Vital Powers requires to be further insisted 
 upon, for it appears to have been overlooked or denied 
 by very eminent physiologists. For instance, Bichat 
 classifies the Vital Powers as Animal Sensibility, Ani- 
 mal Contractility, Organic Sensibility, Organic Contrac- 
 tility. 
 
 Now the view which suggests itself to us, in agree- 
 ment with what has been said, is this : that though 
 Animal Sensibility and Animal Contractility are clearly 
 and certainly distinct, Organic Sensibility and Organic 
 Contractility are neither separable in fact nor in our 
 conception, but together make up a single Vital Power. 
 That they are not separable in fact is, indeed, acknow- 
 ledged by Bichat himself. " The organic contractility," 
 he says'*, "can never be separated from the sensibility 
 of the same kind ; the reaction of the excreting tubes is 
 immediately connected with the action which the secreted 
 fluids exercise upon them : the contraction of the heart 
 must necessarily succeed the influx of the blood into it." 
 It is not wonderful, therefore, that it should have hap- 
 pened, as he complains, that " authors have by no means 
 
 * Life and Death, p. 94. 
 
606 PHILOSOPHY OF BIOLOGY. 
 
 separated these two things, either in their consideration 
 or in language." We cannot avoid asking, Are Organic 
 Sensibility and Organic Contractility really anything 
 more than two different aspects of the same thing, like 
 action and reaction in mechanics, which are only two 
 ways of considering the action which takes place at a 
 point ; or like the positive and negative electricities, 
 which, as we have seen, always co-exist and correspond 
 to each other? 
 
 8. But we may observe, moreover, that Bichat, by 
 his use of the term Contractility, includes in it powers 
 to which it cannot with any propriety be applied. Why 
 should we suppose that the vital powers of absorption, 
 secretion, assimilation, are of such a nature that the 
 name contractility may be employed to describe them ? 
 We have seen, in the last chapter, that the most careful 
 study of these powers leads us to conceive them in a 
 manner altogether removed from any notion of contrac- 
 tion. Is it not then an abuse of language which cannot 
 possibly lead to anything but confusion, to write thus* : 
 "The insensible organic contractility is that, by virtue 
 of which the excreting tubes react upon their respective 
 fluids, the secreting organs upon the blood which flows 
 into them, the parts where nutrition is performed upon 
 the nutritive juices, and the lymphatics upon the sub- 
 stances which excite their open extremities." In the 
 same manner he ascribes f to the peculiar sensibility of 
 each organ the peculiarity of its products and operations. 
 An increased absorption is produced by an increased 
 susceptibility of the " absorbent orifices." And thus, in 
 this view, each organic power may be contemplated 
 either as sensibility or as contractility, and may be sup- 
 posed to be rendered more intense by magnifying either 
 of these its aspects ; although, in fact, neither can be 
 * Life and Death, p. 95. t Ib., p. 90. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 607 
 
 conceived to be increased without an exactly commen- 
 surate increase of the other. 
 
 9. This opinion, unfounded as it thus appears to be, 
 that all the different organic vital powers are merely dif- 
 ferent kinds of Contractility or Excitability, was con- 
 nected with the doctrines of Brown and his followers, 
 which were so celebrated in the last century, that all 
 diseases arise from increase or from diminution of the 
 Vital Force. The considerations which have already 
 offered themselves would lead us to assent to the judg- 
 ment which Cuvier has pronounced upon this system. 
 " The theory of excitation," he says, " so celebrated in 
 these later times by its influence upon pathology and 
 therapeutick, is at bottom only a modification of that, in 
 which, including under a common name Sensibility and 
 Irritability," and we may add, applying this name to all 
 the Vital Powers, "the speculator takes refuge in an 
 abstraction so wide, that if, by it, he simplifies medicine, 
 he annihilates all positive physiology*." 
 
 10. The separation of the nervous influence and the 
 muscular irritability, although it has led to many highly 
 instructive speculations, is not without its difficulties, 
 when viewed with reference to the Idea of Vital Power. 
 If the irritability of each muscle reside in the muscle 
 itself, how does it differ from a mere mechanical force, 
 as elasticity ? But, in point of fact, it is certain that 
 the muscular irritability of the animal body is not an 
 attribute of the muscle itself independent of its con- 
 nexion with the system. No muscle, or other part, 
 removed from the body, long preserves its irritability. 
 This power cannot subsist permanently, except in con- 
 nexion with an organic whole. This condition peculiarly 
 constitutes irritability a living force : and this condition 
 would be satisfied by considering the force as derived 
 
 * Hist, des Set. Nat. depuis 1789, i. 219. 
 
608 PHILOSOPHY OF BIOLOGY. 
 
 from the nervous system ; but it appears that though the 
 nervous system has the most important influence upon 
 all vital actions, the muscular irritability must needs be 
 considered as something distinct. And thus the Irrita- 
 bility or Contractility of the muscle is a peculiar endow- 
 ment of the texture, but it is at the same time an 
 endowment which can only co-exist with life ; it is, in 
 short, a peculiar Vital Power. 
 
 11. This necessity of the union of the muscle with 
 the whole nervous system, in order that it may possess 
 irritability, was the meaning of the true part of Stahl's 
 psychical doctrine ; and the reason why he and his ad- 
 herents persisted in asserting the power of the soul even 
 over involuntary motions. This doctrine was the source 
 of much controversy in later times. 
 
 "But," says Cuvier*, "this opposition of opinion 
 may be reconciled by the intimate union of the nervous 
 substance with the fibre and the other contractile organic 
 elements, and by their reciprocal action; doctrines 
 which had been presented with so much probability by 
 physiologists of the Scotch school, but which were ele- 
 vated above the rank of hypotheses only by the observa- 
 tions of more recent times. 
 
 "The fibre does not contract by itself, but by the 
 influence of the nervous filaments, which are always 
 united with it. The change which produces the con- 
 traction cannot take place without the concurrence of 
 both these substances ; and it is further necessary that it 
 should be occasioned each time by an exterior cause, by 
 a stimulant. 
 
 "The will is one of these stimulants; but it only 
 excites the irritability, it does not constitute it ; for in 
 the case of persons paralytic from apoplexy, the irrita- 
 bility remains, though the power of the will over it is 
 
 * Hist, des Sci. Nat. depuis 1789, i. 213. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE A^ITAL FORCES. 609 
 
 gone. Thus irritability depends in part on the nerve, 
 but not on the sensibility : this last is another property, 
 still more admirable and occult than the irritability; 
 but it is only one among several functions of the nervous 
 system. " It would be an abuse of words to extend this 
 denomination to functions unaccompanied by perception." 
 
 12. Supposing, then, that Contractility is established 
 as a peculiar Vital Power residing in the muscles, we 
 may ask whether we can trace with any further exact- 
 ness the seat and nature of this power. It would be 
 unsuitable to the nature of the present work to dwell 
 upon the anatomical discussions bearing upon this point. 
 I will only remark that some anatomists maintain * that 
 muscles are contracted by those fibres assuming a zigzag 
 form, which at first were straight. Others (Professor 
 Owen and Dr. A Thompson,) doubt the accuracy of this 
 observation ; and conceive that the muscular fibre be- 
 comes shorter and thicker, but does not deviate from a 
 right line. We may remark that the latter kind of action 
 appears to be more elementary in its nature. We can 
 conceive a straight line thrown into a zigzag shape by 
 muscular contractions taking place between remote parts 
 of it ; but it is difficult to conceive by what elementary 
 mode of action a straight fibre could bend itself at cer- 
 tain points, and at certain points only; since the ele- 
 mentary force must act at every point of the fibre, and 
 not at certain selected points. 
 
 13. A circumstance which remarkably marks the 
 difference between the vital force of Contractility, inhe- 
 rent in muscles, and any merely dead or mechanical 
 force, is this; that in assuming their contractile state, 
 muscles exert a tension which they could not themselves 
 support or convey if not strengthened by their vital 
 irritability. They are capable of raising weights by their 
 
 * Miiller, Elem. Phys., p. 887- 
 VOL. I. W. P. R R 
 
61 PHILOSOPHY OF BIOLOGY. 
 
 exertion, which will tear them asunder when the power 
 of contraction is lost by death. This has induced Cuvier 
 and other physiologists* to believe "that in the moment 
 of action, the particles that compose a fibre, not only 
 approach towards each other longitudinally, but that 
 their cohesive attraction becomes instantaneously much 
 greater than it was before : for without such an increase 
 of cohesive force, the tendency to shorten could not, as 
 it would appear, prevent the fibre from being torn." We 
 see here the difficulty, or rather the impossibility, of 
 conceiving muscular contractility as a mere mechanical 
 force ; and perhaps there is little hope of any advantage 
 by calling in the aid of chemical hypothesis to solve the 
 mechanical difficulty. Cuvier conjectures that a sudden 
 change in the chemical composition may thus so quickly 
 and powerfully augment the cohesion. But we may ask, 
 are not a chemical synthesis and analysis, suddenly per- 
 formed by a mere act of the will, as difficult to conceive 
 as a sudden increase and decrease of mechanical power 
 directly produced by the same cause ? 
 
 14. Sensibility. The nerves are the organs and cha'n- 
 nels of sensibility. By means of them we receive our 
 sensations, whether of mere pleasure and pain, or of 
 qualities which we ascribe to external objects, as a bitter 
 taste, a sweet odour, a shrill sound, a red colour, a hard 
 or a hot object of touch. Some of these sensations are 
 but obscurely the objects of our consciousness ; as for 
 example the feeling which our feet have of the ground, 
 or the sight which our eyes have of neighbouring objects, 
 when we walk in a reverie. In these cases the sensa- 
 tions, though obscure, exist ; for they serve to balance 
 and guide us as we walk. In other cases, our sensations 
 are distinctly and directly the objects of our attention. 
 
 But our sensations, as we have already said, we 
 * Prichard, Vital Prin., p. 126. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 611 
 
 ascribe as qualities to external objects. By our senses 
 we perceive objects, and thus our sensations become 
 perceptions. We have not only the sensation of round, 
 purple, and green, repeated and varied, but the percep- 
 tion of a bunch of grapes partly ripe and partly unripe. 
 We have not only sensations of noise and of variously- 
 coloured specks rapidly changing their places, but we 
 have perceptions, by sound and sight, of a stone rolling 
 down the hill and crushing the shrubs in its path. We 
 scarcely ever dwell upon our sensations; our thoughts 
 are employed upon objects. We regard the impressions 
 upon our nerves, not for what they are, but for what 
 they tell us. 
 
 But in what language do the impressions upon the 
 nerves thus speak to us of an external world, of the 
 forms and qualities and actions of objects? How is it 
 that by the aid of our nervous system we become ac- 
 quainted not only with impressions but with tilings ; 
 that we learn not only the relation of objects to us, but 
 to one another ? 
 
 15. It has been shown at some length in the pre- 
 vious Books, that the mode in which sensations are 
 connected in our minds so as to convey to us the 
 knowledge of objects and their relations, is by being con- 
 templated with reference to Ideas. Our sensations, con- 
 nected by the Idea of Space, become figures ; connected 
 by the Idea of Time, they become causes and effects; 
 connected by the Idea of Resemblance, they become 
 individuals and kinds ; connected by the Idea of Organ- 
 ization, they, become living things. It has been shown 
 that without these Ideas there can be no connexion 
 among our sensations, and therefore no perception of 
 Figure, Action, Kind, or in short, of bodies under any 
 aspect whatever. Sensations are the rude Matter of 
 our perceptions ; and are nothing, except so far as they 
 
 R R 2 
 
612 PHILOSOPHY OF BIOLOGY. 
 
 have Form given them by Ideas. But thus moulded by 
 our Ideas, Sensation becomes the source of an endless 
 store of important Knowledge of every possible kind. 
 
 16. But one of the most obvious uses of our percep- 
 tions and our knowledge is to direct our actions. It is 
 suitable to the condition of our being that when we 
 perceive a bunch of grapes, we should be able to pluck 
 and eat the ripe ones; that when we perceive a stone 
 rushing down the side of a hill, we should be able to 
 move so as to avoid it. And this must be done by 
 moving our limbs ; in short, by the use of our muscles. 
 And thus sensation leads, not directly, but through the 
 medium of Ideas, to muscular contraction. I say that 
 sensation and muscular action are in such cases con- 
 nected through the medium of Ideas. For when we 
 proceed to pluck the grape which we see, the sensation 
 does not determine the motion of the hand by any neces- 
 sary geometrical or mechanical conditions, as an impres- 
 sion made upon a machine determines its motions ; but 
 the perception leads us to stretch forth the hand to that 
 part of space, wherever it is, where we know that the 
 grape is, and this, not in any determinate path, but, it 
 may be, avoiding or removing intervening obstacles, 
 which we also perceive. There is in every such case a 
 connexion between the sensation and the resulting 
 action, not of a material but of a mental kind. The 
 cause and the effect are bound together, not by physical 
 but by intellectual ties. 
 
 17. And thus in such cases, between the two vital 
 operations, sensation and muscular action, there inter- 
 venes, as an intermediate step, perception or knowledge, 
 which is not merely vital but ideal. But this is not all ; 
 there is still another mental part of the process which 
 may be readily distinguished from that which we have 
 described. An act of the Will, a Volition, is that in the 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 613 
 
 mind which immediately determines the action of the 
 muscles of the body. And thus Will intervenes between 
 Knowledge and Action ; and the cycle of operations 
 which take place when animals act with reference to 
 external objects is this: Sensation, Perception, Volition, 
 Muscular Contraction. 
 
 18. To attempt further to analyze the mental part 
 of this cycle does not belong to the present part of our 
 work. But we may remark here, as we have already 
 remarked in the History*, how irresistibly we are led 
 by physiological researches into the domain of thought 
 and mind. We pass from the body to the soul, from 
 physics to metaphysics ; from biology to psychology ; 
 from things to persons; from nouns to pronouns. I have 
 there noticed the manner in which Cuvier expresses this 
 transition by the introduction of the pronoun : "The 
 impression of external objects upon the ME, the produc- 
 tion of a sensation, of an image, is a mystery impene- 
 trable to our thoughts." 
 
 19. But to return to the merely biological part of 
 our speculations. We have arrived, it will be perceived, 
 at this result : that in animal actions there intervenes 
 between the two terms of Sensation and Muscular Con- 
 traction, an intermediate process; which may be de- 
 scribed as a communication to and from a center. The 
 center is the seat of the sentient and volent faculties, 
 and is of a hyperphysical nature. But the existence of 
 such a center as a necessary element in the functions of 
 the animal life is a truth which is important in biology. 
 This indeed may be taken as the peculiar character of 
 animal, as distinguished from merely organic powers. 
 Accordingly, it is so stated by Bichat. For although he 
 superfluously, as I have tried to show, introduces into 
 his list of vital powers an organic sensibility, he still 
 
 * Hist. Ind. Set. B. xvn. c. v sect. 2. 
 
614 PHILOSOPHY OF BIOLOGY. 
 
 draws the distinction of which I have spoken ; " in the 
 animal life, sensibility is the faculty of receiving an im- 
 pression plus that of referring it to a common center""." 
 
 20. But since Sensibility and Contractility are thus 
 connected by reference to a common Center, we may 
 ask, before quitting the subject, what are the different 
 forms which this reference assumes. Is the connexion 
 always attended by the distinct steps of knowledge and 
 will, by a clear act of consciousness, as in the case 
 which we have taken, of plucking a grape; or may these 
 steps become obscure, or vanish altogether? 
 
 We need not further illustrate the former connexion. 
 Such actions as we have described are called voluntary 
 actions. In extreme cases, the mental part of the pro- 
 cess is obvious enough. But we may gradually pass 
 from these to cases in which the mental operation is more 
 and more obscure. 
 
 In walking, in speaking, in eating, in breathing, our 
 muscular exertions are directed by our sensations and 
 perceptions : yet in such processes, how dimly are we 
 conscious of perceptive and directive power ! How the 
 mind should be able to exercise such a power, and yet 
 should be scarcely or not at all conscious of its exercise, 
 is a very curious problem. But in all or in most of the 
 above instances, the solution of this problem appears to 
 depend upon psychological rather than biological prin- 
 ciples, and therefore does not belong to this place. 
 
 21. But in cases at the other extreme, the mental 
 part of the operation vanishes altogether. In many 
 animals, even after decapitation, the limbs shrink when 
 irritated. The motions of the iris are determined by 
 the influence of light on our eyes, without our being 
 aware of the motions. Here sensations produce motions, 
 but with no trace of intervening perception or will. 
 
 * Life and Death, p. 84. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 615 
 
 The sensation appears to be reflated back from the 
 central element of animal life, in the form of a muscular 
 contraction; but in this case the sensation is not modified 
 or regulated by any Idea. These reflected motions have 
 no reference to relations of space or force among sur- 
 rounding objects. They are blind and involuntary, like 
 the movements of convulsion, depending for direction 
 and amount only on the position and circumstances of 
 the limb itself with its muscles. Here the Center from 
 which the reflection takes place is merely animal, not 
 intellectual. 
 
 In this case some physiologists have doubted whether 
 the reflection of the sensation in the form of a muscular 
 contraction does really take place from the Center ; and 
 have conceived that sensorial impressions might affect 
 motor nerves without any communication with the nerv- 
 ous Center. But on this subject we may, I conceive, 
 with safety adopt the decision of Professor Miiller, deli- 
 berately given after a careful examination of the subject. 
 "When impressions made by the action of external 
 stimuli on sensitive nerves give rise to motions in other 
 parts, these motions are never the result of the direct 
 reaction of the sensitive and motor fibres of the nerves 
 on each other ; the irritation is conveyed by the sensi- 
 tive fibres to the brain and spinal cord, and is by these 
 communicated to the motor fibres." 
 
 22. Thus we have two extreme cases of the con- 
 nexion of sensation with muscular action ; in one of 
 which the connexion clearly is, and in the other it as 
 clearly is not, determined by "relations of Ideas, in its 
 transit through the nervous Center. There is another 
 highly curious case standing intermediate between these 
 two, and extremely difficult to refer to either. I speak 
 of the case of Instinct. 
 
 Instinct leads to actions which are such as if they 
 
616 PHILOSOPHY OF BIOLOGY. 
 
 mere determined by Ideas. The lamb follows its mother 
 by instinct ; but the motions by which it does this, the 
 special muscular exertions, depend entirely upon the 
 geometrical and mechanical relations of external bodies, 
 as the form of the ground, and the force of the wind. 
 The contractions of the muscles which are requisite in 
 order that the creature may obey its instinct, vary with 
 every variation of these external conditions ; are not 
 determined by any rule or necessity, but by properties 
 of space and force. Thus the action is not governed by 
 sensations directly, but by sensations moulded by ideas. 
 And the same is the case with other cases of instinct. 
 The dog hunts by instinct ; but he hunts certain kinds 
 of animals merely, thus showing that his instinct acts 
 according to resemblances and differences; he crosses the 
 field repeatedly to find the track of his prey by scent ; 
 thus recognizing the relations of space with reference to 
 the track ; he leaps, adjusting his force to the distance 
 and height of the leap with mechanical precision ; and 
 thus he practically recognizes the Ideas of Resemblance, 
 Space, and Force. 
 
 But have animals such Ideas ? In any proper sense 
 in which we can speak of possessing Ideas, it appears 
 plain that they have not. Animals cannot, at any time, 
 be said properly to possess ideas, for ideas imply the 
 possibility of speculative knowledge. 
 
 23. But even if we allow to animals only the prac- 
 tical possession of ideas, we have still a great difficulty 
 remaining. In the case of man, his ideas are unfolded 
 gradually by his intercourse with the external world. 
 The child learns to distinguish forms and positions by a 
 repeated and incessant use of his hands and eyes ; he 
 learns to walk, to run, to leap, by slow and laborious 
 degrees; he distinguishes one man from another, and 
 one animal from another, only after repeated mistakes. 
 
ATTEMPTS TO FORM IDEAS OF SEPARATE VITAL FORCES. 617 
 
 Nor can we conceive this to be otherwise. How should 
 the child know at once what muscles he is to exert in 
 order to touch with his hand a certain visible object? 
 How should he know what muscles to exert that he may 
 stand and not fall, till he has tried often? How should 
 he learn to direct his attention to the differences of 
 different faces and persons, till he is roused by some 
 memory, or hope which implies memory? It seems to 
 us as if the sensations could not, without considerable 
 practice, be rightly referred to Ideas of Space, Force, 
 Resemblance, and the like. 
 
 Yet that which thus appears impossible, is in fact 
 done by animals. The lamb almost immediately after its 
 birth follows its mother, accommodating the actions of 
 its muscles to the form of the ground. The chick, just 
 escaped from the shell, picks up a minute insect, directing 
 its beak with the greatest accuracy. Even the human 
 infant seeks the breast and exerts its muscles in sucking, 
 almost as soon as it is born. Hence, then, we see that 
 Instinct produces at once actions regulated by Ideas, or, 
 at least, which take place as if they were regulated by 
 Ideas; although the Ideas cannot have been developed 
 by exercise, and only appear to exist so far as such 
 actions are concerned. 
 
 24. The term Instinct may properly be opposed to In- 
 sight. The former implies an inward principle of action, 
 implanted within a creature and practically impelling it, 
 but not capable of being developed into a subject of con- 
 templation. While the instinctive actions of animals are 
 directed by such a principle, the deliberate actions of 
 man are governed by insight : he can contemplate the 
 ideal relations on which the result of his action depends. 
 He can in his mind map the path he will follow, and 
 estimate the force he will exert, and class the objects he 
 has to deal with, and determine his actions by the rela- 
 
618 PHILOSOPHY OF BIOLOGY. 
 
 tions wich he thus has present to his mind. He thus 
 possesses Ideas not only practically, but speculatively. 
 And knowing that the Ideas by which he commonly di- 
 rects his actions, Space, Cause, Resemblance, and the like, 
 have been developed to that degree of clearness in which 
 he possesses them by the assiduous exercise of the senses 
 and the mind from the earliest stage of infancy, and that 
 these Ideas are capable of being still further unfolded 
 into long trains of speculative truth, he" is unable to con- 
 ceive the manner in which animals possess such Ideas as 
 their instinctive actions disclose : Ideas which neither 
 require to be unfolded nor admit of unfolding; which 
 are adequate for practical purposes without any previous 
 exercise, and inadequate for speculative purposes with 
 whatever labour cultivated. 
 
 I have ventured to make these few remarks on In- 
 stinct since it may, perhaps, justly be considered as the 
 last province of Biology, where we reach the boundary 
 line of Psychology. I have now, before quitting this 
 subject, only one other principle to speak of. 
 
 CHAPTER VI. 
 OF THE IDEA OF FINAL CAUSES. 
 
 1. BY an examination of those notions which enter 
 into all our reasonings and judgments on living things, it 
 appeared that we conceive animal life as a vortex or cycle 
 of moving matter in which the form of the vortex deter- 
 mines the motions, and these motions again support the 
 form of the vortex : the stationary parts circulate the 
 fluids, and the fluids nourish the permanent parts. Each 
 portion ministers to the others, each depends upon the 
 other. The parts make up the whole, but the existence 
 
IDEA OF FINAL CAUSES. 619 
 
 of the whole is essential to the preservation of the parts. 
 But parts existing under such conditions are organs, and 
 the whole is organized. This is the fundamental concep- 
 tion of organization. " Organized beings," says the phy- 
 siologist "*, "are composed of a number of essential and 
 mutually dependent parts." "An organized product of 
 nature," says the great metaphysician f, "is that in which 
 all the parts are mutually ends and means." 
 
 2. It will be observed that we do not content our- 
 selves with saying that in such a whole, all the parts are 
 mutually dependent. This might be true even of a me- 
 chanical structure ; it would be easy to imagine a frame- 
 work in which each part should be necessary to the 
 support of each of the others ; for example, an arch of 
 several stones. But in such a structure, the parts have 
 no properties which they derive from the whole. They 
 are beams or stones when separate ; they are no more 
 when joined. But the same is not the case in an 
 organized whole. The limb of an animal separated from 
 the body, loses the properties of a limb, and soon ceases 
 to retain even its form. 
 
 3. Nor do we content ourselves with saying that the 
 parts are mutually causes and effects. This is the case 
 in machinery. In a clock, the pendulum by means of 
 the escapement causes the descent of the weight, the 
 weight by the same escapement keeps up the motion of 
 the pendulum. But things of this kind may happen by 
 accident. Stones slide from a rock down the side of a 
 hill and cause it to be smooth ; the smoothness of the 
 slope causes stones still to slide. Yet no one would call 
 such a slide an organized system. The system is organ- 
 ized, when the effects which take place among the parts 
 are essential to our conception of the whole ; when the 
 whole would not be a whole, nor the parts, parts, except 
 
 * Miiller, Elcm., p. 18. t Kant, Urthcilskraft, p 296. 
 
620 PHILOSOPHY OF BIOLOGY. 
 
 these effects were produced; when the effects not only 
 happen in fact, but are included in the idea of the object ; 
 when they are not only seen, but foreseen ; not only ex- 
 pected, but intended : in short when, instead of being- 
 causes and effects, they are ends and means, as they are 
 termed in the above definition. 
 
 Thus we necessarily include, in our Idea of Organi- 
 zation, the notion of an End, a Purpose, a Design ; or, to 
 use another phrase which has been peculiarly appro- 
 priated in this case, a Final Cause. This idea of a Final 
 Cause is an essential condition in order to the pursuing 
 our researches respecting organized bodies. 
 
 4. This Idea of Final Cause is not deduced from the 
 phenomena by reasoning, but is assumed as the only con- 
 dition under which we can reason on such subjects at all. 
 We do not deduce the Idea of Space, or Time, or effi- 
 cient Cause from the phenomena about us, but necessarily 
 look at phenomena as subordinate to these Ideas from 
 the beginning of our reasoning. It is true, our ideas of 
 relations of Space, and Time, and Force, may become 
 much more clear by our familiarizing ourselves with par- 
 ticular phenomena : but still, the Fundamental Ideas are 
 not generated but unfolded ; not extracted from the 
 external world, but evolved from the world within. In 
 like manner, in the contemplation of organic structures, 
 we consider each part as subservient to some use, and we 
 cannot study the structure as organic without such a 
 conception. This notion of adaptation, this Idea of an 
 End, may become much more clear and impressive by 
 seeing it exemplified in particular cases. But still, 
 though suggested and evoked by special cases, it is not 
 furnished by them. If it be not supplied by the mind 
 itself, it can never be logically deduced from the pheno- 
 mena. It is not a portion of the facts which we study, 
 but it is a principle which connects, includes, and renders 
 
IDEA OF FINAL CAUSES. 621 
 
 them intelligible ; as our other Fundamental Ideas do 
 the classes of facts to which they respectively apply. 
 
 5. This has already been confirmed by reference to 
 fact; in the History of Physiology, I have shown that those 
 who studied the structure of animals were irresistibly led 
 to the conviction that the parts of this structure have 
 each its end or purpose ; that each member and organ 
 not merely produces a certain effect or answers a certain 
 use, but is so framed as to impress us with the persuasion 
 that it was constructed/or that use: that it was intended 
 to produce the effect. It was there seen that this per- 
 suasion was repeatedly expressed in the most emphatic 
 manner by Galen ; that it directed the researches and 
 led to the discoveries of Harvey; that it has always 
 been dwelt upon as a favourite contemplation, and fol- 
 lowed as a certain guide, by the best anatomists ; and 
 that it is inculcated by the physiologists of the profound- 
 est views and most extensive knowledge of our own time. 
 All these persons have deemed it a most certain and im- 
 portant principle of physiology, that in every organized 
 structure, plant or animal, each intelligible part has its 
 allotted office: each organ is designed for its appropriate 
 function : that nature, in these cases, produces nothing 
 in vain : that, in short, each portion of the whole arrange- 
 ment has its final cause ; an end to which it is adapted, 
 and in this end, the reason that it is where and what 
 it is. 
 
 6. This Notion of Design in organized bodies must, I 
 say, be supplied by the student of organization out of 
 his own mind : a truth which will become clearer if 
 we attend to the most conspicuous and acknowledged 
 instances of design. The structure of the eye, in which 
 the parts are curiously adjusted so as to produce a distinct 
 image on the retina, as in an optical instrument; the 
 trochlear muscle of the eye, in which the tendon passes 
 
622 PHILOSOPHY OF BIOLOGY. 
 
 round a support and turns back, like a rope round a 
 pulley; the prospective contrivances for the preservation 
 of animals, provided long before they are wanted, as the 
 nlilk of the mother, the teeth of the child, the eyes and 
 lungs of the foetus : these arrangements, and innumer- 
 able others, call up in us a persuasion that Design has 
 entered into the plan of animal form and progress. And 
 if we bring in our minds this conception of Design, nothing 
 can more fully square with and fit it, than such instances 
 as these. But if we did not already possess the Idea of 
 Design ; if we had not had our notion of mechanical 
 contrivance awakened by inspection of optical instru- 
 ments, or pulleys, or in some other way; if we had 
 never been conscious ourselves of providing for the 
 future ; if this were the case, we could not recognize 
 contrivance and prospectiveness in such instances as we 
 have referred to. The facts are, indeed, admirably in 
 accordance with these conceptions, when the two are 
 brought together: but the facts and the conceptions 
 come together from different quarters from without 
 and from within. 
 
 7. We may further illustrate this point by referring 
 to the relations of travellers who tell us that when con- 
 summate examples of human mechanical contrivance 
 have been set before savages, they have appeared inca- 
 pable of apprehending them as proofs of design. This 
 shows that in such cases the Idea of Design had not 
 been developed in the minds of the people who were 
 thus unintelligent : but it no more proves that such an 
 idea does not naturally and necessarily arise, in the pro- 
 gress of men's minds, than the confused manner in 
 which the same savages apprehend the relations of space, 
 or number, or cause, proves that these ideas do not 
 naturally belong to their intellects. All men have these 
 ideas ; and it is because they cannot help referring their 
 
IDEA OF FINAL CAUSES. 623 
 
 sensations to such ideas, that they apprehend the world 
 as existing in time and space, and as a series of causes 
 and effects. It would be very erroneous to say that the 
 belief of such truths is obtained by logical reasoning 
 from facts. And in like manner we cannot logically 
 deduce design from the contemplation of organic struc- 
 tures; although it is impossible for us, when the facts 
 are clearly before us, not to find a reference to design 
 operating in our minds. 
 
 8. Again; the evidence of the doctrine of Final 
 Causes as a fundamental principle of Biology may be 
 obscured and weakened in some minds by the constant 
 habit of viewing this doctrine with suspicion as unphi- 
 losophical and at variance with morphology. By che- 
 rishing such views, it is probable that many persons, 
 physiologists and others, have gradually brought them- 
 selves to suppose that many or most of the arrange- 
 ments which are familiarly adduced as instances of design 
 may be accounted for, or explained away ; that there is 
 a certain degree of prejudice and narrowness of compre- 
 hension in that lively admiration of the adaptation of 
 means to ends which common minds derive from the 
 spectacle of organic arrangements. And yet, even in 
 persons accustomed to these views, the strong and natu- 
 ral influence of the Idea of a Final Cause, the spon- 
 taneous recognition of the relation of means to an end 
 as the assumption which makes organic arrangements 
 intelligible, breaks forth when we bring before them a 
 new case, with regard to which their genuine convictions 
 have not yet been modified by their intellectual habits. 
 I will offer, as an example which may serve to illustrate 
 this, the discoveries recently made with regard to the 
 process of suckling in the kangaroo. In the case of this, 
 as of other pouched animals, the young animal is re- 
 moved, while very small and imperfectly formed, from 
 
624 PHILOSOPHY OF BIOLOGY. 
 
 the womb to the pouch, in which the teats are, and is 
 there placed with its lips against one of the nipples. But 
 the young animal taken altogether is not so large as 
 the nipple, and is therefore incapable of sucking after 
 the manner of common mammals. Here is a difficulty : 
 how is it overcome? By an appropriate contrivance: the 
 nipple, which in common mammals is not furnished with 
 any muscle, is in the kangaroo provided with a powerful 
 extrusory muscle by which the mother can inject the 
 milk into the mouth of her offspring. And again ; in 
 order to give attachment to this muscle there is a bone 
 which is not found in animals of other kinds. But this 
 mode of solving the problem of suckling so small a 
 creature introduces another difficulty. If the milk is 
 injected into the mouth of the young one, without any 
 action of its own muscles, what is to prevent the fluid 
 entering the windpipe and producing suffocation ? How 
 is this danger avoided? By another appropriate con- 
 trivance : there is a funnel in the back of the throat by 
 which the air passage is completely separated from the 
 passage for nutriment, and the injected milk passes in a 
 divided stream on each side of the larynx to the oeso- 
 phagus'". And as if to show that this apparatus is 
 really formed with a view to the wants of the young 
 one, the structure alters in the course of the animal's 
 growth ; and the funnel, no longer needed, is modified 
 and disappears. 
 
 With regard to this and similar examples, the remark 
 which I would urge is this : that no one, however pre- 
 judiced or unphilosophical he may in general deem the 
 reference to Final Causes, can, at the first impression, 
 help regarding this curious system of arrangement as 
 the means to an end. So contemplated, it becomes 
 significant, intelligible, admirable : without such a prin- 
 
 * Mr. Owen, in Phil. Trans., 1834, p. 348. 
 
IDEA OF FINAL CAUSES. 625 
 
 ciple, it is an unmeaning complexity, a collection of con- 
 tradictions, producing an almost impossible result by a 
 portentous conflict of chances. The parts of this appa- 
 ratus cannot have produced one another ; one part is in 
 the mother ; another part in the young one : without 
 their harmony they could not be effective ; but nothing 
 except design can operate to make them harmonious. 
 They are intended to work together; and we cannot 
 resist the conviction of this intention when the facts first 
 come before us. Perhaps there may hereafter be phy- 
 siologists who, tracing the gradual developement of the 
 parts of which we have spoken, and the analogies which 
 connect them with the, structures of other animals, may 
 think that this developement, these analogies, account 
 for the conformation we have described ; and may hence 
 think lightly of the explanation derived from the refer- 
 ence to Final Causes. Yet surely it is clear, on a calm 
 consideration of the subject, that the latter explanation 
 is not disturbed by the former ; and that the observer's 
 first impression, that this is "an irrefragable evidence 
 of creative foresight*," can never be obliterated; how- 
 ever much it may be obscured in the minds of those 
 who confuse this view by mixing it with others which 
 are utterly heterogeneous to it, and therefore cannot be 
 contradictory. 
 
 9. I have elsewhere f .remarked how physiologists, 
 who thus- look with suspicion and dislike upon the 
 introduction of Final Causes into physiology, have still 
 been unable to exclude from their speculations causes 
 of this kind. Thus Cabanis says^, "I regard with 
 the great Bacon, the philosophy of Final Causes as 
 sterile ; but I have elsewhere acknowledged that it was 
 
 * Mr. OWEN, in Phil. Trans., 1834, p. 349. 
 t Bridgewater Treatise, p. 352. 
 Rapports du Physique et dit Moral, i. 299. 
 VOL. I. W. P. S S 
 
626 PHILOSOPHY OF BIOLOGY. 
 
 very difficult for the most cautious man never to have 
 recourse to them in his explanations." Accordingly, he 
 says, " The partisans of Final Causes nowhere find argu- 
 ments so strong in favour of their way of looking at 
 nature as in the laws which preside and the circum- 
 stances of all kinds which concur in the reproduction of 
 living races. In no case do the means employed appear 
 so clearly relative to the end." And it would be easy 
 to find similar acknowledgments, express or virtual, in 
 other writers of the same kind. Thus Bichat, after 
 noting the difference between the organic sensibility by 
 which the organs are made to perform their offices, and 
 the animal sensibility of which the nervous center is the 
 seat, says*, "No doubt it will be asked, why' that is, 
 as we shall see, for what end "the organs of internal 
 life have received from nature an inferior degree of sen- 
 sibility only, and why they do not transmit to the brain 
 the impressions which they receive, while all the acts of 
 the animal life imply this transmission ? The reason is 
 simply this, that all the phenomena which establish our 
 connexions with surrounding objects ought to be, and are 
 in fact, under the influence of the will ; while all those 
 which serve for the purpose of assimilation only, escape, 
 and ought indeed to escape, such influence." The rea- 
 son here assigned is the Final Cause ; which, as Bichat 
 justly says, we cannot help asking for. 
 
 10. Again ; I may quote from the writer last men- 
 tioned another remark, which shows that in the organi- 
 cal sciences, and in them alone, the Idea of forces as 
 Means acting to an End, is inevitably assumed and ac- 
 knowledged as of supreme authority. In Biology alone, 
 observes Bichatf, have we to contemplate the state of 
 disease. "Physiology is to the movements of living 
 
 * Life and Death, (trans.) p. 32. 
 t Anatomic Generate, i. Liii. 
 
IDEA OF FINAL CAUSES. 027 
 
 bodies, what astronomy, dynamics, hydraulics, &c., are 
 to those of inert matter : but these latter sciences have 
 no branches which correspond to them as pathology 
 corresponds to physiology. For the same reason all 
 notion of a medicament is repugnant to the physical 
 sciences. A medicament has for its object to bring the 
 properties of the system back to their natural type ; but 
 the physical properties never depart from this type, and 
 have no need to be brought back to it : and thus there 
 is nothing in the physical sciences which holds the place 
 of therapeutick in physiology." Or, as we might express 
 it otherwise, of inert forces we have no conception of 
 what they ought to do, except what they do. The forces 
 of gravity, elasticity, affinity, never act in a diseased 
 manner ; we never conceive them as failing in their pur- 
 pose ; for we do not conceive them as having any pur- 
 pose which is answered by one mode of their action 
 rather than another. But with organical forces the case 
 is different ; they are necessarily conceived as acting for 
 the preservation and developement of the system in 
 which they reside. If they do not do this, they fail, they 
 are deranged, diseased. They have for their object to 
 conform the living being to a certain type ; and if they 
 cause or allow it to deviate from this type, their action 
 is distorted, morbid, contrary to the ends of nature. 
 And thus this conception of organized beings as sus- 
 ceptible of disease, implies the recognition of a state of 
 health, and of the organs and the vital forces as means 
 for preserving this normal condition. The state of 
 health and of perpetual developement is necessarily con- 
 templated as the Final Cause of the processes and 
 powers with which the different parts of plants and ani- 
 mals are endowed. 
 
 11. This Idea of a Final Cause is applicable as a 
 fundamental and regulative idea to our speculations 
 
 SS 2 
 
628 PHILOSOPHY OF BIOLOGY. 
 
 concerning organized creatures only. That there is a 
 purpose in many other parts of the creation, we find 
 abundant reason to believe, from the arrangements and 
 laws which prevail around us. But this persuasion is 
 not to be allowed to regulate and direct our reasonings 
 with regard to inorganic matter, of which conception 
 the relation of means and end forms no essential part. 
 In mere Physics, Final Causes, as Bacon has observed, 
 are not to be admitted as a principle of reasoning. But 
 in the organical sciences, the assumption of design and 
 purpose in every part of every whole, that is, the per- 
 vading idea of Final Cause, is the basis of sound reason- 
 ing and the source of true doctrine. 
 
 12. The Idea of Final Cause, of end, purpose, design, 
 intention, is altogether different from the Idea of Cause, 
 as Efficient Cause, which we formerly had to consider ; 
 and on this account the use of the word Cause in this 
 phrase has been objected to. If the idea be clearly 
 entertained and steadily applied, the word is a question 
 of subordinate importance. The term Final Cause has 
 been long familiarly used, and appears not likely to lead 
 to confusion. 
 
 13. The consideration of Final Causes, both in phy- 
 siology and in other subjects, has at all times attracted 
 much attention, in consequence of its bearing upon the 
 belief of an Intelligent Author of the Universe. I do 
 not intend, in this place, to pursue the subject far in this 
 view: but there is one antithesis of opinion, already 
 noticed in the History of Physiology, on which I will 
 again make a few remarks 4 ". 
 
 It has appeared to some persons that the mere aspect 
 of order and symmetry in the works of nature the 
 contemplation of comprehensive and consistent law is 
 
 * Hist. Ind. Sci. B. xvn. chap. viii. On the Doctrine of Final 
 Causes in Physiology. 
 
IDEA OF FINAL CAUSES. 629 
 
 sufficient to lead us to the conception of a design and 
 intelligence producing the order and carrying into effect 
 the law. Without here attempting to decide whether 
 this is true, we may discern, after what has been said, 
 that the conception of Design, arrived at in this manner, 
 is altogether different from that Idea of Design which 
 is suggested to us by organized bodies, and which we 
 describe as the doctrine of Final Causes. The regular 
 form of a crystal, whatever beautiful symmetry it may 
 exhibit, whatever general laws it may exemplify, does 
 not prove design in the same manner in which design is 
 proved by the provisions for the preservation and growth 
 of the seeds of plants, and of the young of animals. 
 The law of universal gravitation, however wide and sim- 
 ple, does not impress us with the belief of a purpose, as 
 does that propensity by which the two sexes of each 
 animal are brought together. If it could be shown that 
 the symmetrical structure of a flower results from laws 
 of the same kind as those which determine the regular 
 forms of crystals, or the motions of the planets, the dis- 
 covery might be very striking and important, but it 
 would not at all come under our idea of Final Cause. 
 
 14. Accordingly, there have been, in modern times, 
 two different schools of physiologists, the one proceeding 
 upon the idea of Final Causes, the other school seeking 
 in the realm of organized bodies wide laws and analogies 
 from which that idea is excluded. All the great biolo- 
 gists of preceding times, and some of the greatest of 
 modern times, have belonged to the former school ; and 
 especially Cuvier, who may be considered as the head of 
 it. It was solely by the assiduous application of this 
 principle of Final Cause, as he himself constantly de- 
 clared, that he was enabled to make the discoveries 
 which have rendered his name so illustrious, and which 
 contain a far larger portion of important anatomical 
 
630 PHILOSOPHY OF BIOLOGY. 
 
 and biological truth than it ever before fell to the lot of 
 one man to contribute to the science. 
 
 The opinions which have been put in opposition to 
 the principle of Final Causes have, for the most part, 
 been stated vaguely and ambiguously. Among the most 
 definite of such principles, is that which, in the History 
 of the subject, I have termed the Principle of metamor- 
 phosed and developed Symmetry, upon which has been 
 founded the science of Morphology. 
 
 The reality and importance of this principle are not 
 to be denied by us : we have shown how they are proved 
 by its application in various sciences, and especially in 
 botany. But those advocates of this principle who have 
 placed it in antithesis to the doctrine of Final Causes, 
 have, by this means, done far more injustice to their own 
 favourite doctrine than damage to the one which they 
 opposed. The adaptation of the bones of the skeleton 
 to the muscles, the provision of fulcrums, projecting pro- 
 cesses, channels, so that the motions and forces shall 
 be such as the needs of life require, cannot possibly 
 become less striking and convincing, from any discovery 
 of general analogies of one animal frame with another, 
 or of laws connecting the developement of different parts. 
 Whenever such laws are discovered, we can only consider 
 them as the means of producing that adaptation which 
 we so much admire. Our conviction that the Artist 
 works intelligently, is not destroyed, though it may be 
 modified and transferred, when we obtain a sight of his 
 tools. Our discovery of laws cannot contradict our per- 
 suasion of ends; our Morphology cannot prejudice our 
 Teleology. 
 
 15. The irresistible and constant apprehension of a 
 purpose in the forms and functions of animals has intro- 
 duced into the writings of speculators on these subjects 
 various forms of expression, more or less precise, more 
 
IDEA OF FINAL CAUSES. 631 
 
 or less figurative ; as, that " animals are framed with a 
 view to the part which they have to play;" that " nature 
 does nothing in vain ;" that " she employs the best means 
 for her ends;" and the like. However metaphorical 
 or inexact any of these phrases may be in particular, 
 yet taken altogether, they convey, clearly and definitely 
 enough to preclude any serious errour, a principle of 
 the most profound reality and of the highest import- 
 ance in the organical sciences. But some adherents of 
 the morphological school of which I have spoken reject, 
 and even ridicule, all such modes of expression. " I 
 know nothing,' 1 says M. Geoffrey Saint Hilaire, " of ani- 
 mals which have to play a part in nature. I cannot 
 make of nature an intelligent being who does nothing in 
 vain ; who acts by the shortest mode ; who does all for 
 the best." The philosophers of this school, therefore, 
 do not, it would seem, feel any of the admiration which 
 is irresistibly excited in all the rest of mankind at the 
 contemplation of the various and wonderful adaptations 
 for the preservation, the enjoyment, the continuation of 
 the creatures which people the globe ; at the survey of 
 the mechanical contrivances, the chemical agencies, the 
 prospective arrangements, the compensations, the minute 
 adaptations, the comprehensive interdependencies, which 
 zoology and physiology have brought into view, more 
 and more, the further their researches have been carried. 
 Yet the clear and deep-seated conviction of the reality 
 of these provisions, which the study of anatomy pro- 
 duces in its most profound and accurate cultivators, 
 cannot be shaken by any objections to the metaphors 
 or terms in which this conviction is clothed. In regard 
 to the Idea of a Purpose in organization, as in regard 
 to any other idea, we cannot fully express our meaning 
 by phrases borrowed from any extraneous source ; but 
 that impossibility arises precisely from the circumstance 
 
632 PHILOSOPHY OF BIOLOGY. 
 
 of its being a Fundamental Idea which is inevitably 
 assumed in our representation of each special fact. The 
 same objection has been made to the idea of mechanical 
 force, on account of its being often expressed in meta- 
 phorical language ; for writers have spoken of an energy, 
 effort, or solicitation to motion ; and bodies have been 
 said to be animated by a force. Such language, it has 
 been urged, implies volition, and the act of animated 
 beings. But the idea of Force as distinct from mere 
 motion, as the Cause of motion, or of tendency to 
 motion, is not on that account less real. We endea- 
 vour in vain to conduct our mechanical reasonings with- 
 out the aid of this idea, and must express it as we can. 
 Just as little can we reason concerning organized beings 
 without assuming that each part has its function, each 
 function its purpose; and so far as our phrases imply 
 this, they will not mislead us, however inexact, or how- 
 ever figurative they be. 
 
 16. The doctrine of a purpose in Organization has 
 been sometimes called the doctrine of the Conditions of 
 Existence; and has been stated as teaching that each 
 animal must be so framed as to contain in its structure 
 the Conditions which its existence requires. When ex- 
 pressed in this manner, it has given rise to the objection, 
 that it merely offers an identical proposition ; since no 
 animal can exist without such conditions. But in reality, 
 such expressions as those just quoted give an inade- 
 quate statement of the Principle of a Final Cause. For 
 we discover in innumerable cases, arrangements in an 
 animal, of which we see, indeed, that they are subser- 
 vient to its well being; but the nature of which we 
 never should have been able at all to conjecture, from 
 considering what was necessary to its existence, and 
 which strike us, no less by their unexpectedness than by 
 their adaptation : so far are they from being presented 
 
IDEA OF FINAL CAUSES. 633 
 
 by any perceptible necessity. Who would venture to 
 say that the trochlear muscle, or the power of articulate 
 speech, must occur in man, because they are the neces- 
 sary conditions of his existence? When, indeed, the 
 general scheme and mode of being of an animal are 
 known, the expert and profound anatomist can reason 
 concerning the proportions and form of its various parts 
 and organs, and prove in some measure what their rela- 
 tions must be. We can assert, with Cuvier, that certain 
 forms of the viscera require certain forms of the teeth, 
 certain forms of the limbs, certain powers of the senses. 
 But in all this, the functions of self-nutrition and diges- 
 tion are supposed already existing as ends : and it being 
 taken for granted, as the only conceivable basis of rea- 
 soning, that the organs are means to these ends, we 
 may discover what modifications of these organs are 
 necessarily related to and connected with each other. 
 Instead of terming this rule of speculation merely " the 
 Principle of the Conditions of Existence," we might 
 term it " the Principle of the conditions of organs as 
 Means adapted to animal existence as their End" And 
 how far this principle is from being a mere barren truism, 
 the extraordinary discoveries made by the great assertor 
 of the principle, and universally assented to by natu- 
 ralists, abundantly prove. The vast extinct creation 
 which is recalled to life in Cuvier's great work, the 
 Ossemens Fossiles, cannot be the consequence of a mere 
 identical proposition. 
 
 1 7. It has been objected, also, that the doctrine of 
 Final Causes supposes us to be acquainted with the 
 intentions of the Creator ; which, it is insinuated, is a 
 most presumptuous and irrational basis for our reason- 
 ings. But there can be nothing presumptuous or irra- 
 tional in reasoning on that basis, which if we reject, we 
 cannot reason at all. If men really can discern, and 
 
634 PHILOSOPHY OF BIOLOGY. 
 
 cannot help discerning, a design in certain portions of 
 the works of creation, this perception is the soundest 
 and most satisfactory ground for the convictions to which 
 it leads. The Ideas which we necessarily employ in the 
 contemplation of the world around us, afford us the 
 only natural means of forming any conception of the 
 Creator and Governor of the Universe ; and if we are by 
 such means enabled to elevate our thoughts, however 
 inadequately, towards Him, where is the presumption of 
 doing so ? or rather, where is the wisdom of refusing to 
 open our minds to contemplations so animating and ele- 
 vating, and yet so entirely convincing ? We possess the 
 ideas of Time and Space, under which all the objects of 
 the universe present themselves to us ; and in virtue of 
 these ideas thus possessed, we believe the Creator to be 
 eternal and omnipotent. When we find that we, in like 
 manner, possess the idea of a Design in Creation, and 
 that with regard to ourselves, and creatures more or less 
 resembling ourselves, we cannot but contemplate their 
 constitution under this idea, we cannot abstain from 
 ascribing to the Creator the infinite profundity and 
 extent of design to which all these special instances 
 belong as parts of a whole. 
 
 18. I have here considered Design as manifest in 
 organization only : for in that field of speculation it is 
 forced upon us as contained in all the phenomena, and as 
 the only mode of our understanding them. The exist- 
 ence of Final Causes has often been pointed out in other 
 portions of the creation ; for instance, in the apparent 
 adaptations of the various parts of the earth and of the 
 solar system to each other and to organized beings. In 
 these provinces of speculation, however, the principle of 
 Final Causes is no longer the basis and guide, but the 
 sequel and result of our physical reasonings. If in look- 
 ing at the universe, we follow the widest analogies of 
 
IDEA OF FINAL CAUSES. 635 
 
 which we obtain a view, we see, however dimly, reason 
 to believe that all its laws are adapted to each other, 
 and intended to work together for the benefit of its 
 organic population, and for the general welfare of its 
 rational tenants. On this subject, however, not imme- 
 diately included in the principle of Final Causes as here 
 stated, I shall not dwell. I will only make this remark; 
 that the assertion appears to be quite unfounded, that 
 as science advances from point to point, final causes 
 recede before it, and disappear one after the other. The 
 principle of design changes its mode of application indeed, 
 but it loses none of its force. We no longer consider 
 particular facts as produced by special interpositions, 
 but we consider design as exhibited in the establishment 
 and adjustment of the laws by which particular facts 
 are produced. We do not look upon each particular 
 cloud as brought near us that it may drop fatness on our 
 fields ; but the general adaptation of the laws of heat, 
 and air, and moisture, to the promotion of vegetation, 
 does not become doubtful. We do not consider the 
 sun as less intended to warm and vivify the tribes of 
 plants and animals, because we find that, instead of re- 
 volving round the earth as an attendant, the earth along 
 with other planets revolves round him. We are rather, 
 by the discovery of the general laws of nature, led into 
 a scene of wider design, of deeper contrivance, of more 
 comprehensive adjustments. Final causes, if they appear 
 driven further from us by such an extension of our 
 views, embrace us only with a vaster and more majestic 
 circuit : instead of a few threads connecting some de- 
 tached objects, they become a stupendous net-work, 
 which is wound round and round the universal frame of 
 things. 
 
 19. I now quit the subject of Biology, and with it the 
 circle of sciences depending upon separate original Ideas 
 
636 PHILOSOPHY OF BIOLOGY. 
 
 and permanent relations. If from the general relations 
 which permanently prevail and constantly recur among 
 the objects around us, we turn to the inquiry of what 
 has actually happened, if from Science we turn to His- 
 tory, we find ourselves in a new field. In this region 
 of speculation we can rarely obtain a complete and 
 scientific view of the connexion between objects and 
 events. The past History of Man, of the Arts, of Lan- 
 guages, of the Earth, of the Solar System, offers a vast 
 series of problems, of which perhaps not one has been 
 rigorously solved. Still man, as his speculative powers 
 unfold themselves, cannot but feel prompted and invited 
 to employ his thoughts even on these problems. He 
 cannot but wish and endeavour to understand the con- 
 nexion between the successive links of such chains of 
 events. He attempts to form a Science which shall be 
 applicable to each of these Histories; and thus he begins 
 to construct the class of sciences to which I now, in the 
 last place, proceed. 
 
637 
 
 BOOK X, 
 
 THE PHILOSOPHY OF PALMTIOLOGY. 
 
 CHAPTER I. 
 OF PAL^ETIOLOGICAL SCIENCES IN GENERAL. 
 
 1. I HAVE already stated in the History of the 
 Sciences*, that the class of Sciences which I designate 
 as Palcetiological are those in which the object is to 
 ascend from the present state of things to a more ancient 
 condition, from which the present is derived by intel- 
 ligible causes. As conspicuous examples of this class 
 we may take Geology, Glossology or Comparative Phi- 
 lology, and Comparative Archaeology. These provinces 
 of knowledge might perhaps be intelligibly described as 
 Histories; the History of the Earth, the History of 
 Languages, the History of Arts. But these phrases 
 would not fully describe the sciences we have in view ; 
 for the object to which we now suppose their investiga- 
 tions to be directed is, not merely to ascertain what the 
 series of events has been, as in the common forms of 
 History, but also how it has been brought about. These 
 sciences are to treat of causes as well as of effects. Such 
 researches might be termed Philosophical History ; or, 
 in order to mark more distinctly that the causes of 
 events are the leading object of attention, sEtiological 
 History. But since it will be more convenient to de- 
 scribe this class of sciences by a single appellation, I 
 
 * B. XVTTT. Introd. 
 
638 THE PHILOSOPHY OF PALJETIOLOGY. 
 
 have taken the liberty of proposing to call them* the 
 Palcetiological Sciences. 
 
 While Palaeontology describes the beings which have 
 lived in former ages without investigating their causes, 
 and ^Etiology treats of causes without distinguishing 
 historical from mechanical causation ; Palcetiology is a 
 combination of the two sciences ; exploring, by means 
 of the second, the phenomena presented by the first. 
 The portions of knowledge which I include in this term 
 are palseontological setiological sciences. 
 
 2. All these sciences are connected by this bond ; 
 that they all endeavour to ascend to a past state, by 
 considering what is the present state of things, and what 
 are the causes of change. Geology examines the exist- 
 ing appearance of the materials which form the earth, 
 infers from them previous conditions, and speculates 
 concerning the forces by which one condition has been 
 made to succeed another. Another science, cultivated 
 with great zeal and success in modern times, compares 
 the languages of different countries and nations, and by 
 an examination of their materials and structure, endea- 
 vours to determine their descent from one another : this 
 science has been termed Comparative Philology, or Eth- 
 nography ; and by the French, Linguistique, a word 
 which we might imitate in order to have a single name 
 for the science, but the Greek derivative Glossology ap- 
 pears to be more convenient in its form. The progress 
 of the Arts (Architecture and the like) ; how one stage 
 of the culture produced another ; and how far we can 
 
 * A philological writer, in a very interesting work, (Mr. Donaldson, 
 in his New Cratylus, p. 12) expresses his dislike of this word, and 
 suggests that I must mean palw-cetiological. I think the word is more 
 likely to obtain currency in the more compact and euphonious form in 
 which I have used it. It has been adopted by Mr. Winning, in his 
 Manual of Comparative Philology, and more recently, by other writers. 
 
OF PAL^ETIOLOGICAL SCIENCES IN GENERAL. 639 
 
 trace their maturest and most complete condition to their 
 earliest form in various nations ; are problems of great 
 interest belonging to another subject, which we may for 
 the present term Comparative Archaeology. I have 
 already noticed, in the History*, how the researches 
 into the origin of natural objects, and those relating to 
 works of art, pass by slight gradations into each other ; 
 how the examination of the changes which have affected 
 an ancient temple or fortress, harbour or river, may con- 
 cern alike the geologist and the antiquary. Cuvier's 
 assertion that the geologist is an antiquary of a new 
 order, is perfectly correct, for both are palsetiologists. 
 
 3. We are very far from having exhausted, by this 
 enumeration, the class of sciences which are thus con- 
 nected. We may easily point out many other subjects 
 of speculation of the same kind. As we may look back 
 towards the first condition of our planet, we may in like 
 manner turn our thoughts towards the first condition of 
 the solar system, and try whether we can discern any 
 traces of an order of things antecedent to that which is 
 now established ; and if we find, as some great mathe- 
 maticians have conceived, indications of an earlier state 
 in which the planets were not yet gathered into their 
 present forms, we have, in the pursuit of this train of 
 research, a palsetiological portion of Astronomy. Again, 
 as we may inquire how languages, and how man, have 
 been diffused over the earth's surface from place to 
 place, we may make the like inquiry with regard to the 
 races of plants and animals, founding our inferences 
 upon the existing geographical distribution of the animal 
 and vegetable kingdoms : and thus the Geography of 
 Plants and of Animals also becomes a portion of Palae- 
 tiology. Again, as we can in some measure trace the 
 progress of Arts from nation to nation and from age 
 
 * B. xviu. Introd. 
 
640 THE PHILOSOPHY OF PAL^ETIOLOGY. 
 
 to age, we can also pursue a similar investigation with 
 respect to the progress of Mythology, of Poetry, of 
 Government, of Law. Thus the philosophical history of 
 the human race, viewed with reference to these subjects, 
 if it can give rise to knowledge so exact as to be pro- 
 perly called Science, will supply sciences belonging to 
 the class I am now to consider. 
 
 4. It is not an arbitrary and useless proceeding to 
 construct such a Class of sciences. For wide and various 
 as their subjects are, it will be found that they have all 
 certain principles, maxims, and rules of procedure in 
 common; and thus may reflect light upon each other 
 by being treated of together. Indeed it will, I trust, 
 appear, that we may by such a juxtaposition of different 
 speculations, obtain most salutary lessons. And ques- 
 tions, which, when viewed as they first present them- 
 selves under the aspect of a special science, disturb and 
 alarm men's minds, may perhaps be contemplated more 
 calmly, as well as more clearly, when they are considered 
 as general problems of palsetiology. 
 
 5. It will at once occur to the reader that, if we 
 include in the circuit of our classification such subjects 
 as have been mentioned, politics and law, mythology 
 and poetry, we are travelling very far beyond the ma- 
 terial sciences within whose limits we at the outset pro- 
 posed to confine our discussion of principles. But we 
 shall remain faithful to our original plan ; and for that 
 purpose shall confine ourselves, in this work, to those 
 palsetiological sciences which deal with material things. 
 It is true, that the general principles and maxims which 
 regulate these sciences apply also to investigations of a 
 parallel kind respecting the products which result from 
 man's imaginative and social endowments. But although 
 there may be a similarity in the general form of such 
 portions* of knowledge, their materials are so different 
 
OF PAL^ETIOLOGICAL SCIENCES IN GENERAL. 641 
 
 from those with which we have been hitherto dealing, 
 that we cannot hope to take them into our present 
 account with any profit. Language, Government, Law, 
 Poetry, Art, embrace a number of peculiar Fundamental 
 Ideas, hitherto not touched upon in the disquisitions in 
 which we have been engaged; and most of them involved 
 in far greater perplexity and ambiguity, the subject of 
 controversies far more vehement, than the Ideas we have 
 hitherto been examining. We must therefore avoid 
 resting any part of our philosophy upon sciences, or 
 supposed sciences, which treat of such subjects. To 
 attend to this caution, is the only way in which we can 
 secure the advantage we proposed to ourselves at the 
 outset, of taking, as the basis of our speculations, none 
 but systems of undisputed truths, clearly understood and 
 expressed *. We have already said that we must, know- 
 ingly and voluntarily, resign that livelier and warmer 
 interest which doctrines on subjects of Polity or Art 
 possess, and content ourselves with the cold truths of 
 the material sciences, in order that we may avoid having 
 the very foundations of our philosophy involved in con- 
 troversy, doubt, and obscurity. 
 
 6. We may remark, however, that the necessity of 
 rejecting from our survey a large portion of the researches 
 which the general notion of Palsetiology includes, sug- 
 gests one consideration which adds to the interest of 
 our task. We began our inquiry with the trust that 
 any sound views which we should be able to obtain 
 respecting the nature of Truth in the physical sciences, 
 and the mode of discovering it, must also tend to throw 
 light upon the nature and prospects of knowledge of 
 all other kinds; must be useful to us in moral, poli- 
 tical, and philological researches. We stated this as a 
 confident anticipation ; and the evidence of the justice 
 
 * See Vol. i. p. 8. 
 VOL. I. W. P. T T 
 
642 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 of our belief already begins to appear. We have seen, 
 in the last Book, that biology leads us to psychology, 
 if we choose to follow the path ; and thus the passage 
 from the material to the immaterial has already un- 
 folded itself at one point ; and we now perceive that 
 there are several large provinces of speculation which 
 concern subjects belonging to man's immaterial nature, 
 and which are governed by the same laws as sciences 
 altogether physical. It is not our business here to dwell 
 on the prospects which our philosophy thus opens to our 
 contemplation ; but we may allow ourselves, in this last 
 stage of our pilgrimage among the foundations of the 
 physical sciences, to be cheered and animated by the ray 
 that thus beams upon us, however dimly, from a higher 
 and brighter region. 
 
 But in our reasonings and examples we shall mainly 
 confine ourselves to the physical sciences ; and for the 
 most part to Geology, which in the History I have put 
 forwards as the best representative of the Palaetiological 
 Sciences. 
 
 CHAPTER II. 
 
 OF THE THREE MEMBERS OF A PALAETIO- 
 LOGICAL SCIENCE. 
 
 1. Divisions of such Sciences. IN each of the Sciences 
 of this class we consider some particular order of pheno- 
 mena now existing : from our knowledge of the causes 
 of change among such phenomena, we endeavour to infer 
 the causes which have made this order of things what it 
 is : we ascend in this manner to some previous stage 
 of such phenomena; and from that, by a similar course 
 of inference, to a still earlier stage, and to its causes. 
 
MEMBERS OF A PAL^TIOLOGICAL SCIENCE. 643 
 
 Hence it will be seen that each such science will consist 
 of two parts, the knowledge of the Phenomena, and the 
 knowledge of their Causes. And such a division is, in 
 fact, generally recognized in such sciences : thus we have 
 History, and the Philosophy of History ; we have Com- 
 parison of Languages, and the Theories of the Origin and 
 Progress of Language ; we have Descriptive Geology, 
 and Theoretical or Physical Geology. In all these cases, 
 the relation between the two parts in these several 
 provinces of knowledge is nearly the same ; and it may, 
 on some occasions at least, be useful to express the dis- 
 tinction in a uniform or general manner. The investiga- 
 tion of causes has been termed ^Etiology by philosophical 
 writers, and this term we may use, in contradistinction 
 to the mere Phenomenology of each such department of 
 knowledge. And thus we should have Phenomenal Geo- 
 logy and ^tiological Geology, for the two divisions of 
 the science which we have above termed Descriptive 
 and Theoretical Geology. 
 
 2. The Study of Causes. But our knowledge respect- 
 ing the causes which actually have produced any order of 
 phenomena must be arrived at by ascertaining what the 
 causes of change in such matters can do. In order to 
 learn, for example, what share earthquakes, and volcanoes, 
 and the beating of the ocean against its shores, ought to 
 have in our Theory of Geology, we must make out what 
 effects these agents of change are able to produce. And 
 this must be done, not hastily, or unsystematically, but 
 in a careful and connected manner; in short, this study of 
 the causes of change in each order of phenomena must 
 become a distinct body of Science, which must include a 
 large amount of knowledge, both comprehensive and 
 precise, before it can be applied to the construction of a 
 theory. We must have an ^Etiology corresponding to 
 each order of phenomena. 
 
 T T 2 
 
644: PHILOSOPHY OF PAL^TIOLOGY. 
 
 3. ^Etiology. In the History of Geology, I have 
 spoken of the necessity for such an ^Etiology with regard 
 to geological phenomena : this necessity I have compared 
 with that which, at the time of Kepler, required the 
 formation of a separate science of Dynamics, (the doc- 
 trine of the causes of motion,) before Physical Astronomy 
 could grow out of Phenomenal Astronomy. In pursuance 
 of this analogy, I have there given the name of Geological 
 Dynamics to the science which treats of the causes of 
 geological change in general. But, as I have there inti- 
 mated, in a large portion of the subject the changes are 
 so utterly different in their nature from any modification 
 of motion, that the term Dynamics, so applied, sounds 
 harsh and strange. For in this science we have to treat, 
 not only of the subterraneous forces by which parts of the 
 earth's crust are shaken, elevated, or ruptured, but also 
 of the causes which may change the climate of a portion 
 of the earth's surface, making a country hotter or colder 
 than in former ages ; again, we have to treat of the 
 causes which modify the forms and habits of animals 
 and vegetables, and of the extent to which the effects of 
 such causes can proceed ; whether, for instance, they can 
 extinguish old species and produce new. These and 
 other similar investigations would not be naturally in- 
 cluded in the notion of Dynamics; and therefore it 
 might perhaps be better to use the term ^Etiology when 
 we wish to group together all those researches which 
 have it for their object to determine the laws of such 
 changes. In the same manner the Comparison and 
 History of Languages, if it is to lead to any stable 
 and exact knowledge, must have appended to it an 
 ^Etiology, which aims at determining the nature and 
 the amount of the causes which really do produce 
 changes in language ; as colonization, conquest, the mix- 
 ture of races, civilization, literature, and the like. And 
 
MEMBERS OF A PALJETIOLOGICAL SCIENCE. 645 
 
 the same rule applies to all sciences of this class. We 
 shall now make a few remarks on the characteristics of 
 such branches of science as those to which we are led 
 by the above considerations. 
 
 4. Phenomenology requires Classification. Phenome- 
 nal Geology. The Phenomenal portions of each science 
 imply Classification, for no description of a large and 
 varied mass of phenomena can be useful or intelligible 
 without classification. A representation of phenomena, 
 in order to answer the purposes of science, must be sys- 
 tematic. Accordingly, in giving the History of Descrip- 
 tive or Phenomenal Geology, I have called it Systematic 
 Geology, just as Classificatory Botany is termed Systema- 
 tic Botany. Moreover, as we have already seen, Clas- 
 sification can never be an arbitrary process, but always 
 implies some natural connexion among the objects of 
 the same class ; for if this connexion did not exist, the 
 classes could not be made the subjects of any true 
 assertion. Yet though the classes of phenomena which 
 our system acknowledges must be such as already exist 
 in nature, the discovery of these classes is, for the most 
 part, very far from obvious or easy. To detect the true 
 principles of natural classes, and to select marks by 
 which these may be recognized, are steps which require 
 genius and good fortune, and which fall to the lot 
 only of the most eminent persons in each science. In 
 the History, I have pointed out Werner, William Smith, 
 and Cuvier, as the three great authors of Systematic 
 Geology of Europe. The mode of classifying the mate- 
 rials of the earth's surface which was found, by these 
 philosophers, fitted to enunciate such general facts as 
 came under their notice, was to consider the rocks and 
 other materials as divided into successive layers or strata, 
 superimposed one on another, and variously inclined and 
 broken. The German geologist distinguished his strata 
 
646 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 for the most part by their mineralogical character ; the 
 other two, by the remains of animals and plants which 
 the rocks contained. After a beginning had thus been 
 made in giving a genuine scientific form to phenomenal 
 geology, other steps followed in rapid succession, as has 
 already been related in the History*. The Classifica- 
 tion of the Strata was fixed by a suitable Nomenclature. 
 Attempts were made to apply to other countries the 
 order of strata which had been found to prevail in 
 that first studied : and in this manner it was ascer- 
 tained what rocks in distant regions are the synonyms, 
 or Equivalents -f, of each other. The knowledge thus 
 collected and systematized was exhibited in the form of 
 Geological Maps. 
 
 Moreover, among the phenomena of geology we have 
 Laws of nature as well as Classes. The general form of 
 mountain chains; the relations of the direction and incli- 
 nation of different chains to each other ; the general 
 features of mineral veins, faults, and fissures ; the preva- 
 lent characters of slaty cleavage ; were the subjects of 
 laws established, or supposed to be established, by exten- 
 sive observation of facts. In like manner the organic 
 fossils discovered in the strata were found to follow 
 certain laws with reference to the climate which they 
 appeared to have lived in ; and the evidence which they 
 gave of a regular zoological developement. And thus, by 
 the assiduous labours of many accomplished and active 
 philosophers, Descriptive or Phenomenal Geology was 
 carried towards a state of completeness. 
 
 5. Phenomenal Uranography. In like manner in 
 other palsetiological researches, as soon as they approach 
 to an exact and scientific form, we find the necessity of 
 constructing in the first place a science of classification 
 and exact description,, by means of which the pheno- 
 
 * Hist. Ind. Scl, B. xvm. c. iii. t 76., sect. 4. 
 
MEMBERS OF A PAL^TIOLOGICAL SCIENCE. 647 
 
 mena may be correctly represented and compared; and of 
 obtaining by this step a solid basis for an inquiry into the 
 causes which have produced them. Thus the Palaetiology 
 of the solar system has, in recent times, drawn the atten- 
 tion of speculators ; and a hypothesis has been started, 
 that our sun and his attendant planets have been pro- 
 duced by the condensation of a mass of diffused matter, 
 such as that which constitutes the nebulous patches 
 which we observe in the starry heavens. But the sagest 
 and most enlightened astronomers have not failed to 
 acknowledge, that to verify or to disprove this con- 
 jecture, must be the work of many ages of observation 
 and thought. They have perceived also that the first 
 step of the labour requisite for the advancement of this 
 portion of science must be to obtain and to record the 
 most exact knowledge at present within our reach, 
 respecting the phenomena of these nebulae, with which 
 we thus compare our own system ; and, as a necessary 
 element of such knowledge, they have seen the import- 
 ance of a classification of these objects, and of others, 
 such as Double Stars, of the same kind. Sir William 
 Herschel, who first perceived the bearing of the pheno- 
 mena of nebulae upon the history of the solar system, 
 made the observation of such objects his business, with 
 truly admirable zeal and skill; and in the account of 
 the results of his labours, gave a classification of Nebula; 
 separating them into, first, Clusters of Stars; second, 
 Resolvable Nebulce ; third, Proper Nebulce ; fourth, Pla- 
 netary Nebulae i fifth, Stellar Nebulce; sixth, Nebulous 
 Stars*. And since, in order to obtain from these remote 
 appearances, any probable knowledge respecting our own 
 system, we must discover whether they undergo any 
 changes in the course of ages, he devoted himself to the 
 
 * Phil. Trans. , 1786 anil 1789, and Sir J. Hem-lid's Astronomy, 
 Art. 
 
648 PHILOSOPHY OF PALJETIOLOGY. 
 
 task of forming a record of their number and appearance 
 in his own time, that thus the astronomers of succeeding 
 generations might have a definite and exact standard 
 with which to compare their observations. Still, this 
 task would have been executed only for that part of the 
 heavens which is visible in this country, if this Hippar- 
 chus of the Nebulse and Double Stars had not left behind 
 him a son who inherited all his father's zeal and more 
 than his father's knowledge. Sir John Herschel in 
 1 833 went to the Cape of Good Hope to complete what 
 Sir William Herschel left wanting ; and in the course of 
 five years observed with care all the nebula? and double 
 stars of the Southern hemisphere. This great Herschelian 
 Survey of the Heavens, the completion of which is the 
 noblest monument ever erected by a son to a father, must 
 necessarily be, to all ages, the basis of all speculations 
 concerning the history and origin of the solar system ; 
 and has completed, so far as at present it can be com- 
 pleted, the phenomenal portion of Astronomical Palse- 
 tiology. 
 
 6. Phenomenal Geography of Plants and Animals. 
 Again, there is another Palsetiological Science, closely 
 connected with the speculations forced upon the geolo- 
 gist by the organic fossils which he discovers imbedded 
 in the strata of the earth ; namely, the Science which 
 has for its object the Causes of the Diffusion and Distri- 
 bution of the various kinds of Plants and Animals. And 
 the science also has for its first portion and indispensable 
 foundation a description and classification of the existing 
 phenomena. Such portions of science have recently been 
 cultivated with great zeal and success, under the titles of 
 the Geography of Plants, and the Geography of Animals. 
 And the results of the inquiries thus undertaken have 
 assumed a definite and scientific form by leading to a 
 division of the earth's surface into a certain number of 
 
MEMBERS OF A PAL^TIOLOGICAL SCIENCE. G49 
 
 botanical and zoological Provinces, each province occu- 
 pied by its own peculiar vegetable and animal population. 
 We find, too, in the course of these investigations, various 
 general laws of the phenomena offered to our notice ; 
 such, for instance, as this : that the difference of the 
 animals originally occupying each province, which is clear 
 and entire for the higher orders of animals and plants,* 
 becomes more doubtful and indistinct when we descend 
 to the lower kinds of organizations; as Infusoria and 
 Zoophytes* in the animal kingdom, Grasses and Mosses 
 among vegetables. Again, other laws discovered by 
 those who have studied the geography of plants are 
 these : that countries separated from each other by 
 wide tracts of sea, as the opposite shores of the Medi- 
 terranean, the islands of the Indian and Pacific Oceans, 
 have usually much that is common in their vegetation : 
 and again, that in parallel climates, analogous tribes 
 replace each other. It would be easy to adduce other 
 laws, but those already stated may serve to show the 
 great extent of the portions of knowledge which have 
 just been mentioned, even considered as merely Sciences 
 of Phenomena. 
 
 7. Phenomenal Glossology. It is not my purpose in 
 the present work to borrow my leading illutsrations from 
 any portions of knowledge but those which are concerned 
 with the study of material nature ; and I shall, therefore, 
 not dwell upon a branch of research, singularly interest- 
 ing, and closely connected with the one just mentioned, 
 but dealing with relations of thought rather than of 
 things ; I mean the Palaetiology of Language ; the 
 theory, so far as the facts enable us to form a theory, of 
 the causes which have led to the resemblances and differ- 
 ences of human speech in various regions and various 
 
 * Frichard, Researches into the Phi/steal History of Mankind, 
 i. 55, 28. 
 
650 PHILOSOPHY OF PAUETIOLOGY. 
 
 ages. This, indeed, would be only a portion of the study 
 of the history and origin of the diffusion of animals, if we 
 were to include man among the animals whose dispersion 
 we thus investigate ; for language is one of the most 
 clear and imperishable records of the early events in the 
 career of the human race. But the peculiar nature of 
 the faculty of speech, and the ideas which the use of it 
 involves, make it proper to treat Glossology as a distinct 
 science. And of this science, the first part must neces- 
 sarily be, as in the other sciences of this order, a classi- 
 fication and comparison of languages governed in many 
 respects by the same rules, and presenting the same diffi- 
 culties, as other sciences of classification. Such, accord- 
 ingly, has been the procedure of the most philosophical 
 glossologists. They have been led to throw the languages 
 of the earth into certain large classes or Families, ac- 
 cording to various kinds of resemblance ; as the Semitic 
 Family, to which belong Hebrew, Arabic, Chaldean, 
 Syrian, Phoenician, Ethiopian, and the like; the Indo- 
 European, which includes Sanskrit, Persian, Greek, Latin, 
 and German ; the Monosyllabic languages, Chinese, Tibe- 
 tan, Birman, Siamese ; the Poll/synthetic languages, a 
 class including motet of the North- American Indian 
 dialects; and others. And this work of classification 
 has been the result of the labour and study of many very 
 profound linguists, and has advanced gradually from step 
 to step. Thus the Indo-European Family was first formed 
 on an observation of the coincidences between Sanskrit, 
 Greek, and Latin ; but it was soon found to include the 
 Teutonic languages, and more recently Dr. Prichard* 
 has shown beyond doubt that the Celtic must be in- 
 cluded in the same Family. Other general resemblances 
 and differences of languages have been marked by appro- 
 
 * Dr. Prichard, On the Eastern Origin o/' the Celtic Nations. 
 1831. 
 
MEMBERS OF A PAL^ETIOLOGICAL SCIENCE. 651 
 
 priate terms : thus August von Schlegel has denominated 
 them synthetical and analytical, according as they form 
 their conjugations and declensions by auxiliary verbs and 
 prepositions, or by changes in the word itself: and the 
 polysynthetic languages are so named by M. Duponceau, 
 in consequence of their still more complex mode of 
 inflexion. Nor are there wanting, in this science also, 
 general laws of phenomena; such, for instance, is the 
 curious rule of the interchange of consonants in the 
 cognate words of Greek, Gothic, and German, which has 
 been discovered by James Grimm. All these remark- 
 able portions of knowledge, and the great works which 
 have appeared on Glossology, such, for example, as the 
 Mithridates of Adelung and Vater, contain, for their 
 largest, and hitherto probably their most valuable part, 
 the phenomenal portion of the science, the comparison 
 of languages as they now are. And beyond all doubt, 
 until we have brought this comparative philology to a 
 considerable degree of completeness, all our speculations 
 respecting the causes which have operated to produce 
 the languages of the earth must be idle and unsubstantial 
 dreams. 
 
 Thus in all Palsetiological Sciences, in all attempts to 
 trace back the history and discover the origin of the 
 present state of things, the portion of the science which 
 must first be formed is that which classifies the pheno- 
 mena, and discovers general laws prevailing among them. 
 When this work is performed, and not till then, we 
 may begin to speculate successfully concerning causes, 
 and to make some progress in our attempts to go back 
 to an origin. We must have a Phenomenal science pre- 
 paratory to each /Etiological one. 
 
 8. The Study of Phenomena leads to Theory. As 
 we have just said, we cannot, in any subject, speculate 
 successfully concerning the causes of the present state of 
 
652 PHILOSOPHY OF PAL^TIOLOGY. 
 
 things, till we have obtained a tolerably complete and 
 systematic view of the phenomena. Yet in reality men 
 have not in any instance waited for this completeness 
 and system in their knowledge of facts before they have 
 begun to form theories. Nor was it natural, consider- 
 ing the speculative propensities of the human mind, and 
 how incessantly it is endeavouring to apply the Idea of 
 Cause, that it should thus restrain itself. I have already 
 noticed this in the History of Geology. " While we 
 have been giving an account," it is there said, "of the 
 objects with which Descriptive Geology is occupied, it 
 must have been felt how difficult it is, in contemplating 
 such facts, to confine ourselves to description and classi- 
 fication. Conjectures and reasonings respecting the causes 
 of the phenomena force themselves upon us at every 
 step ; and even influence our classification and nomen- 
 clature. Our Descriptive Geology impels us to construct 
 a Physical Geology." And the same is the case with 
 regard to the other subjects which I have mentioned. 
 The mere consideration of the different degrees of con- 
 densation of different nebula? led Herschel and Laplace 
 to contemplate the hypothesis that our solar system is 
 a condensed nebula. Immediately upon the division of 
 the earth's surface into botanical and zoological pro- 
 vinces, and even at an earlier period, the opposite hypo- 
 theses of the origin of all the animals of each kind from 
 a single pair, and of their original diffusion all over the 
 earth, were under discussion. And the consideration of 
 the families of languages irresistibly led to speculations 
 concerning the families of the earliest human inhabit- 
 ants of the earth. In all cases the contemplation of a 
 very few phenomena, the discovery of a very few steps 
 in the history, made men wish for and attempt to form 
 a theory of the history from the very beginning of things. 
 9. No sound Theory without ^Etiology. But though 
 
MEMBERS OF A PAL^ITIOLOGICAL SCIENCE. 653 
 
 man is thus impelled by the natural propensities of his 
 intellect to trace each order of things to its causes, he 
 does not at first discern the only sure way of obtaining 
 such knowledge : he does not suspect how much labour 
 and how much method are requisite for success in this 
 undertaking: he is not aware that for each order of 
 phenomena he must construct, by the accumulated re- 
 sults of multiplied observation and distinct thought, a 
 separate ^Etiology. Thus, as I have elsewhere remarked*, 
 when men had for the first time become acquainted 
 with some of the leading phenomena of Geology, and 
 had proceeded to speculate concerning the past changes 
 and revolutions by ,which such results had been pro- 
 duced, they forthwith supposed themselves able to judge 
 what would be the effects of any of the obvious agents 
 of change, as water or volcanic fire. It did not at first 
 occur to them to suspect that their common and ex- 
 temporaneous judgment on such points was by no means 
 sufficient for sound knowledge. They did not foresee 
 that, before they could determine what share these or 
 any other causes had had in producing the present con- 
 dition of the earth, they must create a special science 
 whose object should be to estimate the general laws and 
 effects of such assumed causes ; that before they could 
 obtain any sound Geological Theory, they must care- 
 full cultivate Geological ^Etiology. 
 
 The same disposition to proceed immediately from 
 the facts to the theory, without constructing, as an inter- 
 mediate step, a science of Causes, might be pointed out 
 in the other sciences of this order. But in all of them 
 this errour has been corrected by the failures to which 
 it led. It soon appeared, for instance, that a more 
 careful inquiry into the effects which climate, food, habit 
 and circumstances can produce in animals, was requisite 
 
 * Hist. Ind. Sci., B. xvm. c. v. sect. 1, 
 
654 PHILOSOPHY OF PAL^TIOLOGY. 
 
 in order to determine how the diversities of animals in 
 different countries have originated. The ^Etiology of 
 Animal Life (if we may be allowed to give this name to 
 that study of such causes of change which is at present 
 so zealously cultivated, and which yet has no distinctive 
 designation, except so far as it coincides with the Or- 
 ganic Geological Dynamics of our History), is now per- 
 ceived to be a necessary portion of all attempts to 
 construct a history of the earth and its inhabitants. 
 
 10. Cause, in Palcetiology. We are thus led to con- 
 template a class of sciences which are commenced with 
 the study of Causes. We have already considered sci- 
 ences which depended mainly upon the Idea of Cause, 
 namely, the Mechanical Sciences. But it is obvious that 
 the Idea of Cause in the researches now under our con- 
 sideration must be employed in a very different way 
 from that in which we applied it formerly. Force is the 
 cause of motion, because force at all times and under 
 all circumstances, if not counteracted, produces motion ; 
 but the cause of the present condition and elevation of 
 the Alps, whatever it was, was manifested in a series of 
 events of which each happened but once, and occupied 
 its proper place in the series of time. The former is 
 mechanical, the latter historical, cause. In our present 
 investigations, we consider the events which we contem- 
 plate, of whatever order they be, as forming a chain 
 which is extended from the beginning of things down to 
 the present time ; and the causes of which we now 
 speak are those which connect the successive links of 
 this chain. Every occurrence which has taken place in 
 the history of the solar system, or the earth, or its veget- 
 able and animal creation, or man, has been at the same 
 time effect and cause ; the effect of what preceded, the 
 cause of what succeeded. By being effect and cause, it 
 has occupied some certain portion of time; and the times 
 
MEMBERS OF A PAL^ETIOLOGICAL SCIENCE. 655 
 
 which have thus been occupied by effects and causes, 
 summed up and taken altogether, make up the total 
 of Past Time. The Past has been a series of events con- 
 nected by this historical causation, and the Present is 
 the last term of this series. The problem in the Palse- 
 tiological Sciences, with which we are here concerned, 
 is, to determine the manner in which each term is derived 
 from the preceding, and thus, if possible, to calculate 
 backwards to the origin of the series. 
 
 11. Various kinds of Cause. Those modes by which 
 one term in the natural series of events is derived from 
 another, the forms of historical causation, the kinds 
 of connexion between the links of the infinite chain of 
 time, are very various; nor need we attempt to enume- 
 rate them. But these kinds of causation being distin- 
 guished from each other, and separately studied, each 
 becomes the subject of a separate ^Etiology. Thus the 
 causes of change in the earth's surface, residing in the 
 elements, fire and water, form the main subject of Geolo- 
 gical ^Etiology. The ^Etiology of the vegetable and animal 
 kingdoms investigates the causes by which the forms and 
 distribution of species of plants and animals are affected. 
 The study of causes in Glossology leads to an ^Etiology 
 of Language, which shall distinguish, analyze, and esti- 
 mate the causes by which certain changes are produced in 
 the languages of nations ; in like manner we may expect 
 to have an ^Etiology of Art, which shall scrutinize the 
 influences by which the various forms of art have each 
 given birth to its successor: by which, for example, 
 there have been brought into being those various forms 
 of architecture which we term Egyptian, Doric, Ionic, 
 Roman, Byzantine, Romanesque, Gothic, Italian, Eliza- 
 bethan. It is easily seen by this slight survey how 
 manifold and diverse are the kinds of cause which the 
 Palsetiological Sciences bring under our consideration. 
 
<;f><; PHILOSOPHY OK i'Ai,,KTiom<;y. 
 
 But in each of those sciences we shall obtain solid and 
 complete systems of knowledge, only so far as we study, 
 with steady thought and careful observation, that pecu- 
 liar kind of cause which is appropriate to the pheno- 
 mena under our consideration. 
 
 12. Hypothetical Order of Pal&tiological Causes. 
 The various kinds of historical cause are not only con- 
 nected with each other by their common bearing upon 
 the historical sciences, but they form a kind of progres- 
 sion which we may represent to ourselves as having 
 acted in succession in the hypothetical history of the 
 earth and its inhabitants. Thus assuming, merely as a 
 momentary hypothesis, the origin of the solar system 
 by the condensation of a nebula, we have to contemplate, 
 lirst, the causes by which the luminous incandescent 
 diffused mass of which a nebula is supposed to be con- 
 stituted, is gradually condensed, cooled, collected into 
 definite masses, solidified, and each portion made 1 to 
 revolve about its axis, and the whole to travel about 
 another body. We have no difficulty in ascribing the 
 globular form of each mass to the mutual attraction of 
 its particles: but when this form was once assumed, and 
 covered with a solid crust, are there, we may ask, in 
 the constitution of such a body, any causes at work by 
 which the crust might be again broken np and portions 
 of it displaced, and covered with other matter? Again, 
 if we can thus explain the origin of the earth, can we 
 with like success account for the presence of the atmo- 
 sphere and the waters of earth and ocean f . Supposing 
 this done, we have then to consider by what causes such 
 a body could become stocked with vegetable and animal 
 life; for there have not been wanting persons, extra- 
 vagant speculators, no doubt, who have conceived that 
 even this event in the history of the world might be the 
 work of natural causes. Supposing an origin given to 
 
MEMHEKS or A I>AL/KTIOMX;ICAL SCIENCE. <>f>7 
 
 life upon our earth, we have then, brought before us by 
 geological observations, a series of different forms of 
 vegetable and animal existence; occurring in different 
 strata, and, as the phenomena appear irresistibly to 
 prove, existing at successive periods : and we are com- 
 pelled to inquire what can have been the causes by 
 which the forms of each period have passed into those 
 of the next. We find, too, that strata, which must hrtve 
 been at first horizontal and continuous, have undergone 
 enormous dislocations and ruptures, and we have to 
 consider the possible effect of aqueous and volcanic 
 causes to produce such changes in the earth's crust. We 
 are thus led to the causes which have produced the pre- 
 sent state of things on the earth ; and these are causes 
 to which we may hypothetically ascribe, not only the 
 form and position of the inert materials of the earth, 
 but also the nature and distribution of its animal and 
 vegetable population. Man too, no less than other 
 animals, is affected by the operation of such causes as 
 we have referred to, and must, therefore, be included in 
 such speculations. But man's history only begins, where 
 that of other animals ends, with his mere existence. 
 They are stationary, he is progressive. Other species 
 of animals, once brought into being, continue the same 
 through all ages ; man is changing, from age to age, his 
 language, his thoughts, his works. Yet even these 
 changes are bound together by laws of causation ; and 
 these causes too may become objects of scientific study. 
 And such causes, though not to be dwelt upon now, 
 since we permit ourselves to found our philosophy upon 
 the material sciences only, must still, when treated scien- 
 tifically, fall within the principles of our philosophy, 
 and must be governed by the same general rules to 
 which all science is subject. And thus we are led by 
 a close and natural connexion, through a series of causes. 
 VOL. i. w. p. I' r 
 
658 PHILOSOPHY OF PALJETIOLOGY. 
 
 extending from those which regulate the imperceptible 
 changes of the remotest nebulae in the heavens, to those 
 which determine the diversities of language, the mu- 
 tations of art, and even the progress of civilization, 
 polity, and literature. 
 
 While I have been speaking of this supposed series 
 of events, including in its course the formation of the 
 earth, the introduction of animal and vegetable life, and 
 the revolutions by which one collection of species has 
 succeeded another, it must not be forgotten, that though 
 I have thus hypothetically spoken of these events as 
 occurring by force of natural causes, this has been done 
 only that the true efficacy of such causes might be 
 brought under our consideration and made the subject 
 of scientific examination. It may be found, that such 
 occurrences as these are quite inexplicable by the aid of 
 any natural causes with which we are acquainted ; and 
 thus, the result of our investigations, conducted with 
 strict regard to scientific principles, may be, that we 
 must either contemplate supernatural influences as part 
 of the past series of events, or declare ourselves alto- 
 gether unable to form this series into a connected chain. 
 
 13. Mode of Cultivating ^Etiology : In Geology. 
 In what manner, it may be asked, is ^Etiology, with 
 regard to each subject such as we have enumerated, to be 
 cultivated ? In order to answer this question, we must, 
 according to our method of proceeding, take the most 
 successful and complete examples which we possess of 
 such portions of science. But in truth, we can as yet 
 refer to few examples of this kind. In Geology, it is 
 only very recently, and principally through the example 
 and influence of Mr. Lyell, that the ^Etiology has been 
 detached from the descriptive portion of the science ; 
 and cultivated with direct attention : in other sciences 
 the separation has hardly yet been made. But if we 
 
MEMBERS OF A PAL^TIOLOGICAL SCIENCE. 659 
 
 examine what has already been done in Geological ^Eti- 
 ology, or as in the History it is termed, Geological 
 Dynamics, we shall find a number of different kinds of 
 investigation which, by the aid of our general principles 
 respecting the formation of sciences, may suffice to sup- 
 ply very useful suggestions for ^Etiology in general. 
 
 In Geological ^Etiology, causes have been studied, in 
 many instances, by attending to their action in the phe- 
 nomena of the present state of things, and by inferring 
 from this the nature and extent of the action which they 
 may have exercised in former times. This has been 
 done, for example, by Von Hoff, Mr. Lyell, and others, 
 with regard to the operations of rivers, seas, springs, 
 glaciers, and other aqueous causes of change. Again, 
 the same course has been followed by the same philoso- 
 phers with respect to volcanoes, earthquakes, and other 
 violent agents. Mr. Lyell has attempted to show, too, 
 that there take place, in our own time, not only violent 
 agitations, but slow motions of parts of the earth's crust, 
 of the same kind and order with those which have 
 assisted in producing all anterior changes. 
 
 But while we thus seek instruction in the phenomena 
 of the present state of things, we are led to the ques- 
 tion, What are the limits of this " present" period ? For 
 instance, among the currents of lava which we trace as 
 part of the shores of Italy and Sicily, which shall we 
 select as belonging to the existing order of things ? In 
 going backwards in time, where shall we draw the line ? 
 and why at such particular point ? These questions are 
 important, for our estimate of the efficacy of known 
 causes will vary with the extent of the effects which we 
 ascribe to them. Hence the mode in which we group 
 together rocks is not only a step in geological classifica- 
 tion, but is also important to ^Etiology. Thus when the 
 vast masses of trap rocks in the Western Isles of Scot- 
 
 u u 2 
 
660 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 land and in other countries, which had been maintained 
 by the Wernerians to be of aqueous origin, were, prin- 
 cipally by the sagacity and industry of Macculloch, iden- 
 tified as to their nature with the products of recent 
 volcanoes, the amount of effect which might justifiably 
 be ascribed to volcanic agency was materially extended. 
 
 In other cases, instead of observing the current 
 effects of our geological causes, we have to estimate the 
 results from what we know of the causes themselves; 
 as when, with Herschel, we calculate the alterations in 
 the temperature of the earth which astronomical changes 
 may possibly produce ; or when, with Fourier, we try to 
 calculate the rate of cooling of the earth's surface, on the 
 hypothesis of an incandescent central mass. In other 
 cases, again, we are not able to calculate the effects of 
 our causes rigorously, but estimate them as well as we 
 can, partly by physical reasonings, and partly by compa- 
 rison with such analogous cases as we can find in the 
 present state of things. Thus Mr. Lyell infers the change 
 of climate which would result if land were transferred 
 from the neighbourhood of the poles to that of the 
 equator, by reasonings on the power of land and water 
 to contain and communicate heat, supported by a refer- 
 ence to the different actual climates of places, lying 
 under the same latitude, but under different conditions 
 as to the distribution of land and water. 
 
 Thus our ^Etiology is constructed partly from calcu- 
 lation and reasoning, partly from phenomena. But we 
 may observe that when we reason from phenomena to 
 causes, we usually do so by various steps ; often ascend- 
 ing from phenomena to mere laws of phenomena, before 
 we can venture to connect the phenomenon confidently 
 with its cause. Thus the law of subterranean heat, 
 that it increases in descending below the surface, is 
 now well established, although the doctrine which 
 
MEMBERS OF A PAL^ETIOLOGICAL SCIENCE. 6G1 
 
 ascribes this effect to a central heat is not universally 
 assented to. 
 
 14. In the Geography of Plants and Animals. 
 We may find in other subjects also, considerable con- 
 tributions towards ^Etiology, though not as yet a com- 
 plete system of science. The ^Etiology of vegetables 
 and animals, indeed, has been studied with great zeal in 
 modern times, as an essential preparative to geological 
 theory ; for how can we decide whether any assumed 
 causes have produced the succession of species which we 
 find in the earth's strata, except we know what effect 
 of this kind given causes can produce? Accordingly, 
 we find in Mr. Lyell's- Treatise on Geology the most 
 complete discussion of such questions as belong to these 
 subjects : for example, the question whether species 
 can be transmuted into other species by the long con- 
 tinued influence of external causes, as climate, food, 
 domestication, combined with internal causes, as habits, 
 appetencies, progressive tendencies. We may observe, 
 too, that as we have brought before us the inquiry what 
 change difference of climate can produce in any species, 
 we have also the inverse problem, how far a different 
 developement of the species, or a different collection of 
 species, proves a difference of climate. In the same way, 
 the geologist of the present day considers the question, 
 whether, in virtue of causes now in action, species are 
 from time to time extinguished ; and in like manner, 
 the geologists of an earlier period discussed the question, 
 now long completely decided, whether fossil species in 
 general are really extinct species. 
 
 15. In Languages. Even with reference to the 
 ^Etiology of language, although this branch of science 
 has hardly been considered separately from the glosso- 
 logical investigations in which it is employed or assumed 
 to be employed, it might perhaps be possible to point 
 
662 PHILOSOPHY OF PALxtiTIOLOGY. 
 
 out causes or conditions of change which, being general 
 in their nature, must operate upon all languages alike. 
 Changes made for the sake of euphony when words are 
 modified and combined, occur in all dialects. Who can 
 doubt that such changes of consonants as those by which 
 the Greek roots become Gothic, arid the Gothic, German, 
 have for their cause some general principle in the pro- 
 nunciation of each language ? Again, we might attempt 
 to decide other questions of no small interest. Have 
 the terminations of verbs arisen from the accretion of 
 pronouns ; or, on the other hand, does the modification 
 of a verb imply a simpler mental process than the insu- 
 lation of a pronoun, as Adam Smith has maintained? 
 Again, when the language of a nation is changed by the 
 invasion and permanent mixture of an enemy of different 
 speech, is it generally true that it is changed from a syn- 
 thetic to an analytical structure ? I will mention only 
 one more of these wide and general glossological in- 
 quiries. Is it true, as Dr. Prichard has suggested 4 '", 
 that languages have become more permanent as we 
 come down towards later times? May we justifiably 
 suppose, with him, that in the very earliest times, 
 nations, when they had separated from one stock, might 
 lose all traces of this common origin out of their lan- 
 guages, though retaining strong evidences of it in their 
 mythology, social forms, and arts, as appears to be the 
 case with the ancient Egyptians and the Indians f ? 
 
 Large questions of this nature cannot be treated pro- 
 fitably in any other way than by an assiduous study of 
 the most varied forms of living and dead languages. 
 But on the other hand, the study of languages should 
 be prosecuted not only by a direct comparison of one 
 with another, but also with a view to the formation of a 
 science of causes and general principles, embracing such 
 * Researches, n. 221. f lb., n. 192. 
 
MEMBERS OF ^ PAL^ETIOLOGICAL SCIENCE. 
 
 discussions as I have pointed out. It is only when such 
 a science has been formed, that we can hope to obtain any 
 solid and certain results in the Palsetiology of language ; 
 to determine, with any degree of substantial proof, 
 what is the real evidence which the wonderful faculty 
 of speech, under its present developements and forms, 
 bears to the events which have taken place in its own 
 history, and in the history of man since his first origin. 
 
 1 6. Construction of Theories. When we have thus 
 obtained, with reference to any such subject as those we 
 have here spoken of, these two portions of science, a 
 Systematic Description of the Facts, and a rigorous Ana- 
 lysis of the Causes, the Phenomenology and the ^Etio- 
 logy of the subject, we are prepared for the third 
 member which completes the science, the Theory of the 
 actual facts. We can then take a view of the events 
 which really have happened, discerning their connexion, 
 interpreting their evidence, supplying from the context 
 the parts which are unapparent. We can account for 
 known facts by intelligible causes, we can infer latent 
 facts from manifest effects, so as to obtain a distinct 
 insight into the whole history of events up to the present 
 time, and to see the last result of the whole in the pre- 
 sent condition of things. The term Theory, when rigor- 
 ously employed in such sciences as those which we here 
 consider, bears nearly the sense which I have adopted : 
 it implies a consistent and systematic view of the actual 
 facts, combined with a true apprehension of their con- 
 nexion and causes. Thus if we speak of " a Theory of 
 Mount Etna," or "a Theory of the Paris Basin," we 
 mean a connected and intelligible view of the events by 
 which the rocks in these localities have come into their 
 present condition. Undoubtedly the term Theory has 
 often been used in a looser sense; and men have put 
 forth " Theories of the Earth" which, instead of includ- 
 
664 PHILOSOPHY OF PAUETIOLOGY. 
 
 ing the whole mass of actual geological facts and their 
 causes, only assigned, in a vague manner, some causes 
 by which some few phenomena might, it was conceived, 
 be accounted for. Perhaps the portion of our Palsetio- 
 logical Sciences which we now wish to designate, would 
 be more generally understood if we were to describe it 
 as Theoretical or Philosophical History; as when we 
 talk of " the Theoretical History of Architecture," or 
 " the Philosophical History of Language." And in the 
 same manner we might speak of the Theoretical History 
 of the Animal and Vegetable Kingdoms; meaning, a 
 distinct account of the events which have produced the 
 present distribution of species and families. But by 
 whatever phrase we describe this portion of science, it is 
 plain that such a Theory, such a Theoretical History, 
 must result from the application of causes well under- 
 stood to facts well ascertained. And if the term Theory 
 be here employed, we must recollect that it is to be un- 
 derstood, not in its narrower sense as opposed to facts, but 
 in its wider signification, as including all known facts 
 and differing from them only in introducing among them 
 principles of intelligible connexion. The Theories of 
 which we now speak are true Theories, precisely because 
 they are identical with the total system of the Facts. 
 
 17. No sound Palcetiological Theory yet extant. It 
 is not to disparage the present state of science, to say 
 that as yet no such theory exists on any subject. 
 "Theories of the Earth" have been repeatedly pub- 
 lished; but when we consider that even the facts of 
 geology have been observed only on a small portion of 
 the earth's surface, and even within those narrow bounds 
 very imperfectly studied, we shall be able to judge how 
 impossible it is that geologists should have yet obtained 
 a well-established Theoretical History of the changes 
 which have taken place in the crust of the terrestrial 
 
MEMBERS OF A PAL^KTIOLOGICAL SCIENCE. G65 
 
 globe from its first origin. Accordingly, I have ventured 
 in my History to designate the most prominent of the 
 Theories which have hitherto prevailed as premature 
 geological theories'* : and we shall soon see that geo- 
 logical theory has not advanced beyond a few conjec- 
 tures, and that its cultivators are at present mainly 
 occupied with a controversy in which the two extreme 
 hypotheses which first offer themselves to men's minds 
 are opposed to each other. And if we have no theo- 
 retical history of the earth which merits any confidence, 
 still less have we any theoretical History of Language, 
 or of the Arts, which we can consider as satisfactory. 
 The Theoretical History of the Vegetable and Animal 
 Kingdoms is closely connected with that of the earth on 
 which they subsist, and must follow the fortunes of geo- 
 logy. And thus we may venture to say that no Palse- 
 tiological Science, as yet, possesses all its three members. 
 Indeed most of them are very far from having completed 
 and systematized their Phenomenology : in all, the cul- 
 tivation of ^Etiology is but just begun, or is not begun ; 
 in all, the Theory must reward the exertions of future, 
 probably of distant, generations. 
 
 But in the mean time we may derive some instruction 
 from the comparison of the two antagonist hypotheses of 
 which I have spoken. 
 
 CHAPTER III. 
 
 OF THE DOCTRINE OF CATASTROPHES AND 
 THE DOCTRINE OF UNIFORMITY. 
 
 1 . Doctrine of Catastrophes. I HAVE already shown, 
 in the History of Geology, that the attempts to frame a 
 theory of the earth have brought into view two com- 
 
 * Hist. Ind. Sci., B. xvui. c. vii. sect. 3. 
 
666 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 pletely opposite opinions : one, which represents the 
 course of nature as uniform through all ages, the causes 
 which produce change having had the same intensity in 
 former times which they have at the present day ; the 
 other opinion, which sees, in the present condition of 
 things, evidences of catastrophes ; changes of a more 
 sweeping kind, and produced by more powerful agencies 
 than those which occur in recent times. Geologists 
 who held the latter opinion, maintained that the forces 
 which have elevated the Alps or the Andes to their pre- 
 sent height could not have been any forces which are 
 now in action : they pointed to vast masses of strata 
 hundreds of miles long, thousands of feet thick, thrown 
 into highly-inclined positions, fractured, dislocated, 
 crushed : they remarked that upon the shattered edges 
 of such strata they found enormous accumulations of 
 fragments and rubbish, rounded by the action of water, 
 so as to denote ages of violent aqueous action : they 
 conceived that they saw instances in which whole moun- 
 tains of rock in a state of igneous fusion, must have 
 burst the earth's crust from below : they found that in 
 the course of the revolutions by which one stratum of 
 rock was placed upon another, the whole collection of 
 animal species which tenanted the earth and the seas 
 had been removed, and a new set of living things intro- 
 duced in its place : finally, they found, above all the 
 strata, vast masses of sand and gravel containing bones 
 of animals, and apparently the work of a mighty deluge. 
 With all these proofs before their eyes, they thought it 
 impossible not to judge that the agents of change by 
 which the world was urged from one condition to another 
 till it reached its present state must have been more 
 violent, more powerful, than any which we see at work 
 around us. They conceived that the evidence of " catas- 
 trophes" was irresistible. 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 667 
 
 2. Doctrine of Uniformity. I need not here repeat 
 the narrative (given in the History*"") of the process by 
 which this formidable array of proofs was, in the minds 
 of some eminent geologists, weakened, and at last over- 
 come. This was done by showing that the sudden breaks 
 in the succession of strata were apparent only, the dis- 
 continuity of the series which occurred in one country 
 being removed by terms interposed in another locality : 
 by urging that the total effect produced by existing 
 causes, taking into account the accumulated result of 
 long periods, is far greater than a casual speculator would 
 think possible : by making it appear that there are in 
 many parts of the world evidences of a slow and imper- 
 ceptible rising of the land since it was the habitation of 
 now existing species : by proving that it is not univer- 
 sally true that the strata separated in time by supposed 
 catastrophes contain distinct species of animals: by 
 pointing out the limited fields of the supposed diluvial 
 action : and finally, by remarking that though the crea- 
 tion of species is a mystery, the extinction of species is 
 going on in our own day. Hypotheses were suggested, 
 too, by which it was conceived that the change of cli- 
 mate might be explained, which, as the consideration of 
 the fossil remains seemed to show, must have taken 
 place between the ancient and the modern times. In 
 this manner the whole evidence of catastrophes was 
 explained away : the notion of a series of paroxysms of 
 violence in the causes of change was represented as a 
 delusion arising from our contemplating short periods 
 only, in the action of present causes : length of time was 
 called in to take the place of intensity of force : and it 
 was declared that Geology need not despair of account- 
 ing for the revolutions of the earth, as Astronomy ac- 
 counts for the revolutions of the heavens, by the universal 
 
 * Hist. Ind Sci., B. xvm. c. viii- sect 2. 
 
668 PHILOSOPHY OF PALJETIOLOGY. 
 
 action of causes which are close at hand to us, operating 
 through time and space without variation or decay. 
 
 An antagonism of opinions, somewhat of the same 
 kind as this, will be found to manifest itself in the other 
 Palsetiological Sciences as well as in Geology; and it will 
 be instructive to endeavour to balance these opposite 
 doctrines. I will mention some of the considerations 
 which bear upon the subject in its general form. 
 
 3. Is Uniformity probable d priori f The doctrine 
 of Uniformity in the course of nature has sometimes been 
 represented by its adherents as possessing a great degree 
 of d priori probability. It is highly unphilosophical, it 
 has been urged, to assume that the causes of the geolo- 
 gical events of former times were of a different kind from 
 causes now in action, if causes of this latter kind can in 
 any way be made to explain the facts. The analogy of 
 all other sciences compels us, it was said, to explain phe- 
 nomena by known, not by unknown, causes. And on 
 these grounds the geological teacher recommended* "an 
 earnest and patient endeavour to reconcile the indications 
 of former change with the evidence of gradual mutations 
 now in progress." 
 
 But on this we may remark, that if by known causes 
 we mean causes acting with the same intensity which 
 they have had during historical times, the restriction is 
 altogether arbitrary and groundless. Let it be granted, 
 for instance, that many parts of the earth's surface are 
 now undergoing an imperceptible rise. It is not pre- 
 tended that the rate of this elevation is rigorously uni- 
 form ; what, then, are the limits of its velocity ? Why may 
 it not increase so as to assume that character of violence 
 which we may term a catastrophe with reference to all 
 changes hitherto recorded? Why may not the rate of 
 elevation be such that we may conceive the strata to 
 * Lyell, 4ili Ed. B. iv. c. 1, p. 328. 
 
DOCTKLSKS OF CATASTROPHES AND OF UNIFORMITY. 669 
 
 assume suddenly a position nearly vertical ? and is it, in 
 fact, easy to conceive a position of strata nearly vertical, 
 a position which occurs so frequently, to be gradually 
 assumed ? In cases where the strata are nearly vertical, 
 as in the Isle of Wight, and hundreds of other places, or 
 where they are actually inverted, as sometimes occurs, 
 are not the causes which have produced the effect as truly 
 known causes, as those which have raised the coasts where 
 we trace the former beach in an elevated terrace ? If 
 the latter case proves slow elevation, does not the former 
 case prove rapid elevation ? In neither case have we any 
 measure of the time employed in the change ; but does 
 not the very nature of the results enable us to discern, 
 that if one was gradual, the other was comparatively 
 sudden ? 
 
 The causes which are now elevating a portion of 
 Scandinavia can be called known causes, only because we 
 know the effect. Are not the causes which have elevated 
 the Alps and the Andes known causes in the same sense? 
 We know nothing in either case which confines the 
 intensity of the force within any limit, or prescribes to it 
 any law of uniformity. Why, then, should we make a 
 merit of cramping our speculations by such assumptions ? 
 Whether the causes of change do act uniformly ; 
 whether they oscillate only within narrow limits; 
 whether their intensity in former times was nearly the 
 same as it now is; these are precisely the questions 
 which we wish Science to answer to us impartially and 
 truly : where is then the wisdom of " an earnest and 
 patient endeavour" to secure an affirmative reply? 
 
 Thus I conceive that the assertion of an a priori 
 claim to probability and philosophical spirit in favour of 
 the doctrine of uniformity, is quite untenable. We must 
 learn from an examination of all the facts, and not from 
 any assumption of our own, whether the course of nature 
 
670 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 be uniform. The limit of intensity being really unknown, 
 catastrophes are just as probable as uniformity. If a 
 volcano may repose for a thousand years, and then break 
 out and destroy a city ; why may not another volcano 
 repose for ten thousand years, and then destroy a con- 
 tinent; or if a continent, why not the whole habitable 
 surface of the earth ? 
 
 4. Cycle of Uniformity indefinite. But this argument 
 may be put in another form. When it is said that the 
 course of nature is uniform, the assertion is not intended 
 to exclude certain smaller variations of violence and rest, 
 such as we have just spoken of; alternations of activity 
 and repose in volcanoes; or earthquakes, deluges, and 
 storms, interposed in a more tranquil state of things. 
 With regard to such occurrences, terrible as they appear 
 at the time, they may not much affect the average rate 
 of change ; there may be a cycle, though an irregular one, 
 of rapid and slow change ; and if such cycles go on suc- 
 ceeding each other, we may still call the order of nature 
 uniform, notwithstanding the periods of violence which 
 it involves. The maximum and minimum intensities of 
 the forces of mutation alternate with one another ; and 
 we may estimate the average course of nature as that 
 which corresponds to something between the two ex- 
 tremes. 
 
 But if we thus attempt to maintain the uniformity of 
 nature by representing it as a series of cycles, we find 
 that we cannot discover, in this conception, any solid 
 ground for excluding catastrophes. What is the length 
 of that cycle, the repetition of which constitutes uni- 
 formity? What interval from the maximum to the 
 minimum does it admit of? We may take for our cycle 
 a hundred or a thousand years, but evidently such a pro- 
 ceeding is altogether arbitrary. We may mark our cycles 
 by the greatest known paroxysms of volcanic and terre- 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 671 
 
 motive agency, but this procedure is no less indefinite 
 and inconclusive than the other. 
 
 But further ; since the cycle in which violence and 
 repose alternate is thus indefinite in its length and in its 
 range of activity, what ground have we for assuming 
 more than one such cycle, extending from the origin of 
 things to the present time ? Why may we not suppose 
 the maximum force of the causes of change to have taken 
 place at the earliest period, and the tendency towards the 
 minimum to have gone on ever since? Or instead of 
 only one cycle, there may have been several, but of such 
 length that our historical period forms a portion only of 
 the last ; the feeblest portion of the latest cycle. And 
 thus violence and repose may alternate upon a scale of 
 time and intensity so large, that man's experience sup- 
 plies no evidence enabling him to estimate the amount. 
 The course of things is uniform, to an Intelligence which 
 can embrace the succession of several cycles, but it is 
 catastrophic to the contemplation of man, whose survey 
 can grasp a part only of one cycle. And thus the hypo- 
 thesis of uniformity, since it cannot exclude degrees of 
 change, nor limit the range of these degrees, nor define 
 the interval of their recurrence, cannot possess any essen- 
 tial simplicity which, previous to inquiry, gives it a claim 
 upon our assent superior to that of the opposite cata- 
 strophic hypothesis. 
 
 5. Uniformitarian Arguments are Negative only. 
 . There is an opposite tendency in the mode of maintaining 
 the catastrophist and the uniformitarian opinions, which 
 depends upon their fundamental principles, and shows 
 itself in all the controversies between them. The Cata- 
 strophist is affirmative, the Uniformitarian is negative in 
 his assertions: the former is constantly attempting to 
 construct a theory ; the latter delights in demolishing all 
 theories. The one is constantly bringing fresh evidence 
 
672 PHILOSOPHY OF PAL^TIOLOGY. 
 
 of some great past event, or series of events, of a striking 
 and definite kind ; his antagonist is at every step explain- 
 ing away the evidence, and showing that it proves nothing. 
 One geologist adduces his proofs of a vast universal deluge; 
 but another endeavours to show that the proofs do not 
 establish either the universality or the vastness of such an 
 event. The inclined broken edges of a certain formation, 
 covered with their own fragments, beneath superjacent 
 horizontal deposits, are at one time supposed to prove a 
 catastrophic breaking up of the earlier strata ; but this 
 opinion is controverted by showing that the same forma- 
 tions, when pursued into other countries, exhibit a uni- 
 form gradation from the lower to the upper, with no 
 trace of violence. Extensive and lofty elevations of the 
 coast, continents of igneous rock, at first appear to indi- 
 cate operations far more gigantic than those which now 
 occur ; but attempts are soon made to show that time 
 only is wanting to enable the present age to rival the 
 past in the production of such changes. Each new fact 
 adduced by the catastrophist is at first striking and appa- 
 rently convincing ; but as it becomes familiar, it strikes 
 the imagination less powerfully ; and the uniformitarian, 
 constantly labouring to produce some imitation of it by 
 the machinery which he has so well studied, at last in 
 every case seems to himself to succeed, so far as to 
 destroy the effect of his opponent's evidence. 
 
 This is so with regard to more remote, as well as with 
 regard to immediate evidences of change. When it is- 
 ascertained that in every part of the earth's crust the 
 temperature increases as we descend below the surface, 
 at first this fact seems to indicate a central heat : and a 
 central heat naturally suggests an earlier state of the 
 mass, in which it was incandescent, and from which it is 
 now cooling. But this original incandescence of the 
 globe of the earth is manifestly an entire violation of the 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 673 
 
 present course of things ; it belongs to the catastrophist 
 view, and the advocates of uniformity have to explain it 
 away. Accordingly, one of them holds that this increase 
 of heat in descending below the surface may very possibly 
 not go on all the way to the center. The heat which in- 
 creases at first as we descend, may, he conceives, after- 
 wards decrease ; and he suggests causes which may have 
 produced such a succession of hotter and colder shells 
 within the mass of the earth. I have mentioned this 
 suggestion in the History of Geology ; and have given 
 my reasons for believing it altogether untenable *. Other 
 persons also, desirous of reconciling this subterraneous 
 heat with the tenet of uniformity, have offered another 
 suggestion : that the warmth or incandescence of the 
 interior parts of the earth does not arise out of an ori- 
 ginally hot condition from which it is gradually cooling, 
 but results from chemical action constantly going on 
 among the materials of the earth's substance. And thus 
 new attempts are perpetually making, to escape from the 
 cogency of the reasonings which send us towards an ori- 
 ginal state of things different from the present. Those 
 who theorize concerning an origin go on building up the 
 fabric of their speculations, while those who think such 
 theories unphilosophical, ever and anon dig away the 
 foundation of this structure. As we have already said, 
 the uniformitarian's doctrines are a collection of nega- 
 tives. 
 
 This is so entirely the case, that the uniformitarian 
 would for the most part shrink from maintaining as 
 positive tenets the explanations which he so willingly 
 uses as instruments of controversy. He puts forward his 
 suggestions as difficulties, but he will not stand by them 
 as doctrines. And this is in accordance with his general 
 tendency ; for any of his hypotheses, if insisted upon as 
 
 * Hist. Ind. Set., B. XVITI. c. v. sect 5, and note. 
 VOL. I. W. P. X X 
 
674 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 positive theories, would be found inconsistent with the 
 assertion of uniformity. For example, the nebular hypo- 
 thesis appears to give to the history of the heavens an 
 aspect which obliterates all special acts of creation, 
 for, according to that hypothesis, new planetary systems 
 are constantly forming ; but when asserted as the origin 
 of our own solar system, it brings with it an original 
 incandescence, and an origin of the organic world. And 
 if, instead of using the chemical theory of subterraneous 
 heat to neutralize the evidence of original incandescence, 
 we assert it as a positive tenet, we can no longer main- 
 tain the infinite past duration of the earth ; for chemical 
 forces, as well as mechanical, tend to equilibrium ; and 
 that condition once attained, their efficacy ceases. Che- 
 mical affinities tend to form new compounds ; and though, 
 when many and various elements are mingled together, 
 the play of synthesis and analysis may go on for a long 
 time, it must at last end. If, for instance, a large por- 
 tion of the earth's mass were originally pure potassium, 
 we can imagine violent igneous action to go on so long 
 as any part remained unoxidized; but when the oxidation 
 of the whole has once taken place, this action must be 
 at an end ; for there is in the hypothesis no agency 
 which can reproduce the deoxidized metal. Thus a per- 
 petual motion is impossible in chemistry, as it is in 
 mechanics ; and a theory of constant change continued 
 through infinite time, is untenable when asserted upon 
 chemical, no less than upon mechanical principles. And 
 thus the Skepticism of the uniformitarian is of force only 
 so long as it is employed against the Dogmatism of the 
 catastrophist. When the Doubts are erected into Dogmas, 
 they are no longer consistent with the tenet of Unifor- 
 mity. When the Negations become Affirmations, the 
 Negation of an Origin vanishes also. 
 
 6. Uniformity in the Organic World. In speaking 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 67f> 
 
 of the violent and sudden changes which constitute cata- 
 strophes, our thoughts naturally turn at first to great 
 mechanical and physical effects; ruptures and displace- 
 ments of strata ; extensive submersions and emersions of 
 land; rapid changes of temperature. But the catastrophes 
 which we have to consider in geology affect the organic as 
 well as the inorganic world. The sudden extinction of 
 one collection of species, and the introduction of another 
 in their place, is a catastrophe, even if unaccompanied 
 by mechanical violence. Accordingly, the antagonism of 
 the catastrophist and uniformitarian school has shown 
 itself in this department of the subject, as well as in the 
 other. When geologists had first discovered that the 
 successive strata are each distinguished by appropri- 
 ate organic fossils, they assumed at once that each of 
 these collections of living things belonged to a separate 
 creation. But this conclusion, as I have already said, 
 Mr. Lyell has attempted to invalidate, by proving that in 
 the existing order of things, some species become extinct ; 
 and by suggesting it as possible, that in the same order 
 it may be true that new species are from time to time 
 produced, even in the present course of nature. And in 
 this, as in the other part of the subject, he calls in the 
 aid of vast periods of time, in order that the violence of 
 the changes may be softened down : and he appears dis- 
 posed to believe that the actual extinction and creation 
 of species may be so slow as to excite no more notice 
 than it has hitherto obtained; and yet may be rapid 
 enough, considering the immensity of geological periods, 
 to produce such a succession of different collections of 
 species as we find in the strata of the earth's surface. 
 
 7. Origin of the present Organic World. The last 
 great event in the history of the vegetable and animal 
 kingdoms was that by which their various tribes were 
 placed in their present seats. And we may form various 
 
 XX2 
 
676 PHILOSOPHY OF PAL^KTIOLOGY. 
 
 hypotheses with regard to the sudden or gradual man- 
 ner in which we may suppose this distribution to have 
 taken place. We may assume that at the beginning of 
 the present order of things, a stock of each species was 
 placed in the vegetable or animal province to which it 
 belongs, by some cause out of the common order of 
 nature ; or we may take a uniformitarian view of the 
 subject, and suppose that the provinces of the organic 
 world derived their population from some anterior state 
 of things by the operation of natural causes. 
 
 Nothing has been pointed out in the existing order 
 of things which has any analogy or resemblance, of any 
 valid kind, to that creative energy which must be exerted 
 in the production of a new species. And to assume the 
 introduction of new species as " a part of the order of 
 nature," without pointing out any natural fact with 
 which such an event can be classed, would be to reject 
 creation, by an arbitrary act. Hence, even on natural 
 grounds, the most intelligible view of the history of the 
 animal and vegetable kingdoms seems to be, that each 
 period which is marked by a distinct collection of species 
 forms a cycle ; and that at the beginning of each such 
 cycle a creative power was exerted, of a kind to which 
 there was nothing at all analogous in the succeeding 
 part of the same cycle. If it be urged that in some 
 cases the same species, or the same genus, runs through 
 two geological formations, which must, on other grounds, 
 be referred to different cycles of creative energy, we 
 may reply that the creation of many new species does 
 not imply the extinction of all the old ones. 
 
 Thus we are led by our reasonings to this view, that 
 the present order of things was commenced by an act 
 of creative power entirely different to any agency which 
 has been exerted since. None of the influences which 
 have modified the present races of animals and plants 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 677 
 
 since they were placed in their habitations on the earth's 
 surface can have had any efficacy in producing them at 
 first. We are necessarily driven to assume, as the begin- 
 ning of the present cycle of organic nature, an event not 
 included in the course of nature. And we may remark 
 that this necessity is the more cogent, precisely because 
 other cycles have preceded the present. 
 
 8. Nebular Origin of the Solar System. If we 
 attempt to apply the same antithesis of opinion (the 
 doctrines of Catastrophe and Uniformity,) to the other 
 subjects of palsetiological sciences, we shall be led to 
 similar conclusions. Thus, if we turn our attention to 
 astronomical palsetiology, we perceive that the nebular 
 hypothesis has a uniformitarian tendency. According to 
 this hypothesis the formation of this our system of sun, 
 planets, and satellites, was a process of the same kind 
 as those which are still going on in the heavens. One 
 after another, nebulae condense into separate masses, 
 which begin to revolve about each other by mechanical 
 necessity, and form systems of which our solar system 
 is a finished example. But we may remark, that the 
 uniformitarian doctrine on this subject rests on most 
 unstable foundations. We have as yet only very vague 
 and imperfect reasonings to show that by such conden- 
 sation a material system such as ours could result ; and 
 the introduction of organized beings into such a material 
 system is utterly out of the reach of our philosophy. 
 Here again, therefore, we are led to regard the pre- 
 sent order of the world as pointing towards an origin 
 altogether of a different kind from anything which our 
 material science can grasp. 
 
 9. Origin of Languages. We may venture to say 
 that we should be led to the same conclusion once more, 
 if we were to take into our consideration those palsetio- 
 logical sciences which are beyond the domain of matter ; 
 
678 PHILOSOPHY OF PAL^ITIOLOGY. 
 
 for instance, the history of languages. We may explain 
 many of the differences and changes which we become 
 acquainted with, by referring to the action of causes of 
 change which still operate. But what glossologist will 
 venture to declare that the efficacy of such causes has 
 been uniform ; that the influences which mould a lan- 
 guage, or make one language differ from others of the 
 same stock, operated formerly with no more efficacy 
 than they exercise now. " Where," as has elsewhere 
 been asked, " do we now find a language in the process 
 of formation, unfolding itself in inflexions, terminations, 
 changes of vowels by grammatical relations, such as 
 characterize the oldest known languages?" Again, as 
 another proof how little the history of languages sug- 
 gests to the philosophical glossologist the persuasion of 
 a uniform action of the causes of change, I may refer 
 to the conjecture of Dr. Prichard, that the varieties of 
 language produced by the separation of one stock into 
 several, have been greater and greater as we go back- 
 wards in history: that* the formation of sister dialects 
 from a common language, (as the Scandinavian, German, 
 and Saxon dialects from the Teutonic, or the Gaelic, 
 Erse and Welsh from the Celtic,) belongs to the first 
 millennium before the Christian era; while the forma- 
 tion of cognate languages of the same family, as the 
 Sanskrit, Latin, Greek and Gothic, must be placed at 
 least two thousand years before that era ; and at a still 
 earlier period took place the separation of the great 
 families themselves, the Indo-European, Semitic, and 
 others, in which it is now difficult to trace the features 
 of a common origin. No hypothesis except one of this 
 kind will explain the existence of the families, groups, 
 and dialects of languages, which we find in existence. 
 Yet this is an entirely different view from that which 
 
 * Researches, n. 224. 
 
DOCTRINES OF CATASTROPHES AND OF UNIFORMITY. 679 
 
 the hypothesis of the uniform progress of change would 
 give. And thus, in the earliest stages of man's career, 
 the revolutions of language must have been, even by 
 the evidence of the theoretical history of language itself, 
 of an order altogether different from any which have 
 taken place within the recent history of man. And we 
 may add, that as the early stages of the progress of 
 language must have widely different from those later 
 ones of which we can in some measure trace the natural 
 causes, we cannot place the origin of language in any 
 point of view in which it comes under the jurisdiction of 
 natural causation at all. 
 
 10. No Natural Origin discoverable. We are thus 
 led by a survey of several of the palsetiological sciences 
 to a confirmation of the principle formerly asserted"*, 
 That in no palsetiological science has man been able to 
 arrive at a beginning which is homogeneous with the 
 known course of events. We can in such sciences often 
 go very far back ; determine many of the remote cir-* 
 cumstances of the past series of events ; ascend to a 
 point which seems to be near the origin ; and limit the 
 hypotheses respecting the origin itself: but philoso- 
 phers never have demonstrated, and, so far as we can 
 judge, probably never will be able to demonstrate, what 
 was that primitive state of things from which the pro- 
 gressive course of the world took its first departure. In 
 all these paths of research, when we travel far back- 
 wards, the aspect of the earlier portions becomes very 
 different from that of the advanced part on which we 
 now stand ; but in all cases the path is lost in obscurity 
 as it is traced backwards towards its starting point : it 
 becomes not only invisible, but unimaginable ; it is not 
 only an interruption, but an abyss, which interposes itself 
 between us and any intelligible beginning of things. 
 
 * Hist. Ind. Sci., B. xvm. c. vi. sect. 5. 
 
680 PHILOSOPHY OF PAL^TIOLOY. 
 
 CHAPTER IV. 
 
 OF THE RELATION OF TRADITION TO PAL.E- 
 
 TIOLOGY. 
 
 1. Importance of Tradition. SINCE the Palaetio- 
 logical Sciences have it for their business to study the 
 train of past events produced by natural causes down to 
 the present time, the knowledge concerning such events 
 which is supplied by the remembrance and records of 
 man, in whatever form, must have an important bearing 
 upon these sciences. All changes in the condition and 
 extent of land and sea, which have taken place within 
 man's observation, all effects of deluges, sea-waves, 
 rivers, springs, volcanoes, earthquakes, and the like, 
 which come within the reach of human history, have a 
 strong interest for the palsetiologist. Nor is he less con- 
 cerned in all recorded instances of the modification of 
 the forms and habits of plants and animals, by the opera- 
 tions of man, or by transfer from one land to another. 
 And when we come to the Palsetiology of Language, of 
 Art, of Civilization, we find our subject still more closely 
 connected with history ; for in truth these are historical, 
 no less than palsetiological investigations. But, confin- 
 ing ourselves at present to the material sciences, we 
 may observe that though the importance of the infor- 
 mation which tradition gives us, in the sciences now 
 under our consideration, as, for instance, geology, has 
 long been tacitly recognized ; yet it is only recently that 
 geologists have employed themselves in collecting their 
 historical facts upon such a scale and with such compre- 
 hensive views as are required by the interest and use of 
 collections of this kind. The Essay of Von Hoff*, On 
 the Natural Alterations in the Surface of the Earth 
 * Vol. /., 1822; Vol. ii., 1824. 
 
RELATION OF TRADITION TO PAL^ETIOLOGY. 681 
 
 which are proved by Tradition, was the work which 
 first opened the eyes of geologists to the extent and 
 importance of this kind of investigation. Since that 
 time the same path of research has been pursued with 
 great perseverance by others, especially by Mr. Lyell ; 
 and is now justly considered as an essential portion of 
 Geology. 
 
 2. Connexion of Tradition and Science. Events 
 which we might naturally expect to have some bearing 
 on geology, are narrated in the historical writings which, 
 even on mere human grounds, have the strongest claim 
 to our respect as records of the early history of the 
 world, and are confirmed by the traditions of various 
 nations all over the globe ; namely, the formation of the 
 earth and of its population, and a subsequent deluge. 
 It has been made a matter of controversy how the narra- 
 tive of these events is to be understood, so as to make it 
 agree with the facts which an examination of the earth's 
 surface and of its vegetable and animal population dis- 
 closes to us. Such controversies, when they are con- 
 sidered as merely archaeological, may occur in any of the 
 palsetiological sciences. We may have to compare and 
 to reconcile the evidence of existing phenomena with 
 that of historical tradition. But under some circum- 
 stances this process of conciliation may assume an in- 
 terest of another kind, on which we will make a few 
 remarks. 
 
 3. Natural and Providential History of the World. 
 We may contemplate the existence of man upon the 
 earth, his origin and his progress, in the same manner 
 as we contemplate the existence of any other race of 
 animals; namely, in a purely palsetiological view. We 
 may consider how far our knowledge of laws of causa- 
 tion enables us to explain his diffusion and migration, 
 his differences and resemblances, his actions and works. 
 
682 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 And this is the view of man as a member of the Natural 
 Course of Things. 
 
 But man, at the same time the contemplator and the 
 subject of his own contemplation, endowed with facul- 
 ties and powers which make him a being of a different 
 nature from other animals, cannot help regarding his 
 own actions and enjoyments, his recollections and his 
 hopes, under an aspect quite different from any that we 
 have yet had presented to us. We have been endeavour- 
 ing to place in a clear light the Fundamental Ideas, 
 such as that of Cause, on which depends our knowledge 
 of the natural course of things. But there are other 
 Ideas to which man necessarily refers his actions ; he is 
 led by his nature, not only to consider his own actions, 
 and those of his fellow-men, as springing out of this or 
 that cause, leading to this or that material result ; but 
 also as good or bad, as what they ought or ought not to 
 be. He has Ideas of moral relations as well as those 
 Ideas of material relations with which we have hitherto 
 been occupied. He is a moral as well as a natural 
 agent. 
 
 Contemplating himself and the world around him 
 by the light of. his Moral Ideas, man is led to the con- 
 viction that his moral faculties were bestowed upon him 
 by design and for a purpose ; that he is the subject of 
 a Moral Government ; that the course of the world is 
 directed by the Power which governs it, to the unfolding 
 and perfecting of man's moral nature ; that this guid- 
 ance may be traced in the career of individuals and of 
 the world ; that there is a Providential as well as a 
 Natural Course of Things. 
 
 Yet this view is beset by no small difficulties. The 
 full developement of man's moral faculties ; the perfec- 
 tion of his nature up to the measure of his own ideas; 
 the adaptation of his moral being to an ultimate des- 
 
RELATION OF TRADITION TO PAL^ETIOLOGY. 683 
 
 tinatiou, by its transit through a world full of moral 
 evil, in which evil each person has his share ; are effects 
 for which the economy of the world appears to contain 
 no adequate provision. Man, though aware of his moral 
 nature, and ready to believe in an ultimate destination 
 of purity and blessedness, is too feeble to resist the 
 temptation of evil, and too helpless to restore his purity 
 when once lost. He cannot but look for some confir- 
 mation of that providential order which he has begun 
 to believe ; some provision for those deficiencies in his 
 moral condition which he has begun to feel. 
 
 He looks at the history of the world, and he finds 
 that at a certain period it offers to him the promise of 
 what he seeks. When the natural powers of man had 
 been developed to their full extent, and were beginning 
 to exhibit symptoms of decay ; when the intellectual 
 progress of the world appeared to have reached its limit, 
 without supplying man's moral needs; we find the great 
 Epoch in the Providential History of the world. We 
 find the announcement of a Dispensation by which man's 
 deficiencies shall be supplied and his aspirations ful- 
 filled : we find a provision for the purification, the sup- 
 port, and the ultimate beatification of those who use the 
 provided means. And thus the providential course of 
 the world becomes consistent and intelligible. 
 
 4. The Sacred Narrative. But with the new Dispen- 
 sation, we receive, not only an account of its own scheme 
 and history, but also a written narrative of the providen- 
 tial course of the world from the earliest times, and even 
 from its first creation. This narrative is recognized and 
 authorized by the new dispensation, and accredited by 
 some of the same evidences as the dispensation itself. 
 That the existence of such a sacred narrative should be 
 a part of the providential order of things, cannot but 
 
684 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 appear natural ; but, naturally also, the study of it leads 
 to some difficulties. 
 
 The Sacred Narrative in some of its earliest portions 
 speaks of natural objects and occurrences respecting 
 them. In the very beginning of the course of the world, 
 we may readily believe (indeed, as we have seen in the 
 last chapter, our scientific researches lead us to believe) 
 that such occurrences were very different from anything 
 which now takes place ; different to an extent and in a 
 manner which we cannot estimate. Now the narrative 
 must speak of objects and occurrences in the words and 
 phrases which have derived their meaning from their ap- 
 plication to the existing natural state of things. When 
 applied to an initial supernatural state therefore, these 
 words and phrases cannot help being to us obscure and 
 mysterious, perhaps ambiguous and seemingly contra- 
 dictory. 
 
 5. Difficulties in interpreting the Sacred Narrative. 
 The moral and providential relations of man's condition 
 are so much more important to him than mere natural 
 relations, that at first we may well suppose he will accept 
 the Sacred Narrative, as not only unquestionable in its 
 true import, but also as a guide in his views even of 
 mere natural relations. He will try to modify the con- 
 ceptions which he entertains of objects and their pro- 
 perties, so that the Sacred Narrative of the supernatural 
 condition shall retain the first meaning which he had 
 put upon it in virtue of his own habits in the usage of 
 language. 
 
 But man is so constituted that he cannot persist in 
 this procedure. The powers and tendencies of his intel- 
 lect are such that he cannot help trying to attain true 
 conceptions of objects and their properties by the study 
 of things themselves. For instance, when he at first 
 
RELATION OF TRADITION TO PAL^TIOLOGY. 685 
 
 read of a firmament dividing the waters above from the 
 waters below, he perhaps conceived a transparent floor 
 in the skies, on which the superior waters rested, which 
 descend in rain ; but as his observations and his reason- 
 ings satisfied him that such a floor could not exist, he 
 became willing to allow (as St. Augustine allowed) that 
 the waters above the firmament are in a state of vapour. 
 And in like manner in other subjects, men, as their views 
 of nature became more distinct and precise, modified, so 
 far as it was necessary for consistency's sake, their first 
 rude interpretations of the Sacred Narrative; so that, 
 without in any degree losing its import as a view of the 
 providential course of the world, it should be so con- 
 ceived as not to contradict what they knew of the 
 natural order of things. 
 
 But this accommodation was not always made without 
 painful struggles and angry controversies. When men 
 had conceived the occurrences of the Sacred Narrative in 
 a particular manner, they could not readily and willingly 
 adopt a new mode of conception ; and all attempts to 
 recommend to them such novelties, they resisted as 
 attacks upon the sacredness of the Narrative. They had 
 clothed their belief of the workings of Providence in 
 certain images ; and they clung to those images with the 
 persuasion that, without them, their belief could not 
 subsist. Thus they imagined to themselves that the 
 earth was a flat floor, solidly and broadly laid for the 
 convenience of man ; and they felt as if the kindness of 
 Providence was disparaged, when it was maintained that 
 the earth was a globe held together only by the mutual 
 attraction of its parts. 
 
 The most memorable instance of a struggle of this 
 kind is to be found in the circumstances which attended 
 the introduction of the Heliocentric Theory of Coperni- 
 cus to general acceptance. On this controversy I have 
 
686 PHILOSOPHY OF PAL^ITIOLOGY. 
 
 already made some remarks in the History of Science*, 
 and have attempted to draw from it some lessons which 
 may be useful to us when any similar conflict of opinions 
 may occur. I will here add a few reflections with a 
 similar view. 
 
 6. Such difficulties inevitable. In the first place, I 
 remark that such modifications of the current interpre- 
 tation of the words of Scripture appear to be an inevi- 
 table consequence of the progressive character of Natural 
 Science. Science is constantly teaching us to describe 
 known facts in new language ; but the language of Scrip- 
 ture is always the same. And not only so, but the lan- 
 guage of Scripture is necessarily adapted to the common 
 state of man's intellectual developement, in which he is 
 supposed not to be possessed of science. Hence the 
 phrases used by Scripture are precisely those which 
 science soon teaches man to consider as inaccurate. Yet 
 they are not, on that account, the less fitted for their 
 proper purpose : for if any terms had been used, adapted 
 to a more advanced state of knowledge, they must have 
 been unintelligible among those to whom the Scripture 
 was first addressed. If the Jews had been told that 
 water existed in the clouds in small drops, they would 
 have marvelled that it did not constantly descend ; and 
 to have explained the reason of this, would have been 
 to teach Atmology in the sacred writings. If they had 
 read in their Scripture that the earth was a sphere, 
 when it appeared to be a plain, they would only have 
 been disturbed in their thoughts or driven to some wild 
 
 o 
 
 and baseless imaginations, by a declaration to them so 
 strange. If the Divine Speaker, instead of saying that 
 he would set his bow in the clouds, had been made 
 to declare that he would give to water the property 
 of refracting different colours at different angles, how 
 
 * B. v. c. iii. ?eot. 4. 
 
RELATION OF TRADITION TO PAL^ETIOLOGY. 687 
 
 utterly unmeaning to the hearers would the words 
 have been ! And in these cases, the expressions, being 
 unintelligible, startling, and bewildering, would have 
 been such as tended to unfit the Sacred Narrative for 
 its place in the providential dispensation of the world. 
 
 Accordingly, in the great controversy which took 
 place in Galileo's time between the defenders of the then 
 customary interpretations of Scripture, and the assertors 
 of the Copernican system of the universe, when the inno- 
 vators were upbraided with maintaining opinions contrary 
 to Scripture, they replied that Scripture was not intended 
 to teach men astronomy, and that it expressed the acts of 
 divine power in images which were suited to the ideas of 
 unscientific men. To speak of the rising and setting and 
 travelling of the sun, of the fixity and of the foundations 
 of the earth, was to use the only language which would 
 have made the Sacred Narrative intelligible. To extract 
 from these and the like expressions doctrines of science, 
 was, they declared, in the highest degree unjustifiable ; 
 and such a course could lead, they held, to no result but 
 a weakening of the authority of Scripture in proportion 
 as its credit was identified with that of these modes of 
 applying it. And this judgment has since been generally 
 assented to by those who most reverence and value the 
 study of the designs of Providence as well as that of the 
 works of nature. 
 
 7. Science tells us nothing concerning Creation. 
 Other apparent difficulties arise from the accounts given 
 in the Scripture of the first origin of the world in which 
 we live : for example, Light is represented as created 
 before the Sun. With regard to difficulties of this kind, 
 it appears that we may derive some instruction from the 
 result to which we were led in the last chapter; namely, 
 that in the sciences which trace the progress of natural 
 occurrences, we can in no case go back to an origin, but 
 
688 PHILOSOPHY OF PALJETJOLOGY. 
 
 in every instance appear to find ourselves separated from 
 it by a state of things, and an order of events, of a kind 
 altogether different from those which come under our 
 experience. The thread of induction respecting the 
 natural course of the world snaps in our fingers, when 
 we try to ascertain where its beginning is. Since, then, 
 science can teach us nothing positive respecting the 
 beginning of things, she can neither contradict nor con- 
 firm what is taught by Scripture on that subject ; and 
 thus, as it is unworthy timidity in the lover of Scripture 
 to fear contradiction, so is it ungrounded presumption 
 to look for confirmation, in such cases. The providen- 
 tial history of the world has its own beginning, and its 
 own evidence ; and we can only render the system inse- 
 cure, by making it lean on our material sciences. If 
 any one were to suggest that the nebular hypothesis 
 countenances the Scripture history of the formation of 
 this system, by showing how the luminous matter of 
 the sun might exist previous to the sun itself, we should 
 act wisely in rejecting such an attempt to weave toge- 
 ther these two heterogeneous threads ; the one a part 
 of a providential scheme, the other a fragment of a phy- 
 sical speculation. 
 
 We shall best learn those lessons of the true philoso- 
 phy of science which it is our object to collect, by attend- 
 ing to portions of science which have gone through such 
 crises as we are now considering ; nor is it requisite, for 
 this purpose, to bring forwards any subjects which are 
 still under discussion. It may, however, be mentioned 
 that such maxims as we are now endeavouring to esta- 
 blish, and the one before us in particular, bear with a 
 peculiar force upon those Palsetiological Sciences of 
 which we have been treating in the present Book. 
 
 8. Scientific views, when familiar, do not disturb the 
 authority of Scripture. There is another reflection 
 
RELATION OF TRADITION TO PAL^TIOLOGY. 689 
 
 which may serve to console and encourage us in the 
 painful struggles which thus take place, between those 
 who maintain interpretations of Scripture already preva- 
 lent and those who contend for such new ones as the 
 new discoveries of science require. It is this; that 
 though the new opinion is resisted by one party as some- 
 thing destructive of the credit of Scripture and the reve- 
 rence which is its due, yet, in fact, when the new inter- 
 pretation has been generally established and incorporated 
 with men's current thoughts, it ceases to disturb their 
 views of the authority of the Scripture or of the truth of 
 its teaching. When the language of Scripture, invested 
 with its new meaning, has become familiar to men, it is 
 found that the ideas which it calls up are quite as recon- 
 cileable as the former ones were, with the most entire 
 acceptance of the providential dispensation. And when 
 this has been found to be the case, all cultivated persons 
 look back with surprise at the mistake of those who 
 thought that the essence of the revelation was involved 
 in their own arbitrary version of some collateral circum- 
 stance in the revealed narrative. At the present day, we 
 can hardly conceive how reasonable men could ever have 
 imagined that religious reflections on the stability of the 
 earth, and the beauty and use of the luminaries which 
 revolve round it, would be interfered with by an acknow- 
 ledgment that this rest and motion are apparent only*". 
 And thus the authority of revelation is not shaken by 
 any changes introduced by the progress of science in the 
 mode of interpreting expressions which describe physical 
 objects and occurrences; provided the new interpretation 
 is admitted at a proper season, and in a proper spirit ; 
 so as to soften, as much as possible, both the public con- 
 troversies and the private scruples which almost inevit- 
 ably accompany such an alteration. 
 
 * I have here borrowed a sentence or t\vo from my own History. 
 VOL. I. W. P. Y Y 
 
690 PHILOSOPHY OF PAL33TIOLOGY. 
 
 9. When should old Interpretations be given up? But 
 the question then occurs, What is the proper season for 
 a religious and enlightened commentator to make such 
 a change in the current interpretation of sacred Scrip- 
 ture ? At what period ought the established exposition 
 of a passage to be given up, and a new mode of under- 
 standing the passage, such as is, or seems to be, required 
 by new discoveries respecting the laws of nature, accepted 
 in its place ? It is plain, that to introduce such an alter- 
 ation lightly and hastily would be a procedure fraught 
 with inconvenience ; for if the change were made in such 
 a manner, it might be afterwards discovered that it had 
 been adopted without sufficient reason, and that it was 
 necessary to reinstate the old exposition. And the minds 
 of the readers of Scripture, always to a certain extent 
 and for a time disturbed by the subversion of their long- 
 established notions, would be distressed without any 
 need, and might be seriously unsettled. While, on the 
 other hand, a too protracted and obstinate resistance to 
 the innovation, on the part of the scriptural expositors, 
 would tend to identify, at least in the minds of many, 
 the authority of the Scripture with the truth of the ex- 
 position ; and therefore would bring discredit upon the 
 revealed word, when the established interpretation was 
 finally proved to be untenable. 
 
 A rule on this subject, propounded by some of the most 
 enlightened dignitaries of the Roman Catholic church, 
 on the occasion of the great Copernican controversy 
 begun by Galileo, seems well worthy of our attention. 
 The following was the opinion given by Cardinal Bellar- 
 mine at the time: "When a demonstration shall be 
 found to establish the earth's motion, it will be proper to 
 interpret the sacred Scriptures otherwise than they have 
 hitherto been interpreted in those passages where men- 
 tion is made of the stability of the earth and movement 
 
RELATION OF TRADITION TO PALJETIOLOGY. 691 
 
 of the heavens." This appears to be a judicious and 
 reasonable maxim for such cases in general. So long as 
 the supposed scientific discovery is doubtful, the exposi- 
 tion of the meaning of Scripture given by commentators 
 of established credit is not wantonly to be disturbed : 
 but when a scientific theory, irreconcileable with this 
 ancient interpretation, is clearly proved, we must give up 
 the interpretation, and seek some new mode of under- 
 standing the passage in question, by means of which it 
 may be consistent with what we know ; for if it be not, 
 our conception of the things so described is no longer 
 consistent with itself. 
 
 It may be said that this rule is indefinite, for who 
 shall decide when a new theory is completely demon- 
 strated, and the old interpretation become untenable ? 
 But to this we may reply, that if the rule be assented to, 
 its application will not be very difficult. For when men 
 have admitted as a general rule, that the current inter- 
 pretations of scriptural expressions respecting natural 
 objects and events may possibly require, and in some 
 cases certainly will require, to be abandoned, and new 
 ones admitted, they will hardly allow themselves to con- 
 tend for such interpretations as if they were essential 
 parts of revelation ; and will look upon the change of 
 exposition, whether it come sooner or later, without 
 alarm or anger. And when men lend themselves to the 
 progress of truth, in this spirit, it is not of any material 
 importance at what period a new and satisfactory inter- 
 pretation of the scriptural difficulty is found ; since a 
 scientific exactness in our apprehension of the meaning 
 of such passages as are now referred to is very far from 
 being essential to our full acceptance of revelation. 
 
 10. In what Spirit should the Change be accepted? 
 Still these revolutions in scriptural interpretation 
 must always have in them something which distresses 
 
 Y Y 2 
 
692 PHILOSOPHY OF PAJJETIOLOGY. 
 
 and disturbs religious communities. And such uneasy 
 feelings will take a different shape, according as the 
 community acknowledges or rejects a paramount inter- 
 pretative authority in its religious leaders. In the case 
 in which the interpretation of the Church is binding 
 upon all its members, the more placid minds rest in 
 peace upon the ancient exposition, till the spiritual 
 authorities announce that the time for the adoption of 
 a new view has arrived ; but in these circumstances, the 
 more stirring and inquisitive minds, which cannot refrain 
 from the pursuit of new truths and exact conceptions, 
 are led to opinions which, being contrary to those of the 
 Church, are held to be sinful. On the other hand, if 
 the religious constitution of the community allow and 
 encourage each man to study and interpret for himself 
 the Sacred Writings, we are met by evils of another 
 kind. In this case, although, by the unforced influence 
 of admired commentators, there may prevail a general 
 agreement in the usual interpretation of difficult pas- 
 sages, yet as each reader of the Scripture looks upon 
 the sense which he has adopted as being his own inter- 
 pretation, he maintains it, not with the tranquil acquies- 
 cence of one who has deposited his judgment in the 
 hands of his Church, but with the keenness and strenu- 
 ousness of self-love. In such a state of things, though 
 no judicial severities can be employed against the 
 innovators, there may arise more angry controversies 
 than in the other case. 
 
 It is impossible to overlook the lesson which here 
 offers itself, that it is in the highest degree unwise in 
 the friends of religion, whether individuals or commu- 
 nities, unnecessarily to embark their credit in expositions 
 of Scripture on matters which appertain to natural 
 science. By delivering physical doctrines as the teach- 
 ing of revelation, religion may lose much, but cannot 
 
RELATION OF TRADITION TO PAL^TIOLOGY. G93 
 
 gain anything. This maxim of practical wisdom has 
 often been urged by Christian writers. Thus St. Augus- 
 tin says * : "In obscure matters and things far removed 
 from our senses, if we read anything, even in the divine 
 Scripture, which may produce diverse opinions without 
 damaging the faith which we cherish, let us not rush 
 headlong by positive assertion to either the one opinion 
 or the other ; lest, when a more thorough discussion has 
 shown the opinion which we had adopted to be false, 
 our faith may fall with it : and we should be found con- 
 tending, not for the doctrine of the sacred Scriptures, 
 but for our own ; endeavouring to make our doctrine to 
 be that of the Scriptures, instead of taking the doctrine 
 of the Scriptures to be ours." And in nearly the same 
 spirit, at the time of the Copernican controversy, it was 
 thought proper to append to the work of Copernicus a 
 postil, to say that the work was written to account for 
 the phenomena, and that people must not run on blindly 
 and condemn either of the opposite opinions. Even 
 when the Inquisition, in 1616, thought itself compelled 
 to pronounce a decision upon this subject, the verdict 
 was delivered in very moderate language ; that " the 
 doctrine of the earth's motion appeared to be contrary 
 to Scripture :" and yet, moderate as this expression is, 
 it has been blamed by judicious members of the Roman 
 church as deciding a point such as religious authorities 
 ought not to pretend to decide ; and has brought upon 
 that church no ordinary weight of general condemna- 
 tion. Kepler pointed out, in his lively manner, the 
 imprudence of employing the force of religious autho- 
 rities on such subjects: Acies dolabrce in ferrum illisa, 
 postea nee in lignum valet amplius. Capiat hoc cujus 
 interest. " If you will try to chop iron, the axe becomes 
 unable to cut even wood. I warn those whom it concerns." 
 * Lib. i. dc Gcnesi, cap. xviii. 
 
694 PHILOSOPHY OF PAL^ETIOLOGY. 
 
 11. In what Spirit should the Change be urged? - 
 But while we thus endeavour to show in what manner 
 the interpreters of Scripture may most safely and most 
 properly accept the discoveries of science, we must not 
 forget that there may be errours committed on the other 
 side also ; and that men of science, in bringing forward 
 views which may for a time disturb the minds of lovers 
 of Scripture, should consider themselves as bound by 
 strict rules of candour, moderation, and prudence. In- 
 tentionally to make their supposed discoveries a means 
 of discrediting, contradicting, or slighting the sacred 
 Scriptures, or the authority of religion, is in them unpar- 
 donable. As men who make the science of Truth the 
 business of their lives, and are persuaded of her genuine 
 superiority, and certain of her ultimate triumph, they 
 are peculiarly bound to urge her claims in a calm and 
 temperate spirit ; not forgetting that there are other 
 kinds of truth besides that which they peculiarly study. 
 They may properly reject authority in matters of science; 
 but they are to leave it its proper office in matters of 
 religion. I may here again quote Kepler's expressions : 
 " In Theology we balance authorities, in Philosophy we 
 weigh reasons. A holy man was Lactantius who denied 
 that the earth was round ; a holy man was Augustin, 
 who granted the rotundity, but denied the antipodes; 
 a holy thing to me is the Inquisition, which allows the 
 smallness of the earth, but denies its motion ; but more 
 holy to me is Truth ; and hence I prove, from philo- 
 sophy, that the earth is round, and inhabited on every 
 side, of small size, and in motion among the stars, and 
 this I do with no disrespect to the Doctors." I the 
 more willingly quote such a passage from Kepler, be- 
 cause the entire ingenuousness and sincere piety of his 
 character does not allow us to suspect in him anything 
 of hypocrisy or latent irony. That similar professions 
 
RELATION OF TRADITION TO PAL^STIOLOGY. 695 
 
 of respect may be made ironically, we have a noted 
 example in the celebrated Introduction to Galileos 
 Dialogue on the Copernican System ; probably the part 
 which was most offensive to the authorities. "Some 
 years ago," he begins, " a wholesome edict was promul- 
 gated at Rome, which, in order to check the perilous 
 scandals of the present age, imposed silence upon the 
 Pythagorean opinion of the mobility of the earth. 
 There were not wanting," he proceeds, "persons who 
 rashly asserted that this decree was the result, not of a 
 judicious inquiry, but of passion ill-informed ; and com- 
 plaints were heard that counsellors, utterly unacquainted 
 with astronomical observation, ought not to be allowed, 
 with their sudden prohibitions, to clip the wings of spe- 
 culative intellects. At the hearing of rash lamentations 
 like these, my zeal could not keep silence" And he then 
 goes on to say, that he wishes, in his Dialogue, to show 
 that the subject had been fully examined at Rome. 
 Here the irony is quite transparent, and the sarcasm 
 glaringly obvious. I think we may venture to say that 
 this is not the temper in which scientific questions 
 should be treated ; although by some, perhaps, the pro- 
 hibition of public discussion may be considered as jus- 
 tifying any evasion which is likely to pass unpunished. 
 
 12. Duty of Mutual Forbearance. We may add, as 
 a further reason for mutual forbearance in such cases, 
 that the true interests of both parties are the same. 
 The man of science is concerned, no less than any other 
 person, in the truth and import of the divine dispensa- 
 tion ; the religious man, no less than the man of science, 
 is, by the nature of his intellect, incapable of believing 
 two contradictory declarations. Hence they have both 
 alike a need for understanding the Scripture in some 
 way in which it shall be consistent with their under- 
 standing of nature. It is for their common advantage 
 
696 PHILOSOPHY OF PALJETIOLOGY. 
 
 to conciliate, as Kepler says, the finger and the tongue 
 of God, his works and his word. And they may find 
 abundant reason to bear with each other, even if they 
 should adopt for this purpose different interpretations, 
 each finding one satisfactory to himself; or if any one 
 should decline employing his thoughts on such subjects 
 at all. I have elsewhere * quoted a passage from Kep- 
 ler f which appears to me written in a most suitable 
 spirit : " I beseech my reader that, not unmindful of the 
 Divine goodness bestowed upon man, he do with me 
 praise and celebrate the wisdom of the Creator, which I 
 open to him from a more inward explication of the form 
 of the world, from a searching of causes, from a detec- 
 tion of the errours of vision; and that thus not only 
 in the firmness and stability of the earth may we per- 
 ceive with gratitude the preservation of all living things 
 in nature as the gift of God : but also that in its motion, 
 so recondite, so admirable, we may acknowledge the 
 wisdom of the Creator. But whoever is too dull to 
 receive this science, or too weak to believe the Coper- 
 nican system without harm to his piety, him, I say, I 
 advise that, leaving the school of astronomy, and con- 
 demning, if so he please, any doctrines of the philo- 
 sophers, he follow his own path, and desist from this 
 wandering through the universe; and that, lifting up 
 his natural eyes, with which alone he can see, he pour 
 himself out from his own heart in worship of God the 
 Creator, being certain that he gives no less worship to 
 God than the astronomer, to whom God has given to 
 see more clearly with his inward eyes, and who, from 
 what he has himself discovered, both can and will glorify 
 God." 
 
 13. Case of Galileo. I may perhaps venture here to 
 make a remark or two upon this subject with reference 
 
 * Bridgervaier Tr., p. 314. t Com. Stell Mart., Introd. 
 
RELATION OF TRADITION TO TAL^TIOLOGY. GO 7 
 
 to a charge brought against a certain portion of the His- 
 tory of the Inductive Sciences. Complaint has been 
 made"- that the character of the Roman church, as 
 shown in its behaviour towards Galileo, is misrepre- 
 sented in the account given of it in the History of 
 Astronomy. It is asserted that Galileo provoked the 
 condemnation he incurred ; first, by pertinaciously de- 
 manding the assent of the ecclesiastical authorities to 
 his opinion of the consistency of the Copernican doctrine 
 with Scripture ; and afterwards by contumaciously, and, 
 as we have seen, contumeliously violating the silence 
 which the Church had enjoined upon him. It is further 
 declared that the statement which represents it as the 
 habit of the Roman church to dogmatize on points of 
 natural science is unfounded ; as well as the opinion that 
 in consequence of this habit, new scientific truths were 
 promulgated less boldly in Italy than in other countries. 
 I shall reply very briefly on these subjects ; for the deci- 
 sion of them is by no means requisite in order to esta- 
 blish the doctrines to which I have been led in the 
 present chapter, nor, I hope, to satisfy my reader that 
 my views have been collected from an impartial con- 
 sideration of scientific history. 
 
 With regard to Galileo, I do not think it can be 
 denied that he obtruded his opinions upon the ecclesias- 
 tical authorities in an unnecessary and imprudent man- 
 ner. He was of an ardent character, strongly convinced 
 himself, and urged on still more by the conviction which 
 he produced among his disciples, and thus he became 
 impatient for the triumph of truth. This judgment of 
 him has recently been delivered by various independent 
 authorities, and has undoubtedly considerable founda- 
 tion f. As to the question whether authority in matters 
 
 * Dublin Review, No. ix., July, 1838, p. 72. 
 
 t Besides the Dublin Review, I may quote the Edinburgh Rcvicn\ 
 
 which 
 
698 PHILOSOPHY OF PAL^ITIOLOGY. 
 
 of natural science were habitually claimed by the autho- 
 rities of the Church of Rome, I have to allow that I 
 cannot produce instances which establish such a habit. 
 We who have been accustomed to have daily before our 
 eyes the Monition which the Romish editors of Newton 
 thought it necessary to prefix Cceterum latis a summo 
 Pontifice contra telluris motum Decretis, nos obsequi 
 prqfitemur were not likely to conjecture that this was 
 a solitary instance of the interposition of the Papal 
 authority on such subjects. But although it would be 
 easy to find declarations of heresy delivered by Romish 
 Universities, and writers of great authority, against 
 tenets belonging to the natural sciences, I am not aware 
 that any other case can be adduced in which the Church 
 or the Pope can be shown to have pronounced such a 
 sentence. I am well contented to acknowledge this ; 
 for I should be far more gratified by finding myself 
 compelled to hold up the seventeenth century as a model 
 for the nineteenth in this respect, than by having to sow 
 enmity between the admirers of the past and the present 
 through any disparaging contrast*. 
 
 With respect to the attempt made in my History to 
 characterize the intellectual habits of Italy as produced 
 
 which I suppose will not be thought likely to have a bias in favour of 
 the exercise of ecclesiastical authority in matters of science; though 
 certainly there is a puerility in the critic's phraseology which does not 
 add to the weight of his judgment. " Galileo contrived to surround 
 the truth with every variety of obstruction. The tide of knowledge, 
 which had hitherto advanced in peace, he crested with angry breakers, 
 and he involved in its surf both his friends and his foes." Ed. Rev., 
 No. cxxiii. p. 126. 
 
 * I may add that the most candid of the adherents of the Church 
 of Rome condemn the assumption of authority in matters of science, 
 made, in this one instance at least, by the ecclesiastical tribunals. The 
 author of the Ages of Faith (Book vm. p. 248), says, " A Congrega- 
 tion, it is to be lamented, declared the now system to be opposed to 
 Scripture, arid therefore heretical." 
 
RELATION OF TRADITION TO PAL^ETIOLOGY. 699 
 
 by her religious condition, certainly it would ill become 
 any student of the history of science to speak slightingly 
 of that country, always the mother of sciences, always 
 ready to catch the dawn and hail the rising of any new 
 light of knowledge. But I think our admiration of this 
 activity and acuteness of mind is by no means incon- 
 sistent with the opinion, that new truths were promul- 
 gated more boldly beyond the Alps, and that the subtilty 
 of the Italian intellect loved to insinuate what the 
 rough German bluntly asserted. Of the decent duplicity 
 with which forbidden opinions were handled, the re- 
 viewer himself gives us instances, when he boasts of the 
 liberality with which ,Copernican professors were placed 
 in important stations by the ecclesiastical authorities,* 
 soon after the doctrine of the motion of the earth had 
 been declared by the same authorities to be contrary to 
 Scripture. And in the same spirit is the process of 
 demanding from Galileo a public and official recanta- 
 tion of opinions which he had repeatedly been told by 
 his ecclesiastical superiors he might hold as much as he 
 pleased. I think it is easy to believe that among per- 
 sons so little careful to reconcile public profession with 
 private conviction, official decorum was all that was 
 demanded. When Galileo had made his renunciation of 
 the earth's motion on his knees, he rose and said, as we 
 are told, E pur si muove "and yet it does move." 
 This is sometimes represented as the heroic soliloquy of 
 a mind cherishing its conviction of the truth, in spite of 
 persecution ; I think we may more naturally conceive it 
 uttered as a playful epigram in the ear of a cardinal's 
 secretary, with a full knowledge that it would be imme- 
 diately repeated to his master*. 
 
 Besides the Ideas involved in the material sciences, 
 
 * I have somewhat further discussed the case of Galileo in the 
 second edition of the History, Vol. i. p. 418, and Notes (Q) and (R). 
 
700 PHILOSOPHY OF PAL^TIOLOGY. 
 
 of which we have already examined the principal ones, 
 there is one Idea or Conception which our Sciences do 
 not indeed include, but to which they not obscurely 
 point ; and the importance of this Idea will make it 
 proper to speak of it, though this must be done very 
 briefly. 
 
 CHAPTER V. 
 OF THE CONCEPTION OF A FIRST CAUSE. 
 
 1. AT the end of the last chapter but one, we were led 
 to this result, that we cannot, in any of the Palsetiolo- 
 
 *gical Sciences, ascend to a beginning which is of the same 
 nature as the existing cause of events, and which depends 
 upon causes that are still in operation. Philosophers 
 never have demonstrated, and probably never will be 
 able to demonstrate, what was the original condition of 
 the solar system, of the earth, of the vegetable and animal 
 worlds, of languages, of arts. On all these subjects the 
 course of investigation, followed backwards as far as our 
 materials allow us to pursue it, ends at last in an impe- 
 netrable gloom. We strain our eyes in vain when we 
 try, by our natural faculties, to discern an Origin. 
 
 2. Yet speculative men have been constantly employed 
 in attempts to arrive at that which thus seems to be 
 placed out of their reach. The Origin of Languages, the 
 Origin of the present Distribution of Plants and Animals, 
 the Origin of the Earth, have been common subjects of 
 diligent and persevering inquiry. Indeed inquiries re- 
 specting such subjects have been, at least till lately, the 
 usual form which Palsetiological researches have assumed. 
 Cosmogony, the origin of the world, of which, in such 
 speculations, the earth was considered as a principal part, 
 has been a favourite study both of ancient and of modern 
 
CONCEPTION OF A FIRST CAUSE. 701 
 
 times : and most of the attempts at Geology previous to 
 the present period have been Cosmogonies or Geogonies, 
 rather than that more genuine science which we have 
 endeavoured to delineate. Again : Glossology, though 
 now an extensive body of solid knowledge, was mainly 
 brought into being by inquiries concerning the Original 
 Language spoken by men ; and the nature of the first 
 separation and diffusion of languages, the first peopling 
 of the earth by man and by animals, were long sought 
 after with ardent curiosity, although of course with 
 reference to the authority of the Scriptures, as well as 
 the evidence of natural phenomena. Indeed the interest 
 of such inquiries even yet is far from being extinguished. 
 The disposition to explore the past in the hope of find- 
 ing, by the light of natural reasoning as well as by the 
 aid of revelation, the origin of the present course of 
 things, appears to be unconquerable. "What was the 
 beginning?" is a question which the human race cannot 
 desist from perpetually asking. And no failure in ob- 
 taining a satisfactory answer can prevent inquisitive spi- 
 rits from again and again repeating the inquiry, although 
 the blank abyss into which it is uttered does not even 
 return an echo. 
 
 3. What, then, is the reason of an attempt so perti- 
 nacious yet so fruitless? By what motive are we im- 
 pelled thus constantly to seek what we can never find ? 
 Why are the errour of our conjectures, the futility of our 
 reasonings, the precariousness of our interpretations, over 
 and over again proved to us in vain ? Why is it impos- 
 sible for us to acquiesce in our ignorance and to relin- 
 quish the inquiry? Why cannot we content ourselves 
 with examining those links of the chain of causes which 
 are nearest to us; those in which the connexion is 
 intelligible and clear; instead of fixing our attention 
 upon those remote portions where we can no longer 
 
702 PHILOSOPHY OF PALJETIOLOGY. 
 
 estimate its coherence? In short, why did not men 
 from the first take for the subject of their specula- 
 tions the Course of Nature rather than the Origin of 
 Things? 
 
 To this we reply, that in doing what they have thus 
 done, in seeking what they have sought, men are im- 
 pelled by an intellectual necessity. They cannot conceive 
 a Series of connected occurrences without a Commence- 
 ment ; they cannot help supposing a cause for the Whole, 
 as well as a cause for each part ; they cannot be satisfied 
 with a succession of causes without assuming a First 
 Cause. Such an assumption is necessarily impressed 
 upon our minds by our contemplation of a series of 
 causes and effects ; that there must be a First Cause, is 
 accepted by all intelligent reasoners as an Axiom : and 
 like other Axioms, its truth is necessarily implied in the 
 Idea which it involves. 
 
 4. The evidence of this axiom may be illustrated in 
 several ways. In the first place, the axiom is assumed 
 in the argument usually offered to prove the existence of 
 the Deity. Since, it is said, the world now exists, and 
 since nothing cannot produce something, something must 
 have existed from eternity. This Something is the First 
 Cause : it is God. 
 
 Now what I have to remark here is this : the con- 
 clusiveness of this argument, as a proof of the existence 
 of one independent, immutable Deity, depends entirely 
 upon the assumption of the axiom above stated. The 
 World, a series of causes and effects, exists : therefore 
 there must be, not only this series of causes and effects, 
 but also a First Cause. It will be easily seen, that with- 
 out the axiom, that in every series of causes and effects 
 there must be a First Cause, the reasoning is altogether 
 inconclusive. 
 
 5. Or to put the matter otherwise : The argument 
 
CONCEPTION OF A FIRST CAUSE. 703 
 
 for the existence of the Deity was stated thus : Something 
 exists, therefore something must have existed from eter- 
 nity. "Granted," the opponent might say; "but this 
 something which has existed from eternity, why may it 
 not be this very series of causes and effects which is now 
 going on, and which appears to contain in itself no indi- 
 cation of beginning or end?" And thus, without the 
 assumption of the necessity of a First Cause, the force 
 of the argument may be resisted. 
 
 6. But, it may be asked, how do those who have 
 written to prove the existence of the Deity reply to 
 such an objection as the one just stated? It is natural 
 to suppose that, on a subject so interesting and so long 
 discussed, all the obvious arguments with their replies, 
 have been fully brought into view. What is the result 
 in this case ? 
 
 The principal modes of replying to the above objec- 
 tion, that the series of causes and effects which now 
 exists, may have existed from eternity, appear to be 
 these. 
 
 In the first place, our minds cannot be satisfied with 
 a series of successive, dependent, causes and effects, 
 without something first and independent. We pass from 
 effect to cause, and from that to a higher cause, in search 
 of something on which the mind can rest ; but if we can 
 do nothing but repeat this process, there is no use in it. 
 We move our limbs, but make no advance. Our ques- 
 tion is not answered, but evaded. The mind cannot 
 acquiesce in the destiny thus presented to it, of being 
 referred from event to event, from object to object, along 
 an interminable vista of causation and time. Now this 
 mode of stating the reply, to say that the mind cannot 
 thus be satisfied, appears to be equivalent to saying that 
 the mind is conscious of a Principle, in virtue of which 
 such a view as this must be rejected ; the mind takes 
 
704 PHILOSOPHY OF PAL^TIOLOGY. 
 
 refuge in the assumption of a First Cause, from an 
 employment inconsistent with its own nature. 
 
 7. Or again, we may avoid the objection, by putting 
 the argument for the existence of a Deity in this form : 
 The series of causes and effects which we call the world, 
 or the course of nature, may be considered as a whole, 
 and this whole must have a cause of its existence. The 
 whole collection of objects and events may be compre- 
 hended as a single effect, and of this effect there must be 
 a cause. This Cause of the Universe must be superior 
 to, and independent of the special events, which, happen- 
 ing in time, make up the universe of which He is the 
 cause. He must exist and exercise causation, before 
 these events can begin : He must be the First Cause. 
 
 Although the argument is here somewhat modified 
 in form, the substance is the same as before. For the 
 assumption that we may consider the whole series of 
 causes and effects as a single effect, is equivalent to the 
 assumption that besides partial causes we must have a 
 First Cause. And thus the Idea of a First Cause, and 
 the axiom which asserts its necessity, are recognized in 
 the usual argumentation on this subject. 
 
 8. This Idea of a First Cause, and the principle 
 involved in the Idea, have been the subject of discussion 
 in another manner. As we have already said, we assume 
 as an axiom that a First Cause must exist ; and we assert 
 that God, the First Cause, exists eternal and immutable, 
 by the necessity which the axiom implies. Hence God 
 is said to exist necessarily ; to be a necessarily existing 
 being. And when this necessary existence of God had 
 been spoken of, it soon began to be contemplated as a 
 sufficient reason, and as an absolute demonstration of His 
 existence ; without any need of referring to the world as 
 an effect, in order to arrive at God as the cause. And 
 thus men conceived that they had obtained a proof of 
 
CONCEPTION OF A FIRST CAUSE. 705 
 
 the existence of the Deity, d priori, from Ideas, as well 
 as d posteriori, from Effects. 
 
 9. Thus, Thomas Aquinas employs this reasoning to 
 prove the eternity of God*. "Oportet ponere aliquod 
 primum necessarium quod est per se ipsum necessarium ; 
 et hoc est Deus, cum sit prima causa ut dictum est: igitur 
 Deus seternus est, cum omne necessarium per se sit seter- 
 num." It is true that the schoolmen never professed to 
 be able to prove the existence of the Deity d priori : but 
 they made use of this conception of necessary existence 
 in a manner which approached very near to such an 
 attempt. Thus Suarezf discusses the question, " Utrum 
 aliquo modo possit d priori demonstrari Deum esse." 
 And resolves the question in this manner: "Ad hunc 
 ergo modum dicendum est : Demonstrate d posteriori 
 Deum esse ens necessarium et a se, ex hoc attribute 
 posse d priori demonstrari prseter illud non posse esse 
 aliud ens necessarium et a se, et consequenter demon- 
 strari Deum esse." 
 
 But in modern times attempts were made by Des- 
 cartes and Samuel Clarke, to prove the Divine exist- 
 ence at once d priori, from the conception of necessary 
 existence ; which, it was argued, could not subsist with- 
 out actual existence. This argumentation was acutely 
 and severely criticized by Dr. Waterland. 
 
 10. Without dwelling upon a subject, the discussion of 
 which does not enter into the design of the present work, 
 I may remark that the question whether an d priori proof 
 of the existence of a First Cause be possible, is a ques- 
 tion concerning the nature of our Ideas, and the evidence 
 of the axioms which they involve, of the same kind as 
 many questions which we have already had to discuss. 
 Is our Conception or Idea of a First Cause gathered from 
 
 * Aquin. Conlr. Genii/. Lib. i. c. xiv. p. 21. 
 t Metaphyt. Tom. n. Disp. xxix. sect. 3, p. 28. 
 
 VOL. i. w. r. Z z 
 
706 PHILOSOPHY OF PALjETIOLOGY. 
 
 the effects we see around us ? It is plain that we must 
 answer, here as in other cases, that the Idea is not 
 extracted from the phenomena, but assumed in order that 
 the phenomena may become intelligible to the mind ; 
 that the Idea is a necessary one, inasmuch as it does not 
 depend upon observation for its evidence ; but that it 
 depends upon observation for its developement, since 
 without some observation, we cannot conceive the mind 
 to be cognizant of the relation of causation at all. In 
 this respect, however, the Idea of a First Cause is no less 
 necessary than the ideas of Space, or Time, or Cause in 
 general. And whether we call the reasoning derived 
 from such a necessity an argument a priori or a posteri- 
 ori, in either case it possesses the genuine character of 
 demonstration, being founded upon axioms which com- 
 mand universal assent. 
 
 11. I have, however, spoken of our Conception rather 
 than of our Idea of a First Cause ; for the notion of a 
 First Cause appears to be rather a modification of the 
 Fundamental Idea of Cause, which was formerly dis- 
 cussed, than a separate and peculiar Idea. And the 
 Axiom, that there must be a First Cause, is recognized 
 by most persons as an application of the general Axiom 
 of Causation, that every effect must have a cause ; this 
 latter Axiom being applied to the world, considered in 
 its totality, as a single effect. This distinction, however, 
 between an Idea and a Conception, is of no material 
 consequence to our argument; provided we allow the 
 maxim, that there must be a First Cause, to be neces- 
 sarily and evidently true ; whether it be thought better 
 to speak of it as an independent Axiom, or to consider 
 it as derived from the general Axiom of Causation. 
 
 12. Thus we necessarily infer a First Cause, although 
 the Palsetiological Sciences only point towards it, and do 
 not lead us to it. But I must observe further ; that in 
 
CONCEPTION OF A FIRST CAUSE. 707 
 
 each of the series of events which form the subject of 
 Palsetiological research, the First Cause is the same. 
 Without here resting upon reasoning founded upon our 
 Conception of a First Cause, I may remark that this 
 identity is proved by the close connexion of all the 
 branches of natural science, and the way in which the 
 causes and the events of each are interwoven with those 
 which belong to the others. We must needs believe 
 that the First Cause which produced the earth and its 
 atmosphere is also the Cause of the plants which clothe 
 its surface ; that the First Cause of the vegetable and of 
 the animal world are the same; that the First Cause 
 which produced light produced also eyes ; that the First 
 Cause which produced air and organs of articulation pro- 
 duced also language and the faculties by which language 
 is rendered possible : and if those faculties, then also all 
 man's other faculties; the powers by which, as we have 
 said, he discerns right and wrong, and recognizes a pro- 
 vidential as well as a natural course of things. Nor can 
 we think otherwise than that the Being who gave these 
 faculties, bestowed them for some purpose; bestowed 
 them for that purpose which alone is compatible with 
 their nature : the purpose, namely, of guiding and ele- 
 vating man in his present career, and of preparing him 
 for another state of being to which they irresistibly direct 
 his hopes. And thus, although, as we have said, no one 
 of the Palsetiological Sciences can be traced continuously 
 to an Origin, yet they not only each point to an Origin, 
 but all to the same Origin. Their lines are broken indeed, 
 as they run backwards into the early periods of the world, 
 but yet they all appear to converge to the same invisible 
 point. And this point, thus indicated by the natural 
 course of things, can be no other than that which is 
 disclosed to us as the starting point of the providential 
 course of the world; for we are persuaded by such reasons 
 as have just been hinted, that the Creator of the natural 
 
708 PHILOSOPHY OF PAUETIOLOGY. 
 
 world can be no other than the Author and Governor 
 and Judge of the moral and spiritual world. 
 
 13. Thus we are led, by our material sciences, and 
 especially by the Palsetiological class of them, to the 
 borders of a higher region, and to a point of view from 
 which we have a prospect of other provinces of know- 
 ledge, in which other faculties of man are concerned 
 besides his intellectual, other interests involved besides 
 those of speculation. On these it does not belong to our 
 present plan to dwell : but even such a brief glance as 
 we have taken of the connexion of material with moral 
 speculations may not be useless, since it may serve to 
 show that the principles of truth which we are now labo- 
 riously collecting among the results of the physical sci- 
 ences, may possibly find some application in those parts 
 of knowledge towards which men most naturally look 
 with deeper interest and more serious reverence. 
 
 We have been employed up to the present stage 
 of this work in examining the materials of knowledge, 
 namely, Facts and Ideas ; and we have dwelt particularly 
 upon the latter element ; inasmuch as the consideration 
 of it is, on various accounts, and especially at the present 
 time, by far the most important. We have now to pro- 
 ceed to the remainder of our task ; to determine the 
 processes by which those materials may actually be made 
 to constitute knowledge. We have surveyed the stones 
 of our building : we have found them exactly squared, 
 and often curiously covered with significant imagery and 
 important inscriptions. We have now to discover how 
 they may best be fitted into their places, and cemented 
 together, so that rising stage above stage, they may grow 
 at last into that fair and lofty temple of Truth for which 
 we cannot doubt that they were intended by the Great 
 Architect. 
 
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