METEOROLOGY. 
 
By the same Author. 
 
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 PHYSICAL GEOGRAPHY. 
 
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 THE TELESCOPE. 
 
BY 
 
 SIR JOHN F. W. HERSCHEL, BART., K.H. 
 
 M.A., D.C.L., F.R.S. L. & B., HON. M.R.I.A., F.R.A.S. 
 F.G.S., M.C.U.P.S., Ac. Ac. 
 
 SECOND EDITION. 
 
 EDINBURGH: 
 
 ADAM AND CHARLES BLACK 
 
 1862. 
 

 
 
 
INTRODUCTION. 
 
 The little Essay which follows appeared originally 
 as an article in the new edition of the Encyclo- 
 paedia Britannica. The editors of that work being 
 desirous of publishing it separately, have oblig- 
 ingly afforded me an opportunity of revising it 
 during its re-impression, an opportunity of which, 
 however, I have only so far availed myself as to 
 correct some few errors of slight importance — to 
 insert, here and there, in the form of notes and 
 brief additions to the text, some notices of recent 
 speculations or observations not involving large 
 additions, and to explain a little more at large 
 certain points which seemed to require further 
 
VI 
 
 INTRODUCTION. 
 
 elucidation. This has been more especially the 
 case in respect of the theory of the annual and 
 diurnal fluctuations of the barometer, a point of 
 a very delicate nature, and on which the views of 
 meteorologists are so far from being in harmony 
 with each other, or with nature, that M. Dove in 
 one of his most recent publications instances the 
 cases of M. Lamont, who attributes these pheno- 
 mena to an electric attraction exerted by the sun, 
 of Mr. Broun who seeks their origin in the sun’s 
 magnetism, and of M. Henry who looks to the 
 resistance of the ether as their cause. To have 
 extended the Encyclopaedic article into a syste- 
 matic, or anything like a complete treatise, would 
 have required more time and labour than I have 
 at my disposal. 
 
 Where anything beyond mere numerical cor- 
 rections and slight alteration of expressions has 
 been introduced, the interpolations have been 
 distinguished from the original text^ if in an 
 
INTRODUCTION. vii 
 
 entire paragraph, by the addition of an italic 
 letter to the number of the paragraph as, for 
 instance, in Art. (77, a), or if in the form of a 
 note or of an insertion in the text of a paragraph 
 already numbered, by placing the new matter 
 between brackets thus [ ] or by express mention. 
 
 J. F. W. HERSCHEL. 
 
 COLLINGWOOD, APRIL 2 , 1861 . 
 

 
 '■ *v 
 
 
 
 * ♦ 
 
 
 
METEOROLOGY. 
 
 (1.) Meteorology, which, in its ancient and etymolo- 
 gical sense, included all the appearances of the heavens, 
 as well astronomical as atmospheric, is at present 
 restricted in its meaning to the description and explana- 
 tion of those phenomena which group themselves under 
 the heads of the weather, of the seasons, and of climate 
 — phenomena which, scientifically regarded, are refer- 
 able almost entirely to the agency of those laws which 
 govern the ever- varying affections of the atmosphere of 
 our globe in its relations to heat, moisture, and elec- 
 tricity, and the movements which the changes of those 
 relations, brought about by astronomical or other causes, 
 impress upon its parts. 
 
 (2.) Were it not for this last-mentioned class of rela- 
 tions, those, namely, which depend on the mobility of 
 our atmosphere, and the consequent perpetual local 
 interchange of its parts more or less heated, and more 
 or less moist, inter se , the problems presented by 
 meteorology would be of a very simple nature. What- 
 ever be the temperature of the interior of our globe 
 
 B 
 
2 
 
 METEOKOLOGY. 
 
 (and there is every reason to believe it very high), it 
 has been amply demonstrated, that the escape of its 
 internal heat into space through its surface, for many 
 ages past and to come, may be regarded as uniform, and 
 so excessively slow as to he quite inappretiahle as a cause 
 of any portion of the temperature prevalent on the 
 surface, still more so of any variation in that element. 
 Local conflagrations and volcanoes (whatever influence 
 geologists may ascribe to the latter in earlier states of 
 our planet) are absolutely insignificant at present for the 
 supply of warmth, so that it is to the sun alone that we 
 have to look as the ultimate source of heat, and there- 
 fore, also, in all probability, of electrical excitement. 
 Supposing, then, no lateral communication or transfer 
 between the columns of air incumbent on adjacent parts 
 of the earth's surface, the totality of atmospheric and 
 climatic change in any given locality would be limited 
 to periodical and perfectly regular fluctuations of tem- 
 perature depending on the direct heating power of the 
 sun at its various altitudes above the horizon during 
 the day and its withdrawal during the night, and to 
 the alternate generation and condensation of vapour 
 equally periodic and regular, immediately consequent 
 on such fluctuations, over those parts of the surface 
 occupied by water. No rain would ever fall on, or cloud 
 form over, any part of the land, which would be per- 
 fectly arid, and dependent for its temperature, at any 
 spot, on the greater or less aptitude of its materials at 
 that spot for absorbing and retaining the sun's rays. 
 It is needless to add that, under such circumstances, 
 
GENERAL CONSIDERATIONS. 
 
 3 
 
 the ocean only would possess the conditions indis- 
 pensable to animal or vegetable life. 
 
 (3.) The mobility of the air, while it destroys this 
 simplicity of sequence, and substitutes for it the variety 
 and complexity of phenomena we actually observe, lands 
 us, while seeking for their explanation, among mechani- 
 cal difficulties of a very high order. If there be one part 
 of dynamical science more abstruse and unapproachable 
 than another, it is the doctrine of the propagation of 
 motion in fluids, and especially in elastic fluids like the 
 air, even when the amount and application of the original 
 acting forces are known and calculable. But in this case, 
 the acting forces consist in local dilatations of parts of 
 the atmosphere by the sun’s heat during the day, and 
 contractions by cold during the night — in the permanent 
 difference of temperature in the equatorial and polar 
 regions — in the evaporation of moisture in some parts, 
 and its precipitation in rain in others, which act 
 directly as motive forces displacing air, and indirectly 
 by carrying heat in a latent form from one region to 
 another. And as if the problems arising out of these 
 considerations alone were not sufficiently complex and 
 intractable, the occupation of one part of the surface 
 of our globe by land and another by sea ; differing as 
 they do in their relations to heat, in their evaporation 
 of moisture, and in their resistance to the motion of 
 bodies of air passing over them ; the irregular form of 
 the continents, and the existence on them of mountain 
 chains which confine, obstruct, and divert the free 
 courses of aerial currents — all concur to fill the subject 
 
4 
 
 METEOROLOGY. 
 
 of meteorology with, difficulties utterly insurmountable 
 if attacked by those methods of calculation which 
 have proved so signally successful in many other 
 branches of science. 
 
 (4.) And yet it is these very difficulties, and this 
 excessive complication, which, by forcing us to abandon 
 the deductive mode of philosophizing from sheer inade- 
 quacy of methods, throws us on the opposite, or 
 inductive course of inquiry in the very attitude most 
 favourable to success. Tor it is not because the 
 general principles of dynamics are inapplicable to the 
 subject that we are deterred from resorting to them as 
 our sole dependence, but because we neither possess 
 data sufficiently wide and precise to afford ground for 
 their application, nor command enough of them, as 
 instruments, to grapple with such data in all their 
 particularity if we had them. In our assurance of 
 their general applicability , we possess an invaluable 
 clue, which precludes all groping in the dark for causes, 
 and which serves at every step to direct the course our 
 induction ought to take, and the forms in which it is 
 desirable that our acquirements should be invested so 
 as to be most available for constructing a complete 
 theory. We come to the subject, in short, as we have 
 every reason to believe, with a clear apprehension of all 
 the principal efficient causes, and a pretty distinct con- 
 ception of their direct action. It is the number and 
 simultaneous operation of their derivative causes, the 
 immense influence and complication of their indirect 
 actions, which constitute the difficulty of this branch of 
 
GENERAL CONSIDERATIONS. 5 
 
 physics. But, on the other hand, our knowledge of these 
 causes throws the whole burden of the inquiry on the 
 discovery of subordinate or derivative laws, and never 
 leaves us at a loss (as in so many other departments of 
 physical research) for the interpretation of those laws 
 when discovered, or for the best and most philoso- 
 phical way of expressing them in terms conveying 
 their true theoretical import. 
 
 (5.) And hence arises one of the most marked pecu- 
 liarities of this our science, viz., that while in respect 
 of the general explanation of its phenomena it may be 
 said to be nearly complete, inasmuch as there are few 
 of its more important facts and broad features which 
 cannot be rationally and satisfactorily accounted for, 
 and referred to the recognized operations of physical 
 agents, yet when we would follow out the results of 
 their actions in “number, weight, and measure,” and 
 as exhibited in specified time and place, theory affords 
 us little or no assistance. Meteorology, in short, in all 
 that concerns numerical valuation, is pre-eminently a 
 science of detail, and one in which all the subordinate 
 laws which are susceptible of numerical statement have 
 to be made out by laborious and continued observation 
 carried on in every region of the globe. The results of 
 such observation, accumulated in masses, and discussed 
 by the application of those powerful and refined pro- 
 cesses of calculation which modern invention has 
 devised, become cleared of accidental error, freed from 
 the influence of transient and purely local causes of 
 irregularity, and presented in the form of mean or 
 
6 
 
 METEOROLOGY. 
 
 average conclusions, each expressing some general fact 
 or law of progressive change. Thus, while on the one 
 hand deductive theory, based on our knowledge of the 
 acting causes and the circumstances under which they 
 act, pursues their operation clearly to a certain extent, 
 and less and less distinctly as it becomes lost in their 
 entanglement; it is yet enabled to point out the 
 directions where light is to be looked for, the lines of 
 inquiry which inductive observation ought to pursue, 
 and the form of the results which it ought to aim at 
 securing. 
 
 (6.) The course we shall follow in the present essay 
 will be in accordance with this general view of the 
 subject. We shall first pass in review the agents con- 
 cerned, and the laws which regulate their mutual re- 
 actions. We shall then apply our knowledge of these 
 laws to the general explanation of the phenomena of 
 meteorology in their order of importance and natural 
 sequence, and finally afford as complete a view as a 
 mere sketch like the present will allow of those subor- 
 dinate laws of periodic fluctuation which meteorologists 
 are agreed upon, a knowledge of which, as modified by 
 geographical situation, constitutes the science of clima- 
 tology; as well as of the combined system of observa- 
 tion and calculation by which this knowledge may be 
 most availably obtained and extended. 
 
THE SUN AS A SOURCE OF HEAT. 
 
 7 
 
 Of the Sun as a source of Heat, and of the measure 
 of its direct action. Actinometry. 
 
 (7.) The absolute uniformity of the sun’s emission 
 of heat is open to considerable doubt. From some 
 recent inquiries by Professor Wolf, it would appear 
 subject to a periodical increase and diminution con- 
 nected with the abundance and paucity of spots on 
 its disc, a connection surmised by the late Sir William 
 Herschel. That the appearance of such spots is 
 periodical, has been shewn by Professor Schwabe. 
 The period assigned by Professor Wolf is 11*11 years 
 from minimum to minimum, or almost exactly nine 
 periods to each century, commencing at the beginning 
 of the century itself. [That originally proposed by 
 Professor Schwabe, and still, we believe, adhered to by 
 General Sabine, is ten years.] The last year (1856) 
 has been remarkable for an almost total absence of 
 spots — a fact in perfect agreement with this law. As 
 the planet Jupiter, the largest in our system, revolves 
 about the sun in nearly the former time (11*9 y.), it 
 would almost seem as if these singular appearances 
 stood in some connection with electric or magnetic 
 reactions between the sun and planets, the compara- 
 tively small discordance of periods being due perhaps 
 to the action of the other planets.* 
 
 * While in the act of revising this sheet, we observe in the 
 Royal Society notices for March 12, 1857, a letter from Professor 
 Wolf announcing his discovery of an annual sub-period of the 
 spots — a fact strongly corroborative of the view taken in the 
 
8 
 
 METEOROLOGY. 
 
 (8.) Independent, however, of any such cause of 
 inequality, the amount of solar heat momentarily 
 received by the earth is subject to a regular annual 
 fluctuation to the extent of one-fifteenth of its mean 
 amount, due to the eccentricity of the earth's orbit — 
 the heat received in perihelio (or on the 1st of January) 
 being to that in aphelio (July 2d) as 16 to 15. As 
 the sun is vertical over the southern tropic about the 
 former epoch, and over the northern about the latter, 
 it would seem at first sight that the southern hemi- 
 sphere would receive per annum a larger supply of 
 heat ; but the unequal angular velocity of the earth in 
 its orbit, which varies in the same precise ratio, effects 
 an exact compensation in this respect by giving a 
 shorter duration to a hotter summer in the southern 
 hemisphere, and a longer to a cooler one in the 
 northern. 
 
 (9.) The general dependence of climate on geogra- 
 phical situation, the high temperature observed at the 
 equator, and the extreme cold at the poles, the annual 
 variations of temperature which accompany the changes 
 of season, as well as the diurnal alternations of heat and 
 cold, are all such obvious consequences of those astro- 
 nomical arrangements, in consequence of which the 
 sun, at any geographical station attains a greater or 
 less meridian altitude, and continues a longer or a 
 
 text. [In September 1857 appeared a memoir by the same dis- 
 tinguished meteorologist assigning distinct periodical amounts 
 of fluctuation to each of the principal planets. — {Added to the 
 Note January 1861.)] 
 
THE SUN AS A SOURCE OF HEAT. 
 
 9 
 
 shorter time above the horizon, as to need no lengthened 
 explanation. The same sunbeam which, at a vertical 
 incidence, acts on a surface equal to its own sectional 
 area, when incident obliquely on the earth (including 
 its atmosphere), is spread over a surface larger in the 
 inverse proportion of radius to the sine of the obliquity. 
 It needs little consideration, then, to perceive that at 
 the poles, where the sun is below the horizon for half 
 the year, and where during the other half it never 
 attains a greater altitude than 23^-° and that only for a 
 short time, its effective warming power on a given 
 horizontal surface must he very far inferior to that 
 which it exercises in the equatorial regions, where its 
 meridional altitude never falls short of 66|-°, and where 
 the days and nights are always nearly twelve hours in 
 duration ; nor that in intermediate latitudes the increase 
 of its altitude, and the length of the day as it advances 
 along the ecliptic from the winter to the summer 
 solstice, should bring with it that accession of general 
 temperature which we observe. 
 
 (10.) This effect of obliquity of incidence is, how- 
 ever, enhanced by another cause. The sun’s heat is 
 partially absorbed in passing through the atmosphere, 
 and that the more, the greater the mass of air it has to 
 penetrate, or the more obliquely it traverses it. Pro- 
 fessor Porbes, reasoning from observations made by 
 himself and M. Kamtz on the Faulhorn in Switzerland, 
 as compared with others at Brienz, 6844 feet lower in 
 level, concludes that 46 per cent of a vertical sunbeam 
 is absorbed in traversing a cloudless atmosphere before 
 
10 
 
 METEOKOLOGY. 
 
 reaching the sea level. A series of observations made 
 in Paris by M. Pouillet (in 1837-38) at different zenith 
 distances of the sun, gives only 24 per cent. One- 
 third is probably not too low an estimate. The 
 
 remaining two-thirds only (or less if the incidence be 
 oblique) are directly effective in heating the earth’s 
 surface. The absorbed portion is employed in heating 
 the air throughout its whole extent, and though not 
 ineffective in maintaining the general temperature, acts 
 to that end in a very different manner, as being more 
 immediately transferable from one region to another by 
 the action of the wind. 
 
 (11.) Prom experiments made at the Cape of Good 
 Hope from December 23, 1836, to January 9, 1837, by 
 the writer of this essay, it results that the direct heating 
 effect of a vertical sun at the sea level is such as would 
 suffice to melt 0.00754 in. per minute in thickness, 
 from a sheet of ice exposed perpendicularly to its rays. 
 M. Pouillet’s conclusions, reduced to a similar form of 
 expression, give 0.00703 in. A mean of the two deter- 
 minations, 0.007285 in. per minute, may therefore be 
 pretty confidently stated as the measure of the sun’s 
 vertical heating power at the sea level in a perfectly 
 cloudless sky. If visible cloud or haziness, even very 
 trifling, be present, the effect is diminished. In a 
 clouded state of the sky nearly the whole of the solar 
 heat is expended in heating the air, and evaporating the 
 clouds. 
 
 (12.) Supposing, however, the sky clear, and all the 
 rays of heat equally absorbable (which, however, is not 
 
ACTINOMETRY. 
 
 11 
 
 probable), the melting effect per minute of oblique sun- 
 shine for a zenith distance = 2 not exceeding 80° on a 
 sheet of ice perpendicularly exposed to it, would be 
 expressed by 0.01093 in. (-J) sec< % and on a sheet laid 
 horizontally , by the same function multiplied by cos. 2 . 
 This latter effect is the measure of the direct power of 
 sunshine to heat the general surface of the region on 
 which it is incident (abstraction made of the specific 
 nature of that surface).* 
 
 (13.) Actinometry . — The direct heating power of the 
 sun’s rays may be measured in two different ways — 
 statically and dynamically. The statical method con- 
 sists in equilibrating the heating power of sunshine on 
 some body (as a blackened thermometer) with some 
 external cooling influence which is itself measurable or 
 which we have reason to believe invariable. It has 
 been usual to suppose this accomplished by simply 
 noting the degree marked by such a blackened thermo- 
 meter in the sun (exposed till it ceases to rise), in 
 excess of that marked by a similar one in the shade. 
 This is much as if a man should measure his strength 
 by the depth to which he could thrust a pole into the 
 ground, in the absence of any knowledge of its sharp- 
 ness, or the resistance of the soil. The cooling 
 influences (conduction and radiation) are dependent for 
 their effects on local and temporary circumstances too 
 
 * A table, in which the calorific efficacy of a vertical sun is 
 represented by .750, and which gives its diminution for oblique 
 incidences for every fifth degree of altitude, will be found in the 
 article on Climate, Encyclopaedia Britannica, vol. vi. p. 776. 
 
12 
 
 METEOROLOGY. 
 
 numerous and too variable to estimate. The measure 
 itself requires to be measured. The objection is 
 palliated but not removed, by enclosing the thermo- 
 meter in an exhausted glass tube, which eliminates 
 conduction by cutting off the contact of air, and by 
 other methods designed to deaden, or equalize external 
 influences. It is however, insuperable in principle. 
 
 (14.) The dynamical method consists in ascertaining 
 the amount of physical change of a nature susceptible 
 of definite measurement, effected on some object by a 
 given sectional area of sunbeam in a given time, such 
 for instance as the dilatation of a liquid, the melting of 
 ice, or the raising of the temperature of a given 
 quantity of water a certain number of degrees. The 
 first attempts at obtaining such a measure, so far as 
 we are aware, were made by the writer of this article 
 in a tour through Sicily in 1824. A glass vessel full 
 of inked water was exposed alternately 5 minutes in 
 sunshine and in shade, the change of temperature being 
 noted by a very delicate thermometer immersed in the 
 liquid, and the solar effect per minute measured by the 
 difference of the minutely changes observed to take 
 place in sunshine and in shade. A similar method 
 was employed in the experiments at the Cape of Good 
 Hope, cited in art. 11; the sun, nearly vertical, being 
 allowed to shine directly on a cylindrical vessel of 
 water. M. Pouillet’s “ pyroheliometer ” is constructed 
 on this principle — a cylindrical body of water of large 
 diameter in proportion to its height, being inclosed in 
 a metallic vessel of that form with a glass face , which 
 
ACT1N0METRY. 
 
 13 
 
 is exposed perpendicularly to tlie sun. In the “ actino- 
 meter”* a blue liquid (ammonio-sulphate of copper) is 
 enclosed in a glass cylinder, one end of which is closed 
 by a silver screw working in a tight collar, to admit of 
 a small change of capacity when the liquid becomes too 
 much dilated by heat, while the other end is soldered 
 on to a thermometer tube, by w T hich the liquid 
 measures its own dilatation, the cylindrical portion 
 acting as the bulb of the thermometer. The actual tem- 
 perature of the liquid (on which its dilatability depends) 
 is ascertained by an interior thermometer occupying 
 the axis of the cylinder, and whose stem penetrates 
 the axis of the adjusting screw, and is read off along 
 its exterior prolongation. This instrument being 
 several times alternately exposed for one minute in 
 the sun and shade, and the changes of volume in each 
 case read off on the scale, the differences or sums of the 
 mean changes, according as the action has been in the 
 same or in a contrary direction, gives the dilatation 
 produced by the sunshine alone (freed from the dis- 
 turbing influences), corresponding to the actual tem- 
 perature of the liquid, which being reduced by an 
 appropriate table to give the temperature acquired, 
 affords a measure of the effect of a given sectional area 
 of sunbeam in heating a definite volume of liquid. 
 Finally, the result is reduced to “ actines,” or units of 
 solar radiation, each actine denoting that amount of 
 
 * First used in the field by the author in 1826, in Cantal, on 
 the Puv de Dome, and at Montpellier, but without the internal 
 thermometer. 
 
14 
 
 METEOROLOGY. 
 
 radiation which would suffice to melt one millionth 
 part of a metre from the thickness of a sheet of ice 
 perpendicularly exposed, in one minute, supposing it 
 wholly absorbed. Eor the details of the description, 
 the tables to he used for reducing the observations, and 
 the general management of the instrument, the reader 
 is referred to the 44 Manual of Scientific Enquiry,” 
 published by the Board of Admiralty, which contains, 
 moreover, practical directions for making and regis- 
 tering every description of meteorological observation. 
 The portability and facility of use and reduction of 
 this instrument, as well as the consistent results it 
 affords, leave nothing to desire, and afford a perfect 
 measure of solar radiation. 
 
 Of the ISTature and Constitution of the Atmosphere. 
 
 Its Pressure, Mass, and Extent. 
 
 (15.) We live under what may not improperly be 
 called an ocean of air, which covers the sea and land, 
 and extends far beyond the summits of the highest 
 mountains. Like the sea, this ocean has its currents, 
 which are winds, its waves of vast extent and magni- 
 tude, not visible indeed to the eye, but capable of being 
 made so to the intellect by means of the barometer, 
 and its tides due to the action of the sun and moon. 
 But here the analogy ceases. The air is a permanent 
 gas, incapable of being reduced to the liquid state by 
 any degree of cold or pressure yet applied. As such it 
 is highly and perfectly elastic ; condensible by pressure 
 
THE ATMOSPHERE I ITS PRESSURE AND MASS. 15 
 
 when confined, into any fraction, however minute, of 
 its ordinary volume, and dilating itself, when relieved, 
 so as to fill any space, however large. Its elastic 
 force, like that of all gases, is in the direct proportion 
 of its density, its temperature continuing unaltered, hut 
 increases, if the temperature he raised at the uniform 
 rate of 2 + 3 -, or 0.00366 of its amount, for every degree 
 centigrade (or 5-9ths of this quantity = 0.002033 for 
 every degree of Fahrenheit's thermometer) of additional 
 heat, and diminishes at the same rate if cooled. 
 
 (16.) As the air reposes on the earth, and the whole 
 weight is distributed over the whole glohe, each portion 
 (suppose a square inch) of its surface supports the 
 weight of the column of air vertically above it, to 
 whatever height it may extend, and therefore, by the 
 law of reaction, presses upward that column with a 
 force equal to its weight. Hence it follows, that the 
 pressure per square inch, which equilibrates, and there- 
 fore measures the elasticity of the air at the earth's 
 surface, must be equal to the weight of such a column. 
 This the barometer enables us to ascertain, at any 
 instant and at any place, by balancing it against that of 
 a column of mercury just sufficient in height to 
 counteract it. It is subject to extensive fluctuations, 
 but observation has shewn that the mean or average 
 length of such a column in the latitude of Paris, and at 
 the level of the sea, may be taken at 0.760 met. 
 French measure (29.922 in.), the mercury being of the 
 density which it has at the temperature of melting ice, 
 which is 13.596 times that of distilled water at its 
 
16 
 
 METEOROLOGY. 
 
 maximum. If the temperature of the mercury he 62° 
 Eahr., which is the standard temperature of the English 
 metrical system, the dilatation of mercury for 1° Eahr. 
 being almost precisely 1-1 0,000th of its volume, the 
 corresponding length of the mercurial column is 30.012 
 in., which is so nearly 30 in. that it is customary for 
 English meteorologists to consider 30 inches as the 
 mean or standard height of the barometer. In all 
 meteorological reductions and discussions, however, 
 wherever the term “barometric pressure ” is used, it 
 expresses the length of a column of mercury at the 
 temperature 0° C. or 32° Fahr. which balances the 
 aerial pressure. 
 
 (17.) The weight of such a column of mercury 
 having a square inch for its base is 14.7304 lbs. avoird., 
 which is therefore the weight of atmosphere incumbent 
 on each square inch of the earth's surface, supposed a 
 perfect sphere. Hence, from the known diameter of 
 the earth (7926 miles), we calculate the total weight 
 of an atmosphere so uniformly covering it at 11.67085 
 (about 11|) trillions of pounds ; so that, making allow- 
 ance for the space occupied by the land above the sea- 
 level, we may take 11 x 10 18 lbs. as an approximate 
 value, which is about 1-1, 200, 000th part of the mass of 
 the earth itself. Of this, about per cent has been 
 ascertained to consist of a mixture of oxygen and 
 nitrogen gases in the proportion of 21:79 in volume, 
 or about 23:77 in weight. An atomic compound of 
 these gases in the proportion of 2 atoms of nitrogen 
 to 1 of oxygen, would give a ratio of 20 : 80 in volume, 
 
THE ATMOSPHERE : ITS EXTENT. 
 
 17 
 
 Some chemists, therefore, have considered the air as 
 such a compound, and not a mere mixture. But, 
 besides that the deviation of the ratios from each other 
 is beyond the limit of error which chemical analysis 
 tolerates, M. Begnault (Chem. i. 144) has adduced 
 arguments which must be considered decisive against 
 such a conclusion. Still the near approach to an atomic 
 proportion is remarkable. Of the remaining 0*5 per 
 cent, about 0.05 consists of carbonic acid, and 0.45, 
 on an average, of aqueous vapour. 
 
 (18.) The specific gravity of dry atmospheric air is 
 to that of mercury (at 32° Fahr., and 0.76 m. pressure), 
 as 1 : 10513-J-, and a cubic foot of such air weighs 
 1.29056 oz., so that were the air of that uniform 
 density from the surface upwards, in order to exert the 
 same pressure, it would require to be 26214 feet, or a 
 trifle less than five miles in altitude. This is what is 
 understood by the height of a homogeneous atmosphere. 
 
 (19.) Such, however, is not the real constitution of 
 the atmosphere. There are mountains higher than 
 this, which yet are covered with perpetual snow, and 
 have clouds above them ; and if we consider that each 
 stratum of air, as we ascend from the earth’s surface, 
 bears only the weight of those above it, and being 
 therefore less and less pressed, occupies a larger and 
 larger volume in proportion to its weight, we shall per- 
 ceive that (supposing air infinitely divisible and expan- 
 sible), there would be no assignable limit to the height 
 of the atmosphere. Theory demonstrates, that suppos- 
 ing the temperature uniform throughout, the density 
 c 
 
18 
 
 METEOROLOGY. 
 
 would decrease in geometrical progression as the alti- 
 tude increases in arithmetical, and assigns for the rela- 
 tion between them the following equation (in which P, 
 p, represent the densities (measured by the barometric 
 pressures), at the sea level and at the height h , and H 
 the height of a homogeneous atmosphere), viz. 
 
 h = H (Log. P-Log. p), 
 
 the logarithms being hyperbolic; or if h and H be 
 expressed in feet, and the hyperbolic reduced to com- 
 mon or tabular logarithms, 
 
 h = 60309 x (Log. P — Log. p). 
 
 At the height, then, of 60,000 feet in round numbers, 
 or about 111- miles, the density of the air on this sup- 
 position would be one tenth of that at the sea-level ; at 
 23 miles, one hundredth; at 33-|, one thousandth, and 
 so on. At an altitude of 103 miles, the density would 
 be reduced to the thousand-millionth part of its super- 
 ficial amount. Actually (for reasons which will pre- 
 sently appear), the decrease is still more rapid. 
 
 (20.) The question, whether or not there be any 
 absolute limit to the atmosphere, has been considered 
 to depend on the view we may take of the intimate 
 constitution of matter. If it consist of ultimate, finite 
 atoms, a limit must at all events occur where the gravity 
 of one atom to the general mass of the earth exceeds 
 the repulsive power exerted on it by the air below it, 
 a question which defies calculation, since we know 
 nothing of the law of force with which the particles of 
 air repel each other, the usual opinion that it is in- 
 versely as their distance being quite untenable. If, on 
 
THE ATMOSPHERE : ITS EXTENT. 
 
 19 
 
 the other hand, matter he infinitely divisible, it has 
 been argued by Doctor Wollaston that the celestial 
 spaces must be full of attenuated air, and that the sun, 
 planets, and satellites, standing in communication with 
 this general reservoir, would each in the course of ages, 
 have drawn to itself such a share, that equal densities 
 in their vicinity should correspond to equal forces of 
 gravitation. Calculating on this datum, the sun’s 
 atmosphere should have the density of the earth’s at 
 the sea level, at about 4-i times its own radius above 
 its surface, and Jupiter at about At these dis- 
 tances from the respective luminaries, the rays of light 
 should suffer a deviation by refraction, equal to twice 
 our horizontal refraction, or more than a degree, a result 
 directly refuted by observation, which indicates no refrac- 
 tion whatever. This argument, however, takes no account 
 of the effect of centrifugal force. Apart from all con- 
 siderations of molecular repulsion, it is certain that at 
 about 26,000 miles’ distance from the earth’s equatorial 
 surface, the centrifugal force would equal gravity, and 
 beyond that distance would exceed it ; so that were 
 there no physical cause producing a positive and definite 
 limit, all the air beyond that level must be flirted off 
 into space ; and there being no pressure, other air 
 would rise from below to replace it, and share the same 
 fate, so that the whole atmosphere would be drained 
 away, to form a ring like that of Saturn. In fact, how- 
 ever, the excessive tenuity which must, under any 
 hypothesis, be ascribed to the interplanetary air (to 
 express which in fractional parts of its density at the 
 
20 
 
 METEOROLOGY. 
 
 earth’s surface would require the denominator to con- 
 sist of at least 1370 figures), dispenses with giving such 
 reasonings any serious discussion. If, indeed, there 
 were the least ground for believing that atmospheric 
 air could be liquefied by a cold of — 120° Fahrenheit, the 
 existence of a limit at a very moderate height would 
 follow as a matter of course, as will presently appear. 
 Supposing the law of dilatability to hold good rigor- 
 ously for all temperatures, the elasticity of air at — 273° 
 centigrade would be nil. But we have no means 
 of producing this degree of cold, and therefore no 
 experimental examination of the case is possible ; and 
 we must therefore be content with the assurance, 
 that at no elevation which can ever be attained by 
 man, or in which life could be supported, does the 
 law in question suffer any impeachment; and that at 
 80 or 90 miles above the earth’s surface a vacuum 
 exists, inconceivably more perfect than any which we 
 can produce with our air pumps. At 45 miles the air 
 is already rarified about 25,000 times, at which eleva- 
 tion it would seem, from the duration of twilight, that 
 some feeble reflexion of light still subsists. 
 
 (21.) According to Dalton’s views respecting the 
 mixture of gases, two or more bodies of this nature 
 mixed together exert no elastic force on each other 
 mutually, though they obstruct and impede each 
 other’s free movement. Each tends to diffuse itself 
 among the others, and to arrange itself as if the others 
 had no existence, and if left long enough undisturbed 
 would do so. In consequence of this property in a 
 
THE ATMOSPHERE : ITS EXTENT. 
 
 21 
 
 mixed atmosphere, if perfectly quiescent, each gas 
 would constitute a separate and distinct atmosphere, 
 arranged according to the above laws of equilibrium, 
 and each sustaining its quota of the total pressure in 
 the exact proportion of its own volume present in the 
 mixture at the point where the pressure is estimated. 
 But these volumes would be proportionally different at 
 different elevations, the density of the oxygen atmo- 
 sphere decreasing in a more rapid geometrical progres- 
 sion than that of the nitrogen, and that of the carbonic 
 acid than either. But owing to the obstruction each 
 offers to the free permeation of the others, and to the 
 extreme mobility and continued agitation of the air, 
 the state of equilibrium is never even approached ; and 
 experiment has shewn that air collected at all elevations 
 above the surface in balloon ascents (in one instance 
 by Gay Lussac, in his memorable ascent in 1804, at the 
 height of 22,896 feet), contains these two elements in 
 precisely the same proportions. With the carbonic 
 acid, the case is somewhat different, that gas being 
 subject to local variations consequent on its peculiar 
 uses in the economy of animal and vegetable life ; but 
 the differences are so trifling, that for meteorological 
 purposes they may be altogether neglected, and the 
 atmosphere (at least its gaseous portion) regarded as one 
 homogeneous gas. 
 
22 
 
 METEOROLOGY. 
 
 Op the Decrement of Temperature on Ascending 
 
 into the Atmosphere, and on the Barometric 
 
 Measurement of Heights. 
 
 (22.) All who have ascended high mountains and 
 all aeronauts are agreed on the fact of a decrease of 
 temperature, which is conspicuously evident from the 
 existence of perpetual snow on elevated summits even 
 in the hottest regions. Respecting the rate of this 
 decrease and its law, much uncertainty still prevails. 
 We possess, it is true, a great accumulation of observa- 
 tions of mountain temperature, both barometrically and 
 trigonometrically determined by De Saussure, Cordier, 
 Raymond, Humboldt, Colonel Sykes, Eschmann, Bob- 
 laye, and many others, on the Alps, Pyrenees, Etna, 
 Teneriffe, the Andes and Himalayas, and in Greece ; 
 hut the results are only loosely accordant, and appear 
 to indicate that the rate of decrease depends in some 
 considerable degree on the season of the year and the 
 local situation of the place of observation. If we 
 assemble the most accordant, and especially those cases 
 where the heights ascended have been considerable, 
 and trigonometrically determined, we find an average 
 decrement of 1° of Fahrenheit's thermometer for every 
 100 yards of ascent, or 1° Cent, for every 180 yards. 
 The most unexceptionable mode of determining this 
 important element would no doubt be by balloon ascents ; 
 but as the heights in such ascents are necessarily deter- 
 mined barometrically, they involve in their calculation 
 (as will presently be shewn) the very element in question, 
 
THE ATMOSPHERE : DECREMENT OF TEMPERATURE. 23 
 
 and tlie results deduced from such ascents seem gener- 
 ally to indicate a materially slower rate of decrease. 
 Thus we find, indeed, from Gay Lussac’s voyage, as 
 calculated from a decrease of 72*5° Fahr. in ascending 
 22,896 feet, a decrement of 1° in 316 feet, agreeing 
 pretty well with the average above stated. But on the 
 other hand, a mean of four ascents by Mr. Green and 
 Mr. Bush in the Nassau balloon in 1838 and 1850, to 
 altitudes between 19,185 and 20,352 feet, gives 485 feet, 
 and a similar mean of four ascents by Mr. Welsh in the 
 autumn of 1852 from London, under the direction of 
 the committee of the Kew Observatory, one of which 
 was to the height of 22,930 feet, and in which all the 
 observations were conducted with scrupulous precision, 
 and the reductions very scientifically made, afford the 
 result of 386 feet. As a general average deduced, then, 
 from balloon ascents, 400 feet per degree of Fahrenheit 
 would seem to be preferable to 300. 
 
 (23.) For the cause, or rather causes, of the general 
 fact of the decrement in question, we have not far to 
 seek. There are several, all probably more or less 
 efficient. 
 
 The first is, that in receding from the earth's sur- 
 face, we are quitting the proximity of a heated body ; 
 approaching a region where no such body exists ; and 
 interposing more and more of a medium obstructive of 
 heat. If we put any confidence in the theories of 
 Founder and Pouillet, the temperature of the inter- 
 planetary spaces is probably not higher than — 226° 
 Fahr. Consequently, a thermometer exposed at a 
 
24 
 
 METEOROLOGY. 
 
 height where, practically speaking, there is no air, 
 ought at all events not to stand above an arithmetical 
 mean between this and the temperature of the earth's 
 surface below it, that is, — 72° at the equator, and — 1 1 3° 
 at the poles, taking 82° Fahr. and 0° Fahr. as the mean 
 temperatures at those places. Between these two 
 latitudes and levels, then, it would mark, of course, 
 every intermediate degree. 
 
 Again, secondly, As the earth's surface receives on 
 the average (art. 1 0) twice as much solar heat as the 
 air, it is, generally speaking, habitually warmer, and 
 warms the air by contact communication. The heat 
 so imparted is entirely, in the first instance, diffused 
 through the lower strata, only that radiated off going 
 to heat the upper. 
 
 Thirdly and lastly, there exists a powerful cause, 
 first pointed out by Leslie, of quite a distinct nature, 
 which will need a little more explanation. 
 
 (24.) Suppose the atmosphere of equal temperature 
 throughout and at rest. Now let any mass of air at 
 the surface receive an impulse upwards by some external 
 force (not by heating it). It will rise, and in so doing, 
 displace quiescent air above it, which will descend to 
 fill its place, and this process will continue till the 
 upward impulse is extinguished by friction and resist- 
 ance. In rising, air expands, but as the descending air 
 contracts, pari passu , the whole disturbed space, when 
 quiet is restored, will be occupied by air as before, and 
 the total pressure will be unaltered. But as regards 
 the distribution of sensible heat, a great change will 
 
THE ATMOSPHERE I DECREMENT OF TEMPERATURE. 25 
 
 have taken place. The air which has expanded in 
 ascending has absorbed caloric, and grown colder, while 
 that which has contracted in descending has given out 
 just as much, and become hotter. The total heat and 
 the total mass remain unchanged, but the equilibrium 
 of temperature is destroyed. The lower strata have 
 become warmer than the upper: the density adjusts 
 itself accordingly ; and the undisturbed column superin- 
 cumbent on both is supported as before. Precisely the 
 same consequence will result from forcing down by 
 mechanical means (not by cooling) any mass of air from 
 a higher to a lower level. The descending air in con- 
 densing becomes heated, while that which ascends to 
 replace it is cooled by its own expansion. 
 
 (25.) Now this is no imaginary case. It will be 
 shewn hereafter (art. 52) that when aqueous vapour 
 ascends by its levity, it drags air up with it; not by 
 heating it, but by mere mechanical impulse ; and thus 
 we see that the mere fact of a circulation of air in the 
 atmosphere, in so far as that circulation is due to the 
 generation and condensation of vapour, or even to the 
 downward mechanical impulse of the fall of rain or 
 snow , must of necessity cause a deficiency of sensible 
 heat in the higher as compared with the lower regions.* 
 
 * If instead of being urged upwards by external impulse, a 
 body of air dilated by heat, ascend in consequence of such dilata- 
 tion, it will rise until its expansion reduces it to the temperature 
 of the surrounding air ; but it cannot do so without depressing 
 other air to a lower level, which thus becomes heated, so that in 
 this case also the equilibrium of sensible heat is subverted, 
 though in a somewhat different way. 
 
26 
 
 METEOROLOGY. 
 
 (26.) As regards the law followed by this decrement 
 little decisive can be said. A uniform rate of decrease, 
 such as that described in art. (26.) as a physical law co- 
 extensive with the atmosphere, is not probable, though 
 for heights below 15,000 or 20,000 feet it is perhaps as 
 exact as any which can be briefly stated in words. 
 Assumed as a basis of calculation, it leads to the follow- 
 ing very remarkable relation between the height (x) in 
 yards, and the ratio of barometric pressures (vs = ^) 
 at the higher and lower levels, viz. — 
 
 cr = (|) 5 ' 584 
 
 when a = 180 yards x (273 + T), T being the reading 
 of the centigrade thermometer at the lower station, and 
 X the depression of the upper station below the height 
 a (reckoned from the lower station), (X = a — cc), 
 which must be considered a limit to the atmosphere, 
 or rather as a limit beyond which the formula is unin- 
 terpretable, or physically speaking, absurd. Neverthe- 
 less, within the limits above specified it affords results 
 not very remote from the truth. Thus it gives for Gay 
 Lussac’s ascent, calculated on his own data (in which 
 T = 30°. 8 C. and vs = 0*42966), a height of 7678 
 yards, differing only 46 yards from that assigned by 
 himself. Meteorologists in general , we apprehend , are 
 hardly aware how completely the law of equable de- 
 crease is subversive of the received notion of a diminution 
 of pressure in geometric progression upwards from the 
 sea level . This our formula above renders very ap- 
 parent. 
 
THE ATMOSPHERE ! DECREMENT OF TEMPERATURE. 27 
 
 (27.) The law of decrement of temperature is a 
 subject to which great interest is attached, and around 
 which a vast amount of laborious research has accumu- 
 lated, with a result not unusual in such cases — a great 
 deal of thought and calculation wasted, and no very 
 positive conclusion arrived at. The fact is, the pro- 
 blem has been attacked in the wrong direction. Specu- 
 lation has been busy in assigning hypothetical laws, 
 either simply tentative, or resting on no solid foun- 
 dation of physical consideration, to exhibit the 
 relation of the temperature to the height directly : to 
 verify which supposes a series of heights and tempera- 
 tures corresponding to each other to be given by direct 
 observation, the whole series being comparable. Now 
 we possess not, and never can possess, any such series ; 
 and it is therefore purely and simply groping in 
 the dark to assemble a mass of miscellaneous observa- 
 tion from all quarters, in all climates and seasons, in 
 which insulated decrements of temperature are con- 
 cluded from mountain ascents ; and put them together 
 with the expectation that any intelligible result should 
 emerge. We pass, therefore, without discussion, the 
 theory of M. Biot (Kamtz, ii. 130) which assigns a 
 decrement in geometrical progression for heights in 
 arithmetical, and which sets out with the assumption 
 that the whole heat of the air at any place is due to 
 the extinction of heat radiated or conducted imme- 
 diately from the earth at that place ; or that of Lambert, 
 followed by Baron Zach and Mr. Atkinson, in which it 
 is assumed (on a mere general impression that the 
 
28 
 
 METEOROLOGY. 
 
 decrement decreases with the height), that equal decre- 
 ments of temperature shall correspond to uniformly 
 increasing increments of altitude. In fact, no law of 
 decrement, which would not make the density increase 
 upwards, would be incompatible with the equilibrium of 
 the strata; and for heights under 10,000 feet almost 
 any law and rate which satisfies this condition, and 
 represents the temperatures at the highest and lowest 
 levels correctly, will do so at the intermediate ones. 
 The great defect of all such hypotheses is, that they 
 cannot be fairly tested unless we possessed a scale of 
 heights, trigonometrically determined, up to 20,000 or 
 30,000 feet, all in one geographical situation, and 
 readily accessible from the sea level. Balloon ascents, 
 indeed, amply satisfy the latter requirement — but as 
 the heights must be concluded barometrically, they 
 fail to afford what this mode of looking at the subject 
 absolutely requires. A most valuable piece of positive 
 information is, however, afforded by a balloon ascent, 
 viz., that in a given very limited locality, out of the 
 reach of surface inequalities and up-turned currents of 
 heated air ; on a given day, and with every facility for 
 obtaining simultaneous observations on the surrounding 
 region, a definite relation , depending on no hypothesis , 
 hut absolutely given by observation , prevails between 
 the temperature and pressure , as read off at as many 
 different instants, throughout the ascent, as the observer 
 pleases — which relation is capable of being exhibited 
 to the eye with all its capricious incidents by graphical 
 projection in a curve, and of being freed, by a mode of 
 
BAROMETRIC MEASUREMENT OF HEIGHTS. 29 
 
 treating such projections which has elsewhere {Mem. 
 Ast. Soc. v.) been largely exemplified by the writer of 
 these pages, from the greater part of the errors arising 
 from casual influences or imperfect observation. In 
 the view of the subject we are about to take (which 
 it is something astonishing should have been over- 
 looked by all who have treated of it), this information 
 is all that is necessary for a rigorously exact determina- 
 tion of the heights of the several points of observation 
 themselves, and of the law of decrement which actually 
 subsisted at the time and place. Ey the comparison 
 of such laws at different times and places, it will then 
 be seen whether they are such as really to admit of 
 any uniform or general expression. 
 
 (28.) To shew this, let p be the barometric pressure, 
 t the temperature (centigrade), and d the density of the 
 air at any altitude, x , and P, T, A, those at the sea 
 level ; h the height of a homogeneous atmosphere at the 
 temperature 0° C. and H at temperature T. Now if k 
 = 0.00366, we shall have by what was shewn in 
 art. (15), 
 
 d (i+fc t) p . 
 
 1 A (1+* T) ' 
 and since the differential of the pressure (dp) is the 
 weight of the column d x , whose density is 3, 
 dp~— d. dx ; (2.) 
 
 Dividing, then, equation (2) by (1), and observing that 
 
 A (1+*T) 
 
 we shall have 
 
30 
 
 METEOROLOGY. 
 
 dp d X 
 
 p h (\ + kt) * 
 
 If t be known in functions of x , this equation gives 
 at once the relation between the altitude x and the 
 barometric pressure p ; and this is the mode in which 
 the analysis of this question has always been conducted. 
 But if put under the form 
 
 it becomes available for a different mode of procedure. 
 If the law of temperature, as depending on the pressure, 
 be analytically expressible, or if t be an explicit func- 
 tion of p , we have x given at once by integration. But 
 what makes this way of putting the matter peculiarly 
 valuable is, that if this be not the case, but t only 
 given numerically by the registered observations of the 
 thermometer, and the reading-off of a graphical projec- 
 tion of them as above described ; the integral in question 
 may be obtained graphically with quite sufficient pre- 
 cision (practically speaking), and in an infinitely shorter 
 time, than by any system of calculation; so that the 
 determination of the altitudes in balloon ascents is 
 made to depend on no hypothesis whatever, but to 
 result purely and absolutely from the series of observed 
 temperatures and pressures in the ascent and descent. 
 
 (29.) We have been able to collect no more than 
 nine balloon ascents to sufficient altitudes (which 
 should not be less than 10,000 feet), in which a series 
 of corresponding readings of the two instruments have 
 been taken consecutively enough for discussion, viz., 
 
BAROMETRIC MEASUREMENT OF HEIGHTS. 31 
 
 those of Gay Lussac (art. 22), of Messrs. Green and 
 Kush in 1838 and 1850 (19,185, 20,352, 19,904, 19,440 
 feet), and of Mr. Welsh in 1852 (19,510, 19,100, 12,640, 
 and 22,930 feet), these latter leaving nothing to desire 
 in point of instrumental appliances and scientific pre- 
 cision in their use. Plate I. exhibits the graphical 
 projection of the observations registered in each of these 
 ascents, the dots being the points laid down : the con- 
 tinuous curve lines swept among them liberd manu, 
 4 without reference to any theory, but that one condition 
 without which no general speculation on the subject is 
 possible, viz., that their curvature shall be, generally 
 speaking, similar in character, and have its concavity 
 throughout towards the same side : and the dotted lines 
 analogous curves in which this condition is not adhered 
 to, but in which the most essential peculiarities of each 
 ascent are brought into evidence. Each set of dots is 
 referred to the curve to which it belongs by a light 
 connecting line. The readings-off of these curves are 
 stated in cols. 2, 3 .... 10 of the following table, and 
 are set down just as they were read from the actual 
 projections used , without any subsequent equalization 
 of differences or correction whatever. 
 
32 
 
 METEOROLOGY. 
 
 12 
 
 Values 
 of t cal- 
 culated 
 from 
 Eqn. 
 Art. 34. 
 
 
 65.0 
 
 62.5 
 
 56.3 
 
 51.0 
 
 41.0 
 
 O 
 
 cd 
 
 co 
 
 19.0 
 
 7.0 
 
 11 
 
 Mean 
 of the 
 foregoing 
 
 © 
 
 vO 
 
 CO 
 
 O CO O 
 id CO CM 
 
 CO coco 
 
 <M CM pH 
 
 © oo cd 
 co vo vo 
 
 NOH 
 CO pH GO 
 VO VO rH 
 
 44.9 
 
 41.4 
 
 37.6 
 
 CO iH CM 
 CO 05 rH 
 CO (M CM 
 
 O CM CO 
 05 cd tN 
 
 pH pH 
 
 10 
 
 Welsh, 
 Nov. 10, 
 1852. 
 t = 
 
 47°. 1 : : 
 
 IN CD pH 
 CO UO rH 
 rH rH rH 
 
 rH iq^ 
 cidco 
 rH rH co 
 
 CM 05 CO 
 CO CO pH 
 CO CO CO 
 
 t> CO pH 
 
 GO vd CM 
 (M (M <M 
 
 rH GO rH 
 GO cd 05 
 
 pH pH 
 
 + 4.2 
 -1.5 
 -7.3 
 
 1 9 
 
 Welsh, 
 Oct. 21, 
 I 1852. 
 t = 
 
 05 
 
 £- 
 
 VO 
 
 CO CO O 
 CO vd 
 iO »0 vO 
 
 53.5 
 
 51.3 
 
 49.4 
 
 47.0 
 
 44.2 
 
 40.6 
 
 tN VO CO 
 cd (N N 
 CO co <M 
 
 coop 
 
 NNCi 
 
 (NHH 
 
 rH vo VO 
 
 cd © vd 
 + 1 
 
 8 
 
 Welsh, 
 Aug. 26, 
 1S52. 
 t — 
 
 >q 
 
 CO 
 
 CO 
 
 .. 
 
 rH CO rH 
 VO CO t-H 
 CO CO CO 
 
 00 (M CO 
 
 oo’ cd cd 
 
 VO VO vo 
 
 VO CO rH 
 © In rH 
 VO rH rH 
 
 41.0 
 
 37.4 
 
 33.7 
 
 CO © p 
 05 vd 05 
 (M CM pH 
 
 l .. :: 
 © © © 
 rH 05 rH 
 
 7 
 
 Welsh, 
 Aug. 17, 
 1852. 
 
 © 
 
 co 
 
 IN 
 
 © oo rH 
 (M 05 in 
 
 !>. CO CO 
 
 05 rH VO 
 rH <M 05 
 CO CO vo 
 
 rH O O 
 cd cd ci 
 vo vo rH 
 
 GO rH W 
 rH o’ vd 
 rH rH CO 
 
 OOVCC5 
 © vd 05 
 CO CM pH 
 
 © p rH 
 rH CO pH 
 pH 
 
 6 
 
 Rush, 
 June 29, 
 1850. 
 
 t — 
 
 © 
 
 rH 
 
 CO 
 
 rH CO vo 
 CO C<j rH 
 CO CO CO 
 
 O CO © 
 o oo cd 
 CO vo vo 
 
 MCO 
 rH CM* © 
 VO vo VO 
 
 1 
 
 CO rH CO 
 tN rH I-J 
 rH rH rH 
 
 N. CO CO 
 In CO 00 
 CO CO <M 
 
 CM <M CO 
 CO IN + 
 
 NHH 
 
 5 
 
 Rush, 
 June 22, 
 1850. 
 t = 
 
 <M 
 
 CO 
 
 In 
 
 72.6 
 
 71.0 
 
 69.5 
 
 © <M rH 
 00* cd rH 
 
 CO CO co 
 
 CO O CO 
 (NON 
 CO CO vo 
 
 54.8 
 
 51.7 
 
 48.6 
 
 45.4 
 
 41.5 
 37.7 
 
 vq © ° 
 
 CO 05 rH 
 CO <M CM 
 
 4 
 
 Rush, 
 Sept. 10, 
 1838. 
 t = 
 
 © 
 
 6 
 
 CO 
 
 00 rH 00 
 05 05 IN 
 VO VO vO 
 
 rH tN CO 
 CO rH Di 
 
 vo vo vo 
 
 (NHCO 
 ONCO 
 vo rH rH 
 
 rH N- rH 
 o’ cd cd 
 rH CO CO 
 
 vo rH O 
 
 05 >0 pH 
 <M <M CM 
 
 16.4 
 
 11.0: 
 
 5.4:: 
 
 3 
 
 Rush, 
 Sept. 4, 
 1838. 
 t = 
 
 rh 
 
 CD 
 
 CO 
 
 O © 00 
 co id co 
 
 CO CO CO 
 
 CO vo O 
 (NHO 
 CO CO CO 
 
 CO rH co 
 GO CD rH 
 VO vo vo 
 
 OHO 
 CM 05 vd 
 vo rH rH 
 
 p vo vq 
 CM od cd 
 rH CO C0 
 
 28.0 
 
 21.9: 
 
 15.4:: 
 
 2 
 
 Gay 
 Lussac. 
 Sept. 17, 
 1804. 
 t = 
 
 CO 
 
 <M 
 
 00 
 
 oo tN t>. 
 
 HC3N 
 00 t> IN 
 
 rH O CO 
 
 id cd © 
 
 tN t> tN 
 
 oo in co 
 
 N- rH rH 
 CO CO CO 
 
 O rH <M 
 GO rH O 
 VO VO VO 
 
 o O 00 
 cd pH vd 
 rH rH CO 
 
 © vq in 
 ©' cd cd 
 
 CO <M PH 
 
 1 
 
 V = 
 pres- 
 sure in 
 inches. 
 
 p = 
 
 VO 
 
 c? 
 
 005 00 
 CO <M CM 
 
 N. CO vo 
 <M M CM 
 
 rH CO CM 
 CM CM (M 
 
 HOC) 
 <M <M rH 
 
 00 In © 
 r— 1 pH pH 
 
 VC CO 
 
 rl H H 
 
BAROMETRIC MEASUREMENT OF HEIGHTS. 33 
 
 Col. 1 1 contains tlie means of all tlie readings in the 
 other columns, and from these a curve (the last of the 
 plate referred to) is laid down which exhibits an aver- 
 age form of the curve, and embodies all the other results. 
 That this proceeding is legitimate will appear from the 
 following consideration: — Suppose t the temperature 
 (or ordinate of any one of the curves) corresponding to 
 the pressure p (the abscissa), and suppose any general 
 relation such as t = a. <p (p) + fi^(p) + &c. to subsist, 
 a, /5, &c. being parameters peculiar to each curve. 
 Then if there be several such curves in which (corre- 
 sponding to tlie same pressure) a, /3, a', /3', a", /3", 
 &c. are the parameters, and t, t' t", &c. the ordinates, 
 since t = a <p + f3 ^ + &c., t' = a! p + /3' ^ + &c., we 
 have 
 
 t^rt 4* &c. a 4- a-\- &c. j8 • + /3 - j- &c. . n 
 
 = p -f + (VC., 
 
 n n n 
 
 which shews that a similar relation subsists between the 
 means of the temperatures and the pressures, provided 
 mean values of the parameters are used. 
 
 (30.) This essential point premised, we may now ob- 
 serve that the course of all the curves is evidently syste- 
 matic ; that the tendency to fluctuate in one direction in 
 the early part of their course, as marked by the dotted 
 curves in some of them, is contradicted by a similar ten- 
 dency in the opposite direction in others, and that they 
 agree in speaking a language to the eye which we have 
 to interpret into a formula. Thus a good deal depends 
 on the view we may take of the nature of heat itself 
 and of temperature. Is there an absolute zero ? And 
 
 D 
 
34 
 
 METEOROLOGY. 
 
 if so, does matter occupy space in virtue of the presence 
 of heat % If we reply in the affirmative to both these 
 questions, and suppose moreover, empty space absolutely 
 devoid of heat, we must take the extreme lowest ther- 
 mometer reading, as t = — cc corresponding to p= 0. 
 In that case the speculative prolongation of our curve 
 would give it a vertical asymptote at p = 0, and as its 
 aspect so prolonged bears some general resemblance' to a 
 logarithmic curve, we will give that curve a trial. Taking, 
 
 then, log. p = a -f fit* (5), we have ^ = fidt, and 
 
 P 
 
 by equation (4) art. (28), x = h f — ftdt (1 + kt) 
 
 = i3h{(T-t) + Jc^} =j8&(T-^1+&2!+£ } •, (6) 
 
 But by equation (5) we have log. P = a + /3 T, whence 
 we get (3 (T — t) = log. P — log. p ; substituting which 
 in (6) it becomes 
 
 z = /*. lo g.(?) {1+fc.Lp}; (7) 
 
 (31.) This is the formula given by Laplace in the 
 tenth book of the Mecanique Celeste, abstraction made 
 of two factors in his expression for x, viz. 
 
 (l + 0-00228- log. ?) 
 
 which takes into account the diminution of gravity in 
 receding from the centre of the earth, and 
 (1 + 0*00265)* cos. 2 X 
 
 X being the latitude of the place; which expresses the 
 
 * t here expresses centigrade degrees, the same/om apply- 
 ing equally to either mode of expression. 
 
BAROMETRIC MEASUREMENT OF HEIGHTS. 35 
 
 influence of the centrifugal force arising from the earths 
 rotation. The value of h, if the logarithms used are 
 the common tabular ones, may he taken at 60,309 British 
 feet ; if hyperbolic, at 26,254 feet. This is the formula 
 (including these factors) now universally adopted for 
 computing heights from barometric observation. Its 
 reduction to numbers is facilitated by tables which are 
 given in the “ Annuaire” of the French Board of Longi- 
 tude, in Galbraith's Barometric Tables (Edin. 1833), 
 and in that very useful collection by Arnold Guyot, pub- 
 lished by the Smithsonian Institution, U. S. (Washing- 
 ton, 1852), to which, as containing almost every table a 
 meteorologist can require, we once for all refer our readers. 
 From this formula it appears that, according to the best 
 estimate we can form of the temperature at great eleva- 
 tions, the extreme rarefaction specified in art. (19) as 
 existing at 103 miles, on the supposition there made, 
 would really be found about 1 1 miles lower, or at about 
 l-85th part of the earth's diameter above its surface. 
 
 (32.) Laplace's investigation of this formula is based 
 on an assumption (avowedly introduced by him for the 
 sole purpose of simplifying his analysis) of a variation 
 of temperature with altitude which amounts to sup- 
 posing equal decrements of temperature to correspond to 
 increments of height, decreasing progressively in arith- 
 metical progression. This is in fact the law of decrement 
 which would result from our equation (6). It is there- 
 fore precisely the reverse of that of Lambert, Zach, and 
 Atkinson, and, we may add, not in accordance with 
 the general impression among meteorologists (in which, 
 
36 
 
 METEOROLOGY. 
 
 however, we do not participate), that the decrease is 
 slower the higher we ascend. It is somewhat singular 
 that Laplace does not appear to have noticed the 
 logarithmic relation (5) which his hypothesis implies 
 between the temperature and pressure ; and still more so 
 (and we are surprised that the remark should not have 
 occurred either to Laplace himself, or to any of those 
 who have used his formula) that his expression is iden- 
 tical with that which would result from assigning to the 
 whole atmosphere a uniform temperature , the mean of 
 those actually observed at the higher and lower levels. 
 
 (33.) When we come to examine our curve of decre- 
 ment more particularly, however, it becomes evident 
 that it is not a logarithmic curve, hut a most undeniable 
 parabola. The errors in the former case are systematic, 
 and far beyond hearable limits. Supposing the curves 
 to agree at the 15th and 30th inch of p, the errors are 
 at 13, 17, 20, 23, 27, and 30.5 inches respectively + 2*2°, 
 — 1*8°, — 3*3°, — 4-2°, — 2*2°, and + 1*2°. The logarith- 
 mic curve, therefore, is not in satisfactory accordance 
 with the average course of nature as collected from these 
 observations. 
 
 (34.) If we take for Fahrenheit’s scale a = — 87°, 
 /3 = + 9*0667, and y = — 0*1333, or for the centigrade 
 a = — 66*1111, /3 = + 5*0370, and /=-0*0741, we 
 shall find the numbers in col. 1 1 to he perfectly well 
 represented by the equation t — a -f j3 p + yp , substi- 
 tuting which in equation (4), integrating from P and T 
 to p and t, eliminating y by the equation 
 T — 2 = /3 (P — j>) + y (P* — p 2 ), 
 
BAROMETRIC MEASUREMENT OF HEIGHTS. 37 
 
 taking 60,309 ft. for the value of li (as adapted for 
 the use of common logarithms), putting for h its value 
 0.00366, and using the centigrade values of a and j3, 
 we shall find 
 
 «=*{(1 + 0-00366 «) log. ? + 0 000795 { (T - 1) + 0 (P -p) ]• j ; (1 0) 
 
 (35.) To apply this formula to any proposed ascent, 
 the readings of the instruments having been graphically 
 projected, two extreme and one intermediate pair of 
 corresponding values of t and p are to be fixed upon, 
 and thence by resolving the three simple equations of 
 the form a+j?./ 3+p 2 . y = t which these afford, the 
 values of a and /3 are obtained, which may then be 
 substituted in (10), and the value of x determined. 
 
 As an example, we shall take Mr. Welsh’s ascent of 
 Nov. 10, which gives P = 29*972, ^>= 12*240; T = 
 46°*7 F. = 8°*16 C.;* = -ll°-3 F.=-24°*06 C.; 
 a = — 94°*804 F. = — 70°*44 C.j and (3 = + 8°*4848 
 F. = + 4°*7136 C., and executing the calculation we 
 obtain x — 22983 feet, which, corrected (by the factors 
 in art. 31) for latitude and decrease of gravity, finally 
 gives x— 23027 feet, being 97 feet in excess of the 
 height assigned by Mr. Welsh from Laplace’s formula ; 
 by which it appears that, whatever be the objections to 
 which the law of temperature implied in that formula 
 may be liable, it may still be used with tolerable safety 
 even for such altitudes. 
 
 (36.) If^> = 0, or so nearly such as would be the 
 case in ascending some 25 or 30 miles, t = a, which is 
 therefore the temperature a thermometer would mark 
 
38 
 
 METEOROLOGY. 
 
 exposed to the total joint radiation of the earth and 
 air from beneath, and to that into space from above. 
 If then we call S the temperature of space beyond the 
 influence of terrestrial radiation , we have, at least ap- 
 proximately, a = ^ (T -f S). Now we have seen that 
 in our mean curve a = —87° F. .and T = + 65° F., 
 and that in Mr. Welsh’s last ascent a = — 95, T = +49. 
 Both agree in giving S = — 239° F. Hence we may 
 conclude generally, that taking for S this value, a may 
 
 be at once assumed as = — — 11 9-|*° F. 
 
 At the equator, 
 
 then, the limiting temperature of the atmosphere would 
 average — 77-J° F., and at the poles about — 119-J°F., 
 with a range of temperature from the surface of 161 
 in the former case, and !19J° in the latter. 
 
 Of Land and Water as Becipients and Com- 
 municants of Heat. 
 
 (37.) Of the solar heat which actually reaches the 
 surface of the globe, that which falls on water pene- 
 trates it to some moderate depth and is absorbed 
 internally, while that which is incident on land is 
 wholly absorbed superficially, or within a very minute 
 thickness. Water, moreover, is eminently a non-con- 
 ductor of heat, so that once received into its substance 
 it is only diffusable by agitation; and since this, 
 however violent at the surface of the ocean, diminishes 
 rapidly with the depth, the ultimate communication of 
 heat downwards to any considerable depth being a 
 
RELATIONS OF THE SEA TO SOLAR HEAT. 39 
 
 very slow process. Ey far the greater portion of the 
 daily supply of heat to water, then, may be said to float 
 within a moderate depth of the surface, forming a kind 
 of reservoir of heat. On the other hand, water is a 
 good radiant , and as such is continually, both day and 
 night, giving off radiant caloric, which is absorbed in 
 traversing the air, and thereby tends to raise the tem- 
 perature of the latter medium. It is a property of 
 caloric radiant from bodies heated below incandescence 
 to be eminently absorbable by transparent media. 
 Hence it is most probable that much of the heat so 
 radiated off is detained in the lower strata of the air. 
 Meanwhile a balance is struck in the water itself of 
 the quantities received and parted with, by the pre- 
 ponderance of one or the other of which it gains or 
 loses in average temperature on the 24 hours. Thus, 
 in the warm season, when days £re long and nights 
 short, the general temperature of the sea is slowly 
 rising above its annual average, and vice versa in the 
 opposite season. Eelow a certain depth, however, the 
 temperature of the ocean would appear to be deter- 
 mined by other causes, and to be very little dependent 
 on its superficial amount or fluctuations. It results 
 from the observations of Kotzebue, Eeechy, and Sir 
 James C. Eoss, as a general fact ascertained by thermo- 
 metric soundings, that the deep sea water below a 
 certain level, determined by the latitude, is of invariable 
 temperature throughout the globe, and that a very low 
 one; the calculations of Lenz, founded on Kotzebue's 
 results, giving 36° K, and those of Eoss 39 0, 5 (which 
 
40 
 
 METEOROLOGY. 
 
 last is the temperature at which pure water attains its 
 maximum of density). The depth at which the fixed 
 temperature is attained is about 7200 feet at the equator, 
 diminishing to lat. 56° on either side of that line, 
 where it attains the surface, and the sea (superficial 
 currents apart) is of equal temperature at all depths. 
 Thence, again, the upper surface of this uniform sub- 
 stratum descends, and at 70° of latitude has already 
 attained a depth of 4500 feet. Thus the ocean is 
 divided into three great regions; two polar basins in 
 which the surface temperature is below 39°, and one 
 medial zone above it, attaining 8° at the equator, and 
 at the poles of course the freezing point of sea water. 
 It is within these respective regions only, then, that 
 superficial currents can act as transporters of meteoro- 
 logical temperature. 
 
 (38.) The habitudes of dry land with relation to 
 incident heat are very different. There is no mobility 
 of parts, and the communication of heat downwards is 
 therefore entirely a process of conduction. But what 
 is most influential, is the fact that the absorption is 
 performed strictly on the exposed surface, which there- 
 fore in the instant of absorption fixes upon itself within 
 a very minute depth all the heat which, falling on water, 
 would in the same instant he disseminated through 
 many feet or yards of its substance. The mere super- 
 ficial film, then, becomes much more heated, and, since 
 it is a law of radiation that its intensity increases 
 rapidly with the temperature of the radiant surface, it 
 radiates out on the very instant a much larger fraction 
 
RELATIONS OF THE LAND TO SOLAR HEAT. 41 
 
 of the total incident heat than in the case of water, 
 besides imparting to the air by contact-communication 
 a proportionally greater amount. In water the absorbed 
 heat is for the most part withdrawn from the radiant 
 action, enveloped and husbanded. In dry land it is 
 instantly and wholly exposed to such action in its 
 most intense form. It is no uncommon thing in dry 
 and light ( i.e . badly conducting) soils, in hot climates, 
 to find a superficial temperature of 120°, 140° F., and 
 even more. We have ourselves observed it at 159° F. 
 at the Cape of Good Hope. In the arid regions of 
 Australia, Captain Sturt reports that a lucifer match 
 dropped on the ground takes fire. The surface water 
 of the equatorial seas is scarcely ever known to range 
 higher than 85° in the day and a degree or two lower 
 in the night. 
 
 (39.) That portion of the heat which enters the 
 soil is conducted downwards, and so long as the surface 
 is gaining in temperature, a wave of heat is continuously 
 propagated downwards into the earth. When the sur- 
 face, however, by the decline of the sun, begins to lose 
 heat, this ceases, and (the radiation still continuing) 
 what may be called a wave of cold (less comparative 
 heat) begins to be propagated, and so on alternately 
 during the day and night. These waves as they run 
 on spread forwards and backwards , and so by degrees 
 neutralize and destroy each other. Thus the diurnal 
 fluctuations of temperature beneath the surface grow 
 continually less as the depth increases; the rate of 
 diminution depending on the “conductility” of the soil. 
 
42 
 
 METEOKOLOGY. 
 
 In ordinary soils the difference between the diurnal 
 and nocturnal extremes becomes imperceptible at four 
 feet below the surface. (Quetelet, Mem . Acad. Brux., 
 1836.) In like manner, the general increase of heat- 
 due to the summer season, and of cold during winter, 
 are propagated in similar but larger and feebler annual 
 waves, which in their turn neutralize each other at more 
 considerable depths, and become imperceptible at 40 or 
 50 feet. Professor Porbes has shewn in an elaborate 
 memoir on this subject (Trans. R. S. Edin., xvi.) that 
 at depths varying from 57 to 99 feet, according to 
 the nature of the soil, the annual variation does not 
 exceed 0°.01 C. 
 
 (40.) The absorption of incident heat as solar heat , 
 and its radiation outwards as terrestrial heat (i. e. heat 
 of a much more absorbable nature) by the solid surface, 
 depends very much on the nature of its substance ; but 
 if the ground be covered with vegetation, the whole of 
 the incident heat is returned back either by radiation 
 or contact -communication to the air; and the soil 
 receives no heat where so covered, otherwise than cir- 
 cuitously through the medium of heated air. All these 
 causes acting together produce a vast difference as 
 respects the temperature of the air in regions of the 
 globe covered by the ocean and those occupied by dry 
 land. In the former its fluctuations, both diurnal and 
 annual, are confined within very much narrower limits 
 than in the latter; and this contrast, which theory 
 indicates, is confirmed by universal observation, as the 
 expression of the distinction between an insular and a 
 
TERRESTRIAL RADIATION. 
 
 43 
 
 continental climate, or that of a small island remote 
 from all other land and of the central regions of an 
 extensive continent. If there be one general feature 
 in meteorology more prominent than another it is the 
 uniformity of temperature over great bodies of water, as 
 compared to that under similar exposures to the direct 
 sun on land. 
 
 (41.) Terrestrial Radiation . — The theory of radiant 
 heat promulgated by Prevost, which all experimental 
 inquiry into the subject has tended to confirm, lays it 
 down as a principle, that a mutual interchange of heat 
 is continually taking place between all bodies freely 
 exposed to view of each other, the hotter radiating 
 more than the colder in the ratio of some function 
 increasing with the temperature. The experiments of 
 Dulong and Petit on the radiation of bodies in vacuo, 
 have shewn that this function, within the limits of 
 their experiments, is of the exponential form, or in 
 other words, that the force of radiation in vacuo 
 increases in geometrical progression as the excess of 
 temperature of the radiant body above that of its 
 envelope increases in arithmetical.* Hence, when a 
 hot body is placed in presence of bodies, some colder 
 some hotter than itself, an equilibrium will rapidly be 
 established, in which its momentary gains and losses of 
 heat to and fro among them all will balance each other, 
 and its temperature will thenceforward be unchanged. 
 
 (42.) Such will be the case if the body be com- 
 
 * There mast be some natural limit to such a law. Radiation 
 in absolute vacuity cannot be infinite. 
 
44- 
 
 METEOROLOGY. 
 
 pletely surrounded or enclosed by others. But if only 
 partially so, if there he an opening out into perfectly 
 free space, through which rays of heat can escape, and 
 from which none are returned, heat will constantly flow 
 out from such a system, and the body will be maintained 
 at a temperature lower than that of such partial enve- 
 lope, and the more so the larger the angular area of 
 the opening. 
 
 (43.) If it were certain that the vacuum, or setherial 
 medium in which the planets move, and which conveys 
 light, had absolutely no temperature of its own capable 
 of being imparted to matter, and if the air were per- 
 fectly transcalescent and incapable of radiation from its 
 own particles, or from those of impurities floating in it, 
 a thermometer placed a very small distance from the 
 ground, with an unobstructed view of the sky, would 
 receive from the hemisphere above it no heat but that 
 radiated from the stars and moon ; or (putting the moon 
 out of the question, as it is almost certain that no 
 portion of her heat escapes absorption in the air), none 
 bearing a greater ratio to that it would receive from the 
 sun, than the light of a starlight night to direct sun- 
 shine, which cannot exceed that of 1 to 100,000,000. 
 It may therefore be regarded as nil. 
 
 (44.) The mean temperature of the earth remaining 
 unchanged, it necessarily follows that it emits by radia- 
 tion from and through the surface of its atmosphere, on 
 an average, the exact amount of heat it receives from 
 the sun, i.e., as much as would melt 0*01093 in. in 
 thickness of ice per minute over the area of one of its 
 
TERRESTRIAL RADIATION. 
 
 45 
 
 great circles, or one-fourth of this thickness (0*00273 in.) 
 over its whole surface (art. 11, 12), which is equivalent 
 to 135-960ths of that quantity, or 0*000374 in. depth 
 of water per minute (or l-40th in. per hour), condensed 
 from its dew point. Taking this as the measure of the 
 total average radiation, one-third of it, or 1 -120th in., 
 may be taken as radiated off from the atmosphere 
 without ever reaching the earth, and the remaining 
 two-thirds (1-6 0th in.), may be considered as got rid of 
 by radiation, direct or indirect, from the surface of the 
 earth. In complete absence of any means of estimating 
 the ratio of these portions, we may suppose the latter 
 to be one-half of l-60th or 1 -120th in. Let us now 
 consider the manner in which this part of the process 
 takes place, supposing a clear sky to prevail. 
 
 (45.) Conduction through the soil is a very slow 
 process, radiation a very rapid one. So soon, then, 
 as the sun has sunk so low as not to counteract the 
 earth's radiation, the immediate surface begins to part 
 with its heat, at first, of course, slowly, but as night 
 advances, more rapidly, and at length much faster than 
 it can percolate from the interior to supply the waste. 
 The surface, therefore, becomes greatly chilled, and a 
 wave of cold (to use the mode of expression adopted in 
 art. 39), is propagated downwards, neutralizing and 
 destroying the heat-wave rising to meet it — a process 
 which goes on leisurely, and takes its own time. 
 Meanwhile the chilled surface now borrows heat from 
 the air also, to supply its waste, 1st, by contact-com- 
 munication; 2d, by downward radiation; and , 3 d, by 
 
46 
 
 METEOROLOGY. 
 
 condensation of vapour when the temperature of the 
 surface-air is reduced to the dew point , and thus attains 
 that state of equilibrium which the circumstances 
 admit of. The process is in fact in every respect the 
 converse of that described (art. 38), by whieh heat 
 penetrates the soil, the immediate surface exhibiting in 
 both cases the most sudden and violent effect of the 
 acting causes. 
 
 (46.) The most consecutive series of experiments 
 and observations we possess on terrestrial radiation, are 
 those of Dr. Wells, Professor Daniell, Captain Sabine, 
 and more recently Mr. Glaisher, the author of a very 
 elaborate memoir on the subject {Phil. Trans., 1847). 
 Our limits will only permit us to mention some of the 
 more prominent results obtained. The maximum of 
 terrestrial radiation takes place when a perfect calm and 
 cloudless sky prevail during a long night, in a level 
 country. Under these circumstances, there is nothing 
 to disturb the air immediately resting on the soil, so as 
 to replace the air cooled by contact with the chilled 
 surface by warmer air from above; and if a series of 
 thermometers be exposed at various heights above the 
 surface, that which is just not in contact will be found 
 to mark several degrees lower than the general tempe- 
 rature of the air, and the others at greater altitudes, 
 will stand progressively higher, up to about 10 or 12 
 feet, the difference, however, above 4 feet being very 
 trifling. 
 
 (47.) The depression of the thermometer exposed to 
 radiation in contact with any horizontal surface is 
 
TERRESTRIAL RADIATION. 
 
 47 
 
 greater as the radiating power of the substance of 
 which that surface consists is greater, and as its power 
 of conducting heat is less. The greatest depression 
 observed by Mr. Glaisher below a thermometer freely 
 suspended at 12 feet above the ground, was no less 
 than 2 8°. 5 Fahr. ! the lower thermometer being placed 
 on raw cotton wool on long grass. The relative de- 
 pressing powers of this and other supporting substances, 
 assigned by him from a mean of all his observations, are 
 given below ; long grass being taken as a standard. 
 
 Hare Skin . . . 1316 
 
 Rabbit Skin . . . 1240 
 
 Raw White Wool . . 1222 
 
 Flax . . . .1186 
 
 Raw Silk . . .1107 
 
 Un wrought White Cot- 
 ton Wool . . . 1085 
 
 Long Grass . . . 1000 
 
 Lamp-black Powder . 961 
 
 Flannel. . . .871 
 
 Glass .... 864 
 
 Sheet Copper . . 839 
 
 Coloured Lambs’ Wool . 832 
 
 Whiting-powder . .827 
 
 Charcoal Powder . .776 
 
 Jet-black Lambs’ Wool . 741 
 Sheet Zinc . . .681 
 
 White Tin . . . 667 
 
 Snow .... 657 
 Sheet-Iron . . . 642 
 
 Paper .... 614 
 Slate .... 573 
 Garden Mould . .472 
 
 River Sand . . . 454 
 
 Stone .... 390 
 Brick . . . .372 
 
 Gravel .... 288 
 
 (48.) When a thermometer is exposed with its bulb 
 in the focus of a concave silver hemisphere * or para- 
 boloid, highly polished both internally and externally, 
 and deep enough, when exposed with the concavity 
 upwards, to cut off from the thermometer all view of 
 the earth, and as it were to continue the sky beneath it, 
 it can only receive heat by condensation and radiation 
 
 * The figure is absolutely of no importance. A paraboloid is 
 generally used, for no reason that we can perceive but to increase 
 the cost. 
 
48 
 
 METEOROLOGY. 
 
 from the air, and from the condensation of moisture. 
 A thermometer so exposed under a clear sky, and 
 shaded from direct sunshine, always marks several 
 degrees below the temperature of the air, and its 
 depression affords a rude measure (of the statical kind, 
 and open to all the objections to which that kind of 
 measure is open. — See art. 13) of the facility for the 
 escape of heat by radiation afforded under the circum- 
 stances of exposure. As compared with exposure on 
 any of the supporting substances above enumerated, 
 the depressing power of such a reflector by Mr. 
 Glaisher’s experiments appears to be 888, that of long 
 grass being 1000, which is almost identical with that 
 of the glass of which the bulb is formed. If the axis 
 of such a reflector be directed to a cloud, or to any 
 terrestrial object, the thermometer immediately rises, 
 even should that object be the summit of a snow- 
 covered mountain (as we had ourselves occasion to 
 observe on April 18, 1824, from the roof of the 
 observatory at Turin, the snowy range of the Alps 
 affording an excellent object for trial). If directed to 
 a cloud, the height of the cloud is not indifferent — Mr. 
 Glaisher’s observations clearly shewing that the higher 
 the cloud the greater the radiation upward, whether 
 estimated by the reflector, or by the depression of 
 a thermometer laid on grass. Thus in nights uni- 
 formly and totally cloudy, the mean height of the 
 clouds being respectively 1900, 2800, and 3700 feet 
 (which his peculiar situation enabled him to ascertain), 
 the depressions were found to average 1°*6, 2° *5, 3 0, 9, 
 
TERRESTRIAL RADIATION. 
 
 49 
 
 clearly indicating the lower temperature of the higher 
 clouds. 
 
 (49.) As an instance of the effect of terrestrial radia- 
 tion applied to a practical purpose, may be mentioned 
 the manufacture of ice in the East Indies. The process, 
 as described by Mr. Williams {Phil. Tr., vol. lxxxiii. 
 p. 56), practised in Benares on an immense scale, con- 
 sists in exposing shallow porous earthen pans on straw 
 in a level area divided into compartments four or five 
 feet square. The pans are filled in the afternoon ; and 
 the temperature being much reduced by evaporation 
 before night, the freezing process is completed by radia- 
 tion at night. In this way Mr. Williams has often 
 seen ice 1 -J- inch in thickness produced in December, 
 January, and February, the thermometer at 5 £ feet 
 above the ground, marking from 41° to 46° Fahr. In 
 a night of 12 hours, it may be remarked, the mean 
 emission of heat from the earth's surface, taken as 
 two-thirds of the total mean radiation, would suffice for 
 the conversion of 480x0*00273 or 1*31 in. into ice 
 (art. 44). So that there can be no necessity to recur to 
 other causes than radiation (as has been done by some) 
 for a full account of the effect observed. 
 
 (50.) Of the evaporation and condensation of water , 
 and the dilatation of air , as elements of power in 
 Meteorological Dynamics. — Water, freely exposed to 
 the air. evaporates at all temperatures, even when in the 
 state of snow or ice. The rapidity of evaporation is, 
 however, much increased by warmth. Thus, in a calm 
 atmosphere, under the ordinary pressure, Dalton found 
 
 E 
 
50 
 
 METEOROLOGY. 
 
 that when, from a certain surface, the evaporation from 
 boiling water proceeded at the rate of 40 grs. per 
 minute, it was 20 grs. at a temperature of 180° Fahr., 
 13 grs. at 164°, 10 grs. at 152° and so on. C ceteris 
 
 paribus, in dry air the rapidity of evaporation is propor- 
 tional to the elastic force with which the generated 
 vapour tends to escape from the evaporating surface; 
 i. e., to the tension of vapour due to the temperature 
 of that surface. If the air he already moist, evapo- 
 ration is proportionally retarded, the force of escape 
 being the difference between the elastic tensions of the 
 generated vapour and of that already existing in the 
 air. Under a low atmospheric pressure, also, it is far 
 more rapid than under a high one, owing to the 
 comparative absence of obstruction to the diffusion of 
 vapour by the aerial particles — vapour being subject 
 to the same laws of diffusion and non-reciprocity of 
 pressure as other gases, and indeed, while maintained 
 in the vaporous state, to all the other laws of gaseous 
 statics and dynamics. Owing to the same reason, 
 evaporation is accelerated by wind blowing over the 
 evaporating surface, which removes the generated 
 vapour as fast as it is produced, and dispenses with 
 the slower process of diffusion upwards. Cceteris 
 paribus, moreover, the amount of water evaporated is 
 proportional to the surface exposed to air. It is much 
 greater, therefore, from rough and porous solid sub- 
 stances kept wetted (as, for instance, from moist soil 
 or from vegetation wetted by rain), than from the 
 surface of water itself ; and from the latter, when 
 
EVAPORATION OF WATER, A MOVING POWER. 51 
 
 agitated by winds or dashed in spray, than when 
 tranquil. 
 
 (51.) Evaporation never takes place without the 
 abstraction of heat from the evaporating surface. 
 Every grain of water evaporated carries off with it 
 sufficient heat to raise 960 grains, 1° Eahr., to supply 
 which, that quantity of the residual water must have 
 been cooled 1°. This heat, however, is latent , i.e ., 
 does not appear as temperature in the vapour produced, 
 which is no warmer than the surface from which it 
 emanates. On condensation, however, the absorbed 
 heat is given out again; and thus aqueous vapour 
 becomes an agent in the transfer of heat, in its latent 
 state, from one part of the globe, or from one region of 
 the atmosphere to another, just as a moving body 
 transfers the impetus which created its velocity to the 
 place where it encounters an obstacle. 
 
 (52.) Yapour introduced into the air acts as a 
 moving power in two distinct ways. 1st, By a simple 
 addition of volume. The tension of the vapour is 
 added to the elastic force of the air, according to 
 Dalton’s law, and increases by the same amount the 
 total power of the mixture to support pressure. Were 
 the specific gravity of vapour the same with that of air, 
 the effect of its introduction would be simply one of 
 distension. It would tend to relieve itself by lateral 
 diffusion, or removal of obstructing air ; and if prevented 
 from so doing, would simply heave up the incumbent 
 aerial column in struggling to diffuse itself, and so 
 increase its total vertical altitude. 2d, But a far more 
 
52 
 
 METEOROLOGY. 
 
 efficacious motive power originates in the less specific 
 gravity of the vapour of water than of air of the same 
 temperature (O’ 62 35 : 1). It is the lightest of all known 
 “ vapours,” and, with exception of hydrogen and 
 ammonia, the lightest of gases. In consequence, as 
 soon as generated, it tends to rise in the air by its 
 buoyancy, and in so doing, carries up with it much of 
 the air with which it is intermixed, disengaging itself 
 no doubt from it, in its upward progress, to become 
 entangled, however, with fresh particles, which again it 
 carries upward, to abandon them for others. In this 
 way, not only is its upward diffusion far more rapid 
 than its horizontal, but in its struggle upwards it tends 
 to produce an ascensional movement in the air itself, 
 and thus (as we shall presently see) to act as a powerful 
 agent in the production of wind. 
 
 (53.) Whenever vapour comes in contact with any 
 body, or arrives at any locality whose temperature is 
 lower than that due to its tension, a portion of it con- 
 denses into water, or, it may be, into ice. In so doing 
 it gives out again its latent heat, which is communicated 
 to the condensing body, raising its temperature, or else 
 is disseminated throughout the region, together with 
 the condensed particles. If the condensation be into 
 water, the heat thus reappearing as temperature is 
 precisely the same in amount as that taken up in 
 evaporating the same quantity of vapour from water, 
 or 960° Fahr. ; if into ice, the additional amount of 
 135°, which is that which becomes latent on the 
 conversion of ice into water is set free. If the 
 
VAPOUR : ITS EFFECT ON THE BAROMETER. 53 
 
 condensation takes place at tlie surface of the earth 
 the result is dew or hoar-frost, according as the surface 
 is above or below the freezing-point ; if aloft in the air, 
 the result is a cloud of mist, or, if abundant, rain, 
 snow, or hail. Eut in every case the condensation of 
 vapour is accompanied with a mitigation of cold at the 
 point where it actually takes place . The same is true 
 of the freezing of water, however contrary to ordinary 
 notions. Were it not for this, our winters would be 
 intolerable. 
 
 (54.) It is clear, moreover, that the generation of 
 vapour, under any extensive region, more rapidly than 
 it is carried off by diffusion or otherwise, must be 
 attended with an increase of barometric pressure, since 
 the total weight of the atmosphere vertically over any 
 region must be supported by the total area of surface, 
 and equally so that its condensation, provided the con- 
 densed water he abstracted from the atmosphere , must 
 lead to a diminution of pressure. The contrary will 
 happen if the vapour generated be carried off as fast as 
 produced by such a general upheaving of the aerial 
 strata over any region as shall subvert their equilibrium, 
 and cause them to overflow, upwards and laterally. In 
 such a case, since air also will be carried off bodily from 
 the region, and be replaced by vapour, the mean specific 
 gravity of the whole aerial column, and its total weight, 
 will be diminished, and the barometric pressure lowered. 
 This takes place on a most extensive scale over the 
 intertropical seas. The temperature of the surface 
 water in them is habitually very elevated (from 78° at 
 
54 
 
 METEOROLOGY. 
 
 the tropics to 83° at the equator), and varies very little 
 by the vicissitudes of season, or the alternation of day 
 and night. A steady and copious evaporation is there- 
 fore continually going on. Yapour, carrying with it 
 air, is constantly thrown up beyond the levels of 
 equilibrium, where it flows over and spreads itself out 
 over the upper regions of higher latitudes. The imme- 
 diate consequence is a habitual deficiency of barometric 
 pressure at the sea-level on the equatorial, as compared 
 with that on the extra-tropical seas. In a voyage to 
 the Cape of Good Hope in 1833-4, the writer of these 
 pages found this decrease from the tropics to the equator, 
 on either side, to amount to 0*24 in. He was not at 
 the time aware that the fact had before been noticed by 
 Schouw and Humboldt. 
 
 (55.) The dilatation of the air itself by beat, whether 
 communicated to it from the earth, or radiated directly 
 into it from the sun, acts in a somewhat different 
 manner. Air is dilated only by about one-tenth of its 
 volume by 50° Fahr. increase of temperature, so that 
 unless locally and violently heated, its effect in pro- 
 ducing bodily uprushing currents is comparatively less 
 than that of the introduction of vapour into its mass. 
 When heated over large tracts, it acts rather by 
 increased elasticity to upheave the superincumbent 
 strata, and, by bulging them upwards, to destroy their 
 equilibrium, and cause the upper atmosphere to flow 
 over on less heated regions. The general effect, how 
 ever, is similar; and as the sun cannot generate vapour 
 without at the same time heating the air, it is impossible 
 
THE WINDS. 
 
 55 
 
 to separate their dynamical effects. Whether the air 
 go forth from its place jproprio motu , or he jostled out 
 of it by the introduction of a lighter medium, the 
 local relief of pressure is equally produced. 
 
 (56.) Of the ivinds. — Among the proximate agents 
 in meteorology, the winds hold the first place. To 
 their agency is owing the subversion of what Humboldt 
 has termed the solar climate of the world (or that 
 which would exist were the atmosphere motionless), 
 and the production of its real climate. This they 
 effect in two ways, viz., 1st, Directly , by transferring 
 into regions remote from their origin the heated air 
 and aqueous vapour (charged with latent heat) which 
 the sun’s direct action generates ; and, 2dly, Indirectly , 
 by causing currents in the ocean, which convey to one 
 locality the surface water heated in another. In both 
 ways they effect a constant circulation, both of heat 
 and moisture, the two great elements of climate, which 
 cannot therefore be understood till we know something 
 of the habitual force and direction of these great aerial 
 movements, considered on an extensive scale. 
 
 (57.) A very small difference of atmospheric pres- 
 sures, as a moving power, suffices to generate a con- 
 siderable wind. Calculating from a formula given by 
 D. Bernouilli to express the velocity of a gas issuing 
 through an orifice in a vessel in which it is compressed, 
 into surrounding air of less elasticity, it appears that, 
 to generate in atmospheric air, velocities of efflux equal 
 respectively to 10, 20, 30; 60, 90, 120; and 150 feet 
 per second (or of 7, 14, 21 ; 41, 61, 82; and 92 miles 
 
56 
 
 METEOROLOGY. 
 
 per hour), would require corresponding effective differ- 
 ences of pressure of 0-006 in., 0*010 in., 0*016 in., 0*06 
 in., 0*14 in., 0*25 in., and 0*41 in. These may he taken 
 as the velocities of wind in a gentle air ; a light breeze ; 
 a good sailing breeze ; a gale ; a great storm ; a tempest ; 
 and a hurricane producing universal desolation, sweeping 
 away buildings, and tearing up trees. The correspond- 
 ing pressures of the wind per square foot on a plane 
 surface, perpendicularly opposed to it, are respectively 
 in pounds 0*2, 0*9, 1*9; 7*5, 16*7, 30*7; 37*9. It 
 must he borne in mind, however, that for such pressures 
 to produce the velocities ascribed to them, they must 
 be supposed to act unmitigated by any graduation, 
 which is never the case in nature, the transition from 
 a higher to a lower pressure at stations remote from 
 each other being always extremely gradual, so that 
 barometric elevations and depressions to a much larger 
 extent may and do exist without giving rise to great 
 winds. It is only when sensible differences subsist 
 between the pressures at places near each other that 
 violent phenomena arise. 
 
 (58.) We have seen that the immediate effect of the 
 application of heat to any region is to generate an 
 ascensional movement in the incumbent atmosphere, 
 a bodily overflowing of its material above, and a relief 
 of barometrical pressure below. The air of the cooler 
 surrounding region not being so relieved (but rather 
 the contrary, owing to the increase of weight poured on 
 it from above), will he driven in by the difference of 
 hydrostatic pressures so arising, and thus originate two 
 
THE TEADE WINDS. 
 
 57 
 
 distinct winds, an upper one setting outward from the 
 heated region, a lower inward . If the region heated 
 he a limited one, these currents will radiate from and 
 to it as a centre ; if a linear tract, or a whole zone of 
 the globe, such as the generally heated intertropical 
 region, they will assume the character of two sheets of 
 air setting inwards on both sides below, uniting and 
 flowing vertically upwards along the medial line, and 
 again separating aloft, and taking on a reversed move- 
 ment. 
 
 (59.) In this account of the production of wind, 
 however, no account is taken of the earth's rotation on 
 its axis, which modifies all the phenomena, and gives 
 their peculiar character to all the great aerial currents 
 which prevail over the globe. The first clear perception 
 and announcement of this cause, as affording an expla- 
 nation of the trade winds (otherwise inexplicable), is 
 due to Hadley (Phil. Tr ., 1735), and affords a beautiful 
 demonstration of that great astronomical principle as a 
 physical fact. To form a right estimate of its importance, 
 it is only necessary to observe, that of all the winds 
 which occur over the whole earth, one-half at least, 
 more probably two-thirds, of the average momentum is 
 nothing else than force given out by the globe in its rota- 
 tion in the trade currents, and in the act of reabsorp- 
 tion or resumption by it from the anti-trades. 
 
 (60.) Since the earth revolves on an axis passing 
 through its poles from west to east, each point in its 
 surface has a rotatory velocity eastward proportional to 
 the radius of its circle of latitude, and any body of air 
 
58 
 
 METEOROLOGY. 
 
 relatively quiescent on that point will have the same. 
 Conceive now such a body to be urged by any impulse 
 in the direction of a meridian towards the equator. 
 Since such impulse communicates to it no increase of 
 easterly velocity it will find itself, at each point of 
 its progress, continually more and more deficient in 
 this element of movement, and will lag behind the 
 swifter surface below it, or drag upon it with a relative 
 westerly tendency. In other words, it will no longer 
 be a direct north or south wind, hut, relatively to the 
 surface over which it is moving, will assume continually 
 more and more the character of a north-easterly or 
 south-easterly one, according as it approaches the 
 equator from the north or south. 
 
 (61.) Meanwhile, however, the earth is continually 
 actiqg on the air by friction, and communicating to it 
 rotatory velocity. As it approaches the equator, in 
 whose vicinity the diurnal circles increase more slowly, 
 the relative westerly tendency is continually less and 
 less reinforced by the cause which produced it, and the 
 counteraction arising from friction acquires energy, till, 
 on arriving near the equator, the wind loses its easterly 
 character altogether; while the northern and southern 
 currents here meeting and opposing, mutually destroy 
 each other, producing a calm; and become deflected 
 upwards to form an ascensional current replacing the 
 air abstracted. The result, then, is the formation of 
 two great tropical belts, in the northern of which a 
 north-easterly, and in the southern a south-easterly 
 wind prevails, while the winds in the equatorial belt 
 
THE ANTI-TRADE WINDS. 
 
 59 
 
 which separates them, are comparatively feeble and free 
 from any steady prevalence of easterly character. This 
 is the general description of the trade winds as actually 
 observed. 
 
 (62.) A precisely contrary set of re-actions takes place 
 on the upheaved or displaced equatorial air. In flow- 
 ing over to regain its level, it commences its course 
 relatively in a meridional direction, but really with the 
 full amount of easterly velocity which the earth's 
 equator has; and since this, as it proceeds north or 
 southwards, is in excess of what would suffice to keep 
 it on the same meridian, it continually deviates to the 
 eastward ; and when it again returns to the earth in 
 its circulation, which it does on both sides beyond the 
 tropics, it does so with a powerful westward tendency, 
 and the more, as in its course it has been less under 
 the influence of surface friction, owing to the elevated 
 region in which it has travelled. It thus restores to 
 the mass of the earth the momentum abstracted by it 
 in the former phase of the cycle. We have here the 
 origin of the S.W. and westerly gales, so prevalent in 
 our latitudes, and of the almost universally westerly 
 winds in the northern and southern extra -tropical seas. 
 The existence of an upper current, opposite in direction 
 to the under, is a matter of frequent observation, as 
 shewn by the courses of a lower and higher stratum of 
 clouds. 
 
 (63.) Were the whole globe covered with water, and 
 the sun always in the equinoctial, the system of the 
 trades and anti-trades (for so the compensating westerly 
 
60 
 
 METEOROLOGY. 
 
 winds may conveniently be designated) would be per- 
 fectly symmetrical about the equator, as their medial 
 line. Two causes tend to derange this symmetry, viz. 
 — ls£, The movement of the sun in declination, which 
 carries it alternately away from the equator to 23|- u on 
 either side ; and 2d, The existence and peculiar form 
 of the continents. 
 
 (64.) Suppose the sun at the northern tropic. At 
 that time, the region beneath the southern being 47° 
 from the circle of vertical sunshine, will be receiving 
 little more than half its- maximum of solar heat (art. 12), 
 and the circle of 47° latitude will be receiving as much 
 heat as the equator itself, or more, the days being 
 longer. If this state of things were permanent, the 
 neutral line would shift from the equator to the northern 
 tropic, carrying the whole system of the trades with it. 
 But the sun approaches the tropic gradually, and does 
 not remain there, but returns to the equator; and as, 
 moreover, the general temperature of the ocean follows 
 very slowly the action of its rays (art. 40), these effects 
 cannot be fully wrought out, or nearly so, and the 
 utmost that could arise would be a very moderate 
 northerly transfer of the medial line, and with it, of the 
 inner and outer limits of the trades ; and as the reverse 
 effects will of course arise when the sun gets into south 
 declination, the result altogether will issue in a perio- 
 dical annual oscillation of the wind system to and fro 
 on either side the equator; the maximum excursions 
 falling later in the year than the precise epochs of the 
 solstice, on the general principle that cumulative 
 
PERIODICAL WINDS — MONSOONS. 
 
 61 
 
 EFFECTS NECESSARILY ATTAIN THEIR MAXIMUM LATER IN 
 POINT OF TIME THAN THEIR CAUSES. 
 
 (65.) This is very nearly an accurate account of the 
 real state of things in the Pacific Ocean, whose vast 
 extent brings it within the general scope of our hypo- 
 thesis, and in which the north-eastern trade extends 
 from about 2° to 23° north latitude, in its mean situa- 
 tion, and the south-eastern from about 3° to 21° south 
 latitude. Between them lies an equatorial belt of 
 about 5° in breadth, of such habitual calm as to have 
 given a name to the ocean itself. The annual oscilla- 
 tion is confined within very moderate limits. 
 
 (66.) In the Atlantic the disturbing influence of 
 the continents is very sensibly felt. The great mass of 
 Africa, and especially of its sandy and burning deserts, 
 lies considerably north of the equator. These become 
 intensely heated, and their temperature follows the sun 
 much more closely than that of the sea. There can be 
 no doubt that the medial line of the trades crosses 
 Africa considerably to the north of the equator, nor 
 that the annual oscillation of the northern trades at 
 least is very great, and the influence extends to the 
 neighbouring Atlantic. In this ocean the equatorial 
 limit of the north-east trade shifts with the season 
 from 5° 15' to 11° IT. lat., and that of the south from 
 about 2° to 3° 15' IT., so that the medial line lies always 
 a little north of the equator. 
 
 (67.) It is in the Indian seas, however, and especially 
 in the vicinity of the great Asiatic continent, that the 
 disturbing influence of the land is most clearly exhi- 
 
62 
 
 METEOROLOGY. 
 
 bited, issuing in a complete reversal of the north-east 
 trade during a considerable portion of the year, and the 
 production of monsoons, i. e., of winds which blow half 
 the year in one, and the other half in the contrary 
 direction. When the sun is south of the equinoctial, 
 it being the cold season in those continental regions, 
 the regular trade winds prevail throughout those seas, 
 and what is called the north-east monsoon is in fact no 
 other than the undisturbed north-east trade wind. 
 But where the sun has north latitude, and especially 
 about the northern solstice, it is vertical over a very 
 large region of Arabia, Hindostan, Bengal, Burmah, 
 and Cochin, which become, of course, intensely heated. 
 Under these circumstances, besides the permanent line 
 of maximum temperature in the equatorial sea, there is 
 developed another more intense and less regular line 
 of the same nature, under or near the northern tropic, 
 towards w T hich, and not towards the equator, a large 
 proportion of the intermediate air is drawn. Receiving 
 thence a northern impulse, and that impulse carrying it 
 into a region of less rotatory velocity than that which 
 it has left, it assumes a relative south-west direction, 
 and is called the south-west monsoon. Meanwhile, 
 south of the equator, the south-east trade continues to 
 prevail from May to October over all that part of the 
 Indian Ocean which is not skirted with large tracts of 
 land to the south; but where this is the case, as in the 
 Java seas, as far as New Guinea, which are skirted to 
 the south by the great Australian continent, we have 
 again a double maximum, and the phenomenon of a 
 
LAW OF ROTATION OF THE WIND. 
 
 63 
 
 N.W. monsoon taking the place of the S.E. trade. 
 Those who would wish to pursue this subject into 
 details, are referred to Dove’s Meteorological Researches, 
 Kamtz’s Meteorology, and Horsburgh’s India Directory, 
 and more especially to the wind-charts published by 
 the Board of Trade. The setting in of the monsoon is 
 generally accompanied by deluges of rain and thunder- 
 storms of excessive violence. 
 
 (68.) Sea and land winds . — The uniformity of tem- 
 perature over a surface of sea, compared with that over 
 land, gives rise to winds alternately setting to and 
 from the land, at those seasons when it is powerfully 
 heated in the day time, while at night its temperature 
 sinks to an equality, or even sometimes below, that of 
 the sea surrounding it. As the hottest and coldest 
 hours of the day are about 2 p. m. and a little before 
 sunrise, the winds in question necessarily attain their 
 greatest power at somewhat later epochs in the day. 
 
 (69.) Dove's law of rotation of the wind . — It is not, 
 however, merely in the great system of aerial move- 
 ments which affect the whole atmosphere, that the 
 influence of the earth’s rotation is felt. Even very 
 limited local movements are modified by it. It is a 
 remark as old as Lord Bacon ( de Ventis , 1600), and 
 since confirmed by Mariotte in France, Sturm in Ger- 
 many, Toaldo in Italy, and many other writers both 
 in Europe and North America, that the wind has a 
 decidedly preponderating tendency to veer round the 
 compass according to the sun’s motion, i.e., to pass 
 from N. through N.E., E. S.E., to south, and so on 
 
64 
 
 METEOROLOGY. 
 
 round in the same direction through west to north ; that 
 it often makes a complete circuit in that direction, or 
 more than one in succession (occupying sometimes many 
 days in so doing), but that it rarely veers, and very 
 rarely or never makes a complete circuit in the contrary 
 direction. M. Dove in his “ Meteor ologische Untersuch- 
 ungen ,” was the first to shew that this tendency is a 
 direct consequence of the cause above mentioned. 
 
 (70.) Suppose at any station in north latitude, 
 after a calm, the air over and around the place, for 
 some considerable distance, to receive an impulse in 
 the direction of a meridian, carrying it towards the 
 equator. The first air which passes over the station, 
 coming from its immediate neighbourhood, has the 
 same rotatory velocity as the station, and therefore 
 passes it as a north wind . But the movement con- 
 tinuing, that which arrives subsequently having set out 
 from a continually higher and higher latitude, arrives 
 with continually less and less rotatory velocity, and 
 therefore in its passage over the station, will relatively 
 decline more and more to the east, and pass as a north- 
 east wind. If now the southward movement relax, 
 and at length cease, the relative motion from the east 
 will continue for a while, till destroyed by friction, 
 and the wind will for the moment have become a 
 direct east wind. Now, suppose a contrary impulse 
 given, or that the mass of air begins to travel again 
 northward, the east wind will evidently begin to he 
 deflected towards the north in its direction, and will 
 become a south-east wind. As the northward move- 
 
LAW OF THE WIND’S ROTATION. 
 
 65 
 
 ment continues, the fresh arrivals will bring with them 
 an excess of rotatory velocity, or a tendency to blow 
 relatively from the west and will thus first neutralize 
 the easterly character, changing the wind from SE. to 
 S., and finally overcome it, passing into a south-west 
 wind. If, then, the other oscillation take place, and the 
 mass of air begin again to travel southward, the wind, by 
 the very same reasoning, will gradually change to west, 
 then by FW. to H., and finally come round again to 
 the HE. It is obvious that for a station in south 
 latitude, the conditions being reversed, a contrary law 
 of rotation ought to prevail. Observations in south 
 latitude are in great measure wanting by which to test 
 this theory. In north, as we have seen, it is found 
 conformable to fact. 
 
 (71.) In the tropical regions, where the superficial 
 air always flows towards the equator, no such oscillatory 
 movement northwards and southwards, as is above 
 supposed, takes place. Where monsoons exist, there is 
 but one such oscillation annually, and accordingly the 
 wind makes one annual circuit ; but in the temperate 
 zones beyond the trades, as casual circumstances deter- 
 mine, equatorial and polar tendencies alternately pre- 
 ponderate, and every oscillatory movement so impressed 
 is thus converted into a circulation in a fixed direction. 
 
 (72.) Cyclones . — The West Indian seas, those about 
 Mauritius, and the China seas, are infested with hurri- 
 canes , or storms of wind, of excessive violence, pro- 
 ductive of frightful devastation both on land and on 
 sea, and which, in addition to the interest which such 
 
 F 
 
66 
 
 METEOKOLOGY. 
 
 scourges must always command, have of late come to 
 possess a peculiar one in the eyes of meteorologists, on 
 account of the remarkable features in their history 
 brought to light by the laborious researches of Professor 
 Kedfield, Colonel Reid, and Mr. Piddington. By a 
 collection of the log-books of ships which have 
 encountered such storms, and the comparison of the 
 recorded directions of the wind, at different periods of 
 their progress on land, in regions devastated by them, 
 the following general facts respecting them have been 
 established, viz., 1st, That in any such hurricane, the 
 movement of the air (regarding its whole extent) is 
 vorticose. They are in fact whirlwinds, though often 
 of vast magnitude, the diameters of some of them, 
 which have been already traced, exceeding 500 miles, 
 though for the most part not more than 200 or 300. 
 Hence the name given to them of cyclones. 2d, The 
 centre of the vortex is not fixed, but travels leisurely 
 enough (from 2 to 30 miles per hour), along certain 
 tracts. In the West Indies they are confined to a 
 pretty definite area, their usual course being in a para- 
 bolic curve, having some point near Bermuda for its 
 focus — originating in the Gulf of Florida — and running 
 along the coasts of the United States, following 
 generally the course of the Gulf Stream, and sweeping 
 across the Atlantic, occasionally visiting our island. 
 In the southern Indian seas, according to Mr. Pidding- 
 ton (, Sailor’s Handbook), they follow also parabolic 
 curves, the vertices of which often sweep round the 
 isles of Mauritius, Rodriguez, and Bourbon, and whose 
 
HURRICANES AND CYCLONES. 
 
 67 
 
 average focus is a point about 25° S. lat. and 70° E. 
 long. Along the arcs of these parabolas, in both 
 regions, the initial movement of the centre of the storm 
 is westward, so that the movement of the cyclone in 
 its parabolic orbit is contrary to that of the wind in 
 the cyclone itself. 3d, In cyclones which occur in the 
 northern hemisphere, the rotation of the air is invariably 
 in the contrary direction of the hands of a watch laid 
 face uppermost ; in those of the southern 
 
 hemisphere this rule is reversed and the movement is 
 . 4th, They originate between the tropics, and 
 run outwards from the equator towards the poles. 
 But on the equator itself they never occur . 5th, They 
 are announced by a rapid fall of the barometer, the 
 depression being greatest in the centre (sometimes 
 amounting to two inches !) 6th, The wind is most 
 violent in the neighbourhood of the centre of the 
 cyclone, but as the centre itself passes over any spot, a 
 momentary calm is observed, the wind immediately 
 recommencing in the reverse direction to what it had 
 the instant before (a necessary consequence of the 
 vorticose motion). 
 
 (73.) A complete account of all these characters is 
 afforded by Hadley’s principle, as developed by Dove 
 in his “ Law of Rotation,” and applied to this specific 
 class of aerial movements by Professor Taylor. Suppose 
 (in the northern hemisphere), that owing to the appli- 
 cation of local heat, a tendency in the air over some 
 extensive locality C, to ascend in a vertical column 
 should arise. To supply the place of the air so ascend- 
 
68 
 
 METEOROLOGY. 
 
 ing, an indraught from all the surrounding region will 
 commence. Let the equal lines Nn, 1-1, 2-2, 3-3, Ee, 
 
 N 
 
 Fig. 1. 
 
 &c. (fig. 1) represent the forces and directions of 
 currents drawn in from equidistant points, situated to 
 the K, KNE., NE., EKE., East, &c. ; then, were the 
 oarth at rest, these currents would all press towards C 
 with equal force, and the lines NVa, &c., would be 
 terminated by concentric circles, and a mere vertical 
 ascending current without gyration would result. But 
 the earth revolving from W. to E., take to the westward 
 
ATMOSPHERIC TIDES AND WAVES. 
 
 69 
 
 of n , na to ~Nn as the difference of the rotatory 
 velocities at N, n to the velocity of the indraught ; 
 join Nn, which will then represent the relative force 
 and direction of the current setting in from N ; and a 
 similar construction being made at every other point, 
 the system of relative currents will he that represented 
 by the arrows Na, 1 b, 2 c, 3 d, E e, &c. And it needs 
 but a bare inspection of the figure to perceive that such 
 a system terminating in an ascensional movement over 
 the tract C can be no other than a vortex or spiral eddy 
 in the direction of the internal curved arrow, i. e., in a 
 direction contrary to the motion of the hands of a 
 watch laid face upwards. In the southern hemisphere 
 it will be the reverse, as will appear on drawing the 
 figure. 
 
 (74.) It is also obvious that the force of the vortex 
 so arising must be in proportion to the strength of its 
 efficient causes. In high latitudes there is a deficiency 
 of solar heat and aqueous evaporation to produce a suffi- 
 ciently powerful ascending current. On the other 
 hand, on the equator, with abundant heat, the other 
 efficient cause, viz., a difference of diurnal rotatory 
 velocity, is absent. 
 
 Atmospheric Tides and Waves. 
 
 (75.) Atmospheric waves . — The atmosphere, like the 
 ocean, has its waves, which are rendered sensible by 
 the increase or diminution of barometric pressure, as 
 the crest or the trough of the wave passes over the 
 
70 
 
 METEOROLOGY. 
 
 place of observation. They are, however, on a nmch 
 vaster scale than those of the sea, as might he expected, 
 from the greater mobility of the medium, and the 
 extent of surface over which their exciting causes 
 act simultaneously. Eut they are distinguished from 
 the latter by features of a peculiar kind, which depend 
 on two causes, viz., 1st, the varying density of the air 
 from the earth upwards ; and 2d, The fact that the 
 disturbances in which they originate are not (as in the 
 case of the sea-waves) merely superficial, but extend 
 through the whole depth of the atmosphere, and are 
 most powerful at the ground level. 
 
 (7 6.) A very good general notion may be formed of 
 the peculiar modification of waves which depend on a 
 decreasing density of the medium in which they are 
 excited, by pouring into a large glass vessel fluids of 
 different densities which do not mix, and which have 
 different colours. An undulatory movement impressed 
 on such a system disappears very speedily from the 
 surface of the uppermost fluid, but continues long after 
 to agitate the lower strata; and moreover the latter, 
 while possessing the inertia which belongs to their entire 
 densities, but the preponderant weight, which corres- 
 ponds only to their differences of density from those 
 above them, are less controlled by gravity in proportion, 
 and their excursions above and below their planes of 
 equilibrium are therefore vastly exaggerated. Again, 
 if there are several such strata, which is easily managed 
 by carefully pouring, one over the other, several fluids 
 (even if miscible , provided actual mixture be avoided), 
 
ATMOSPHERIC TIDES. 
 
 71 
 
 their undulations are far from maintaining any paral- 
 lelism or correspondence ; and it will be found practi- 
 cable to propagate in them waves of independent 
 origin, and differing in direction, mutually reacting 
 on each other. The aerial waves are, besides, exag- 
 gerated by the elasticity of the medium, the portion 
 thrown up, ijpso facto , dilating itself, and therefore 
 swelling into a higher convexity than it would assume 
 if inelastic. 
 
 (77.) As the attractions of the sun and moon tend 
 to produce an elliptic distortion in the spherical outline 
 of the ocean (whose vertex follows the luminaries), and 
 which thus becomes converted into a great circulating 
 tide-wave, with two maxima and two minima in the 
 luni-solar day; so the heat of the sun producing a far 
 more considerable elevation of the lines of equal density 
 ( which when so elevated cease to he statical level lines), 
 and a far greater deviation from the figure of dynamical 
 equilibrium in the aerial hemisphere beneath it ; while 
 the nightly chill on the other side acts in a contrary 
 way on the opposite hemisphere ; a similar, but much 
 more considerable circulating wave, or what may be 
 called a heat-tide , is generated, following the sun (as 
 all cumulative and periodical effects follow their 
 causes) at a certain interval, but which differs from the 
 sea-tide wave in having only one elevation and one 
 depression, and in having a mean solar day for its 
 period. The gravitation tide of the atmosphere, de- 
 pending on the joint attractions of the sun and moon 
 will give rise to no greater difference of level in the 
 
72 
 
 METEOROLOGY. 
 
 aerial strata than what the same causes produce in the 
 ocean itself, viz., about six feet. Its effect on the 
 barometer therefore, would amount at the maximum 
 to less than 1-1 30th of an inch. 
 
 (77, a.) The direct effect of the diurnal heat-tide on 
 the barometer in an atmosphere free from aqueous 
 vapour would be even less in amount than this. In 
 fact, the heat-wave itself in such an atmosphere would 
 be one of form, and not of pressure ; since each column 
 of the air, though dilated in altitude by the increase of 
 temperature, undergoes no diminution of weight by 
 such expansion. The direct effect indeed would be 
 altogether nil but for the reaction on the earth’s 
 surface arising from the alternate elevation and depres- 
 sion of the centre of gravity of each atmospheric 
 column through a vertical altitude of about 726 feet 
 (taking exempli gratia , 20° Fahr. for the difference of 
 day and night temperature, and applying the formula 
 (7) art. 30). But the length of the period in which 
 this oscillation is performed (viz., 24 hours or 86,400 sec ), 
 reduces the motive force of this reaction to an almost 
 infinitesimal equivalent of barometric pressure (less 
 than 1 -700,000th of an inch). Equally inappretiable 
 will be the effect of this, as a motive force acting 
 laterally to thrust air from the hot hemisphere into 
 the cold. An indirect effect, however, by no means of 
 so very minute an order, results from the elevation of 
 the surface of the atmosphere above the figure of 
 equilibrium on one side, and depression below it on 
 the other. To form some rough estimate of this effect. 
 
ATMOSPHERIC HEAT-TIDES. 
 
 73 
 
 whose exact calculation would be difficult, we must 
 consider that an elevation of 363 feet on one side, and 
 a similar depression on the other, correspond to a slope 
 of 3".5 at the common boundary of the two hemispheres, 
 down which the centre of gravity of each aerial column 
 situate on that boundary (being unsupported laterally), 
 tends to glide. The effect of this will be the production 
 of a general movement of air setting outwards from 
 the heated hemisphere, and which, though feeble (as 
 its velocity would, at its maximum, hardly exceed a 
 mile an hour), yet acting over the whole circumference 
 of a great circle of the globe, would transfer a sensible 
 fraction of the whole atmosphere backwards and for- 
 wards. Taking the earth’s radius at 4000 miles; a 
 bodily extension of the air in one hemisphere of 1 3 - 
 miles in excess of its amplitude would correspond to a 
 mean diminution of pressure of a hundredth of an inch 
 of mercury (the indirect effect thus being 7000 times 
 greater than the direct !) 
 
 (78.) Were the sun constantly vertical over the 
 equator (exactly as in the astronomical theory of the 
 tides), no annual fluctuation of this kind would arise; 
 but as the point of maximum heat oscillates from 
 tropic to tropic, an annual transfer of air from hemi- 
 sphere to hemisphere takes place, producing a fluctua- 
 tion analogous to the menstrual inequality of the tides 
 arising from the moon’s change of declination — only as 
 there is 365 times more time given for this cause to 
 work out its effect, than in the case of the diurnal heat 
 tide, the extent of the annual variation in the baro- 
 
74 
 
 METEOROLOGY. 
 
 metric pressure thus produced in the mode above 
 characterized as indirect must he very considerable: 
 and for the same reason, as in the diurnal fluctuation, 
 the wave which causes it is single not double crested. 
 
 (79.) It is not with these fluctuations, however, that 
 we are now concerned. They are greatly modified, and 
 not only powerfully exaggerated but essentially altered 
 in their character by the alternate generation and con- 
 densation of aqueous vapour, and will therefore more 
 properly be considered under another head. The 
 atmospheric waves here considered are those which 
 originate, not from the general movement of the whole 
 body of the atmosphere, but from internal displace- 
 ments, the result of winds diverted from their course, 
 or of great local disturbances of temperature, due to a 
 concurrence of circumstances which may be termed 
 casual, forasmuch as we cannot trace their laws. Such 
 waves have been traced by comparing hourly observa- 
 tions of the barometer made by numerous observers, 
 on certain days determined by preconcerted arrange- 
 ment, in distant places : the progress of the waves, their 
 general direction, their height, and velocity, being con- 
 cluded from the rise and fall of the barometer as 
 noted in each. Thus, to cite some instances, it has been 
 found that on the 21st of September 1836, by observa- 
 tions made at Markree, Limerick, Halifax, Oxford, 
 London, Brussels, Hanover, Geneva, Turin, Gibraltar, 
 and Cadiz, a wave having a barometric depth of 0*2 in., 
 was ascertained to have passed over the British Isles and 
 the west of Europe, having its crest nearly in the 
 
ATMOSPHERIC WAVES. 
 
 75 
 
 direction NNE. or SSW., and the direction of its pro- 
 gress nearly from WNW. to ESE. The half breadth 
 of this wave, which occupied nearly 26 hours in its 
 passage, extended from Oxford to near Halle in 
 Wiirtemherg (about 540 miles). Its velocity of advance 
 was about 26 miles per hour. Again, on the 21st of 
 December 1837, a very well defined wave travelled in 
 a direction from 10° north of W. to 10° south of E., at 
 the rate of 18*62 miles per hour. The total depth of 
 this wave from crest to trough was measured by fully 
 inch of barometric pressure, so that the level strata 
 must have fluctuated through a vertical height of at 
 least 700 feet. The area over which this wave was 
 traced, is marked by fifteen stations of observation, 
 extending from Markree in Ireland, to Parma in Italy. 
 — {Brit. Ass. Rep. 1843.) 
 
 (80.) It would appear from the researches of Mr. 
 Birt, that a very remarkable wave of this kind (to 
 which he has given the name of “ the great November 
 wave”) passes annually over these islands and the 
 adjacent regions (embracing probably the whole of 
 Europe and the seas on its north-west coasts in its 
 range), the crest extending in a direction from NE. to 
 SW., the direction of progress (at right angles to this 
 or) from Nff. to SE., the velocity about nineteen 
 miles per hour. Both the breadth and depth of this 
 wave are on a vast scale. The whole wave occupies 
 about fourteen days in its transit, the crest passing 
 over London about the middle of November, so that 
 its total breadth cannot be less than 6000 miles, while 
 
76 
 
 METEOROLOGY. 
 
 the extent of barometric elevation from its trough to 
 its crest seldom falls short of an inch, and occasionally 
 amounts to double that quantity. What is no less 
 remarkable, there is a certain region (in which London 
 is included), over which the rise and fall of the baro- 
 meter during the transit of the wave exhibit a con- 
 siderable resemblance, so that a section of it, in the 
 direction of its advance, would be a symmetrical curve, 
 the middle crest being preceded and followed at about 
 five days’ interval by two lower ones, and the begin- 
 ning and the end marked by deep depressions. The 
 researches of M. Le Yerrier leave no doubt that the 
 great Crimean storm of the 14th November 1854, of 
 disastrous memory, was part and parcel of this pheno- 
 menon. 
 
 Anemometry. 
 
 (81.) The wind, regarded as a meteorological 
 element to be measured and recorded, differs from 
 other elements, inasmuch as it offers two distinct 
 objects of measurement, viz., its direction and velocity ; 
 three, indeed, since the quantity of air passing over 
 a given place of observation varies as the velocity 
 and density jointly. This, however, is a nicety into 
 which meteorologists have not yet thought it worth 
 while to go, being content to regard the number of 
 miles travelled over by the wind in a given direction 
 as expressing the material transfer of the air in that 
 direction. In fact, as different and often opposing 
 currents co-exist at different levels, it would be a 
 
ANEMOMETRY. 
 
 77 
 
 useless refinement to do so. The direction and velocity, 
 however, are essential features. The former is readily 
 determined by a well-constructed vane, erected high 
 enough to he out of the reach of eddies and either 
 read off on a divided circle to degrees of deviation from 
 the meridional direction, or so mechanically arranged as 
 to register itself at every instant. The velocity may 
 be measured (or self-recorded) in several different ways. 
 As, for instance, first by causing the wind to act per- 
 pendicularly (as in Osier's anemometer) against a 
 square foot of surface, so as to drive hack a spring of 
 known elasticity, the extent of compression determining 
 the number of pounds which equilibrate the momentum 
 per square foot, and which (like the direction) may be 
 self-recorded at every instant. Secondly, by causing it 
 to drive round the fans of a light vane, presented always 
 perpendicular to its direction, and registering the 
 number of its turns by means of an endless screw and 
 wheelwork, as in WhewelTs construction (C. U. Phil. 
 Tr. vi. ; improved by Dr. Kobinson, Mem. R I. Acad, 
 xxii.), which has the advantage of giving not merely 
 the momentary velocity, but the total or integral 
 amount of space run over, or the transfer of air per day, 
 per hour, or per minute, as may be required. 
 
 ( 82 .) Since the whole of the air in the region 
 surrounding the place of observation participates in the 
 movement so recorded, and must be considered as 
 transferred bodily at each instant with a motion equal 
 and parallel, the particle which was first over the spot 
 will describe a curve whose elementary arc and direc- 
 
78 
 
 METEOROLOGY. 
 
 tion are determined, and may therefore be traced, either 
 by hand or by a self-acting movement in the mechanism 
 of the anemometer on any scale. Suppose (fig. 2) A p 
 q v B to be the trace of one day’s movement, A S the 
 direction of the meridian, p , q, r, the points attained at 
 stated hours, t v t 2 , &c., and let Q 1? Q 2 , Q 3 , &c. be the 
 angles p A P, q p a, r qb, &c., or the directions of the 
 
 wind, reckoned round the compass from the north, 
 eastwards, and v lf v 2 , &c. its velocities ; then since p P 
 = v . sin. Q, AP = v . cos. Q ; if dt be the element of the 
 time, we shall have AS = fvdt. cos. and BS =fvdt. 
 sin. 0, from t = 0 to t = 24 h. in strictness and approxi- 
 mately — 
 
 BS = v v sin. 4* v 2 . sin. + &c. = A 
 
 AS = v 1 . cos. Q 1 4 v 2 . cos. + &c. = B 
 
 So that if AB be joined, AB representing the mean 
 movement during the twenty-four hours, if AB = Y, 
 and BAS = p, we shall have 
 
ANEMOMETRY. 
 
 79 
 
 A 
 
 Y = s/ A 2 + B 2 ; tan. <p = ^ 
 
 whence the mean velocity and direction, during the 
 twenty-four hours, may he calculated from a series of 
 registered numbers, or from the measurement of AB and 
 BS on the self-registered trace. 
 
 (83.) AB, BC, CD, DE, &c., represent the mean 
 diurnal movements during a week, month, or year (fig. 
 3), so, by a similar system of calculation, may the mean 
 
 weekly, monthly, or annual direction and velocity be 
 computed. Hitherto it has not been possible to obtain 
 the necessary data for any considerable number of 
 stations, the instruments required being both costly and 
 comparatively of recent construction. But no class of 
 observations is calculated to afford more insight into 
 the sequence of meteorological changes : and they can- 
 not be too earnestly recommended to general attention. 
 Meanwhile, in the absence of all information as to the 
 velocity of the wind, it has been the practice to assume 
 all winds as of equal force , or rather that the force of 
 
80 
 
 METEOKOLOGY. 
 
 winds may be regarded, on the average, as measured by 
 tbe frequency of tbeir occurrence. The formula given 
 by Lambert for the average direction and force of the 
 wind is founded on this supposition (a most misleading 
 one), and consists in substituting for v ly v 2 , &c., in the 
 general values of A and B above given, the numbers 
 n v n 2 , and in which the winds N., NNE., NE., &c., 
 making angles ^ == 0, 0 2 = 22°.l, Q 3 = 45°, &c., supposing 
 the circumference divided into sixteen “ points or 
 = 0, $ 2 = 45°, &c., if only into eight points. As there 
 exists an abundance of observations in which the direc- 
 tion of the wind, per vane , is thus recorded daily, a 
 rude approximation to the desired results can thus be 
 made for a great number of localities. Kamtz and 
 Dove have thus computed the mean annual force and 
 direction, as well as their monthly variations, for a 
 great number of stations in Europe and North 
 America, the general result of which the former has 
 embodied in a synoptic table, as below, viz. — 
 
 
 Direction. 
 
 Force. 
 
 England 
 
 S. 66° W. 
 
 0.198 
 
 France and Holland ... 
 
 S. 88 W. 
 
 0.135 
 
 Germany 
 
 S. 76 W. 
 
 0.177 
 
 Denmark 
 
 S. 62 W. 
 
 0.170 
 
 Sweden 
 
 S. 77 W. 
 
 0.228 
 
 Eastern Europe 
 
 N. 87 W. 
 
 0.167 
 
 Northern part of United States ... 
 
 S. 86 W. 
 
 0.182 
 
 in which the numbers under the column headed Force 
 express the values of V in the formula so modified. 
 
OCEANIC CURRENTS. 
 
 81 
 
 Of Oceanic Currents as Distributors of Heat 
 and Moisture. 
 
 (84.) The winds act indirectly as distributors of 
 heat and moisture, by producing currents in the ocean. 
 Were there a free communication round the globe, at 
 or about its equator, the continuous action of the trades 
 could not fail to establish a westerly circulation of the 
 equatorial waters with little deviation to the north or 
 south ; and were the whole globe covered with water, 
 the compensating SW. and NW. winds beyond the 
 tropics would produce two extra-tropical easterly cur- 
 rents, surrounding the globe, and separated from the 
 equatorial one by zones of still water, a lively picture 
 in short of what is most probably the state of the planet 
 Jupiter (the rotatory velocity of whose equator is 26 
 times greater than the earth's) as concluded from the 
 appearance of its belts. 
 
 (85.) The continent of America, however, which pre- 
 sents an unbroken barrier as far as the 55th degree of 
 south latitude, effectually prevents the equatorial current 
 from making a complete circuit round the globe, its 
 passage round Cape Hoorn being barred by the contrary 
 southern compensating current. Its passage round the 
 Cape of Good Hope, also, is materially impeded, though 
 not prevented, by a similar cause, so that in the Atlantic 
 two vast eddies are formed, in the southern of which the 
 water, deflected along the Brazilian coast till it meets the 
 opposite current at Cape Hoorn, joins that current, and 
 is swept eastward with it. In the northern it is thrown 
 
 G 
 
82 
 
 METEOROLOGY. 
 
 upon the north-east coast of South America, through 
 the Caribbean Sea, obliquely into the hollow of the 
 Gulf of Mexico, where it is suddenly and violently 
 deflected to the north-west, and issues in what is 
 called the Gulf Stream, to which, as a very powerful 
 agent in determining our own climate, we must devote 
 some small space, referring the reader for further details 
 on the subject of currents to works on Hydrography, 
 and to the chart of Oceanic Currents by Captain Beechy, 
 in the Admiralty Manual of Scientific Enquiry , p. 106. 
 
 (86.) The Gulf Stream, where it quits the Gulf of 
 Florida, has a velocity of from three to five miles per 
 hour (varying with the season), a breadth of only 
 a few miles, and a temperature of 83°. Thence it 
 follows the coast of America to about the 36th degree 
 of latitude, where it still possesses a temperature of 
 76° Fahr., and where it quits the coast about Cape 
 Fear, and encircling the Azores, spreads itself in wide 
 diverging streams over the basin of the Atlantic, between 
 the coasts of America and Spain, forming a vast eddy, 
 overgrown with the “ sargasso” or Gulf weed. The 
 main stream, however, continues to run north-west- 
 ward, directed full towards the British Islands, to 
 about the 46th parallel, in the 40th degree of west 
 longitude, where its force is much weakened by sub- 
 division. The surface water, however, continues to 
 flow onwards in the same direction, and its presence on 
 our western shores is evidenced by the warm vapours 
 the south-west winds waft from above it, and by 
 tropical plants and seeds thrown ashore on the west 
 
PRECIPITATION OF VAPOUR. 
 
 83 
 
 coast of Ireland, on the Hebrides, and even on Norway. 
 Were the isthmus of Panama broken through, there is 
 no doubt that the whole climate of our islands would 
 undergo a most notable deterioration. 
 
 Of the precipitation of Vapour, and the formation 
 of Dew, Pogs, Clouds, and Rain, etc., Hygrometry. 
 
 (87.) Air and vapour, according to the views of 
 Deluc (first distinctly announced in a very remarkable 
 paper, Phil Tr. 1792, p. 400), and the theory of the 
 independent elasticity of gases in general, announced by 
 Dalton in 1801, form two distinct and in great measure 
 independent atmospheres ; the one permanent in mate- 
 rial and constant in quantity — the other in a continual 
 state of destruction and renovation. Wbre the tempera- 
 ture of all regions of the globe alike, no precipitation of 
 vapour in the form of rain or snow would ever take 
 place. A certain definite amount of vapour once gene- 
 rated and diffused, would remain as a permanent con- 
 stituent of the atmosphere, and each aerial stratum 
 would exist in a state of habitual exact saturation, so 
 that no further evaporation would take place from a 
 moist surface at whatever level exposed. Rut owing 
 to the equatorial heat, the polar cold, and the great 
 system of circulation established by the winds, the at- 
 mosphere is converted into a great distilling apparatus, 
 and the vapour raised in warmer regions is continually 
 being precipitated in colder, according to laws which 
 we are now to trace. 
 
84 
 
 METEOROLOGY. 
 
 (88.) The most immediate, though assuredly not 
 the most obvious result of this state of things, is a 
 general fact avouched (like the cold of the higher 
 regions) by all mountain travellers and all aeronauts, 
 viz. — The habitual liygrometric or relative dryness of 
 those regions in clear weather. This is shewn by 
 very ordinary but very demonstrative facts. Thus 
 Deluc remarked that the head of his walking stick 
 always fell off in high mountain ascents, from the 
 shrinking of the wood. We have seen that were 
 there never any rain, etc., each stratum of the air 
 would be in an exact state of saturation, and no 
 evaporation would be possible from a moist surface at 
 any level. “ But * every act of precipitation, no matter 
 how produced, unsettles this state of things, and with- 
 draws from the total mass of air some portion of its 
 entire amount of vapour. As such precipitations, 
 therefore, are constantly going on in some place or 
 other, the atmosphere, as a mass, though incumbent 
 on a wet and evaporating surface, is necessarily always 
 deficient in moisture; and for the very same reason, 
 every superior stratum is relatively deficient in com- 
 parison with that immediately beneath it, from which 
 its supply is derived. In point of ultimate causation, 
 then, there is a constant drain on the aqueous contents 
 of the atmosphere, arising from changes of temperature. 
 This drain extends to all its strata; but while the 
 
 * Essays from the Edinburgh and Quarterly Reviews, etc., by 
 the author of this work (London, Longman and Co., 1857), 
 p. 353. 
 
HYGROMETRY. 
 
 85 
 
 lower renew their losses from a surface hygrometrically 
 wet , the upper draw their supply from sources more 
 and more deficient in moisture.” What the equatorial 
 depression of the barometer at the sea level then is to 
 the system of winds, such is the habitual hygrometric 
 dryness of the air above the clouds to that of rains — at 
 once an indication of a process in progress, and an 
 efficient agent in continuing it. Wherever such 
 relative dryness exists, vapour, by its own expansive 
 nisuSy is in the act of transfer in an invisible state 
 from one atmospheric region to another, and the 
 rapidity of that transfer is proportional, cceteris paribus , 
 to the degree of dryness, as the velocity of a river at 
 any point is to the inclination of its surface to the 
 horizon. This by no means supposes a universally 
 prevalent deficiency of vaporous tension. Complete 
 saturation must exist at the points of evaporation and 
 deposition, but at intermediate ones any amount of 
 irregularity may prevail according to local circum- 
 stances. 
 
 (89.) Hygrometry . — To obtain a measure of this 
 important element is the object of hygrometry , which 
 consists in determining by instrumental means the 
 absolute quantity of water existing, as vapour, in a 
 given volume (suppose a cubic foot) of air, under any 
 circumstances of temperature and pressure, and thence, 
 from the known specific gravity of vapour, deducing 
 its elastic force or tension. For the ways in which 
 this may be accomplished, and for a description of the 
 instruments used, the reader is referred to the article 
 
86 
 
 METEOROLOGY. 
 
 on Hygrometry, in the Encyclopaedia Britannica and 
 other similar digests. The method now adopted in 
 preference to all others, as the most simple and con- 
 venient in practice, and leading to results which a very 
 severe examination has proved to be quite satisfactory, 
 is the simultaneous observation of the wet and dry 
 thermometer. The formula of reduction, as it results 
 from Dr. Apjohn’s elaborate investigations, is as 
 follows : — Let t , t f be the respective readings of the 
 wet and dry thermometers (in degrees Fahrenheit), h 
 the barometric pressure in inches, / the elastic force of 
 saturated vapour at the temperature t , and F its elastic 
 force at the “ Dew-point,” or at that temperature which 
 the air ought to have, so as to be exactly saturated 
 with the quantity of vapour it actually contains. Then 
 will 
 
 * = /- 
 
 t'—t 
 
 80 
 
 T' X ^ h 
 
 or, F =/— 96 • 3q5 
 
 (») 
 
 the equation (a) or (b) being used according as t, the 
 reading of the wet thermometer, is above or below 32°. 
 / is found from a table of the elastic force of saturated 
 vapours (see Steam) at different temperatures, which 
 will also be found in the Admiralty Manual of 
 Scientific Enquiry , p. 321 ; and F being calculated 
 from the above expression, the dew point may be had 
 from the same table, used reversely, i.e., entering the 
 table with F and finding the corresponding tempera- 
 ture. F known, the weight of water per cubic foot is 
 found by multiplying the weight of a cubic foot of dry 
 air at 30 inches (563*2124 grs.) by the specific gravity 
 
DEW. 
 
 87 
 
 of steam for elasticity F, i.e ., by F x 0*6235, or by the 
 formula F X 35*166. Copious tables for facilitating 
 the whole process have been published by Mr. Glaisher 
 ( Hygrom . Tables , Lond. E. and J. E. Taylor. 1847). 
 
 (90.) If the temperature of any given space con- 
 taining vapour be higher than its dew-point, water 
 exposed in it will evaporate. The air it contains is 
 then said to be relatively more or less dry, or (in 
 reference to the old chemical theory of solution 
 advanced by Hutton, the language of which being con- 
 venient, is retained, though the theory is exploded), 
 under-saturated. If lower, some portion of the vapour 
 will begin to be precipitated, and this precipitate 
 assumes various forms, according to the circumstances 
 under which a sufficiently low temperature is produced. 
 
 (91.) I. Dew . — When the mass of moist air is 
 simply brought into contact with a cold body, the 
 result is dew , which is deposited in minute globules of 
 water on the body, or if the temperature of the latter 
 be below the freezing-point, ice or hoar-frost. The 
 nature of these phenomena was, up to a late period, 
 strangely misconceived, — the effect, by a mistake very 
 common in meteorology, being put for the cause, the 
 dew being regarded as 'producing the chill accompanying 
 it, instead of the reverse. Dr. Wells, in his “Essay 
 on Dew” — a little work which deserves to be con- 
 sidered as a model of experimental inquiry-^- was the 
 first to place in a clear light the true nature of the 
 process. The chief facts to be accounted for are these : 
 — 1st. Dew (as distinguished from small rain or the 
 
88 
 
 METEOROLOGY. 
 
 moisture produced by visible fog) is never deposited 
 except on a surface colder than the air. 2d. It is 
 never deposited in cloudy weather ; and so strict is its 
 connection with a clear shy , that its deposition is 
 immediately suspended whenever any considerable 
 cloud passes the zenith of the place of observation. 
 3d. It is never copiously deposited in a place screened 
 or sheltered from a clear view of the shy , even if the 
 screen be of very thin material, such as muslin or 
 paper suspended over it. 4th. It is most copiously 
 deposited on all such bodies as are good radiants and 
 bad conductors of heat , such as grass, paper, glass, wool, 
 etc., but little or not at all on bad radiants , such as 
 polished metals, which are also good conductors. And, 
 lastly, it is never deposited if there be much wind 
 All these circumstances, as Dr. Wells has shewn, point 
 to the escape of heat from the bodies exposed by 
 radiation out into space , or into the upper and colder 
 regions of the air, faster than it can be restored by 
 counter-radiation or by conduction from contact with 
 the warm air or with solid substances— wind acting in 
 this respect with great efficacy, by continually renewing 
 the air in contact. Hoar-frost differs only from dew 
 by being frozen in the moment of deposition, and 
 therefore accreting in crystalline spiculse. 
 
 (92.) II. Mist or Fog . If a table of vapour tension, 
 or the formula from which such a table is calculated, 
 viz. 
 
 Tab. Log. (-^) = — 0. 0085412197 0.0000208109. <2+0. 000000058. <3 
 
 where p is the elastic force of saturated vapour, corres* 
 
FOG. 
 
 89 
 
 ponding to a temperature of 212 ° — t Fahr. (Biot, TV. 
 de Pliys. i. 278), be projected into a curve (fig. 4.), 
 taking t for an abscissa, and p for an ordinate, it will 
 be found to bave the form PDQ convex in every part 
 towards its axis or asymptote A B. Hence, if between 
 any two dew-point temperatures, A M, A 1ST, an arith- 
 metical mean A B be taken, and P Q, the ends of the 
 ordinates joined, B E will express the arithmetical 
 mean of the extreme ordinates, or of the elasticities at 
 
 the two temperatures, and B D (less than B E) that 
 corresponding to their mean. Hence it is evident, that 
 if two equal volumes of air, saturated at temperatures 
 t and H be mixed, since the mixture will have the 
 mean temperature, water must be precipitated, the 
 corresponding vapour tension being less than the 
 mean. The form in which the moisture so pre- 
 
90 
 
 METEOKOLOGY. 
 
 cipitated first appears, will necessarily be that of very 
 minutely divided particles, which, however, having 
 the refractive power of water, reflect and refract light 
 as such, and appear therefore as a mist, fog, or cloud 
 of greater or less density and opacity, according to the 
 amount precipitated in a given volume. It is a 
 favourite dogma with many meteorologists, that the 
 particles so precipitated assume the form, not of drops, 
 but of hollow spheres or bubbles. De Saussure states, 
 that he has seen such floating before his eyes in clouds 
 and fogs on the Alps,* and the dusty appearance of the 
 vapour floating over a cup of coffee in the sunshine is 
 adduced in proof. The strongest argument in their 
 favour, however (for there is great room for optical 
 illusion in such matters), is that adduced by Kratzen- 
 stein, that the sun striking on a cloud or fog produces 
 no rainbow, which it ought to do were the water col- 
 lected in spherical drops . This argument does not 
 
 admit of a ready answer; but the difficulty, on the 
 other hand, of conceiving any possible mode in which 
 such bubbles can be formed, disposes us to believe 
 that the extreme minuteness of the globules may be 
 found to afford one, their diameters being probably 
 of an order comparable with the breadths of the 
 luminiferous undulations, t 
 
 * [I have never, myself, seen such a phenomenon, and have 
 questioned Alpine excursionists of far more extensive experience 
 than my own, with alike negative reply. Note added Feb. 1861.] 
 
 I [On the Newtonian doctrine of fits of easy transmission 
 and reflexion, or (which comes to the same thing), on the hypo- 
 
RADIATION FOGS. 
 
 91 
 
 (93.) Radiation Fogs and River Mists . — When the 
 air in contact with a radiating surface has been reduced 
 in temperature to the dew-point, and has discharged its 
 superfluous moisture in dew or frost, it remains satu- 
 rated and at the same time colder than that above it. 
 If the ground be quite level, and the air quite calm, 
 however, little or no mixture will take place, the upper 
 air remaining uppermost, in the absence of any reason 
 for its descent, or for the rise of that beneath. But if 
 the ground slope ever so little towards a valley or 
 hollow basin, the cold air will run downwards, and 
 mixing with the air below, if sufficiently near to satu- 
 ration, will depress the mean temperature of the 
 mixture below its resultant dew-point, and produce 
 fog. If the low ground be occupied by water or 
 marsh, as the air reposing on it is sure to be saturated, 
 copious precipitation will necessarily result. If dry, 
 
 thesis of light consisting in rotating corpuscles with attractive and 
 repulsive poles — there would be no difficulty of the kind. A 
 globule (or a particle of water of any other form) whose greatest 
 linear diameter did not exceed the thickness of that central spot 
 in a soap-bubble which reflects little or no light, would be 
 equally non-reflective, and therefore incapable of forming a rain- 
 bow. In the undulatory theory, however, it is the parallelism of 
 the surfaces of the film of which that central spot consists which 
 renders it non-reflective. I suspect, however, that in the case 
 contemplated in the text, that theory, carefully re-examined, 
 would render a somewhat different account of the singular 
 abruptness of transition from the most brilliant reflexion to an 
 almost absolute extinction of the reflected ray, and of the uni- 
 formity over large areas of a thin film of the very small remaining 
 fraction of the incident light which it does reflect, than that 
 usually given. Note added Feb. 1861.1 
 
92 
 
 METEOROLOGY. 
 
 the mist produced will he less copious, and may not 
 even take place at all. In the Weald of Kent, a 
 district abounding in grassy slopes and winding and 
 branching valleys, in the calm clear nights which are 
 there so frequent, beautiful instances of radiation-fog 
 are of perpetual occurrence. Immediately after sunset, 
 in clear weather, dew commences — streams of cold air 
 set downwards, following the lines of shortest descent 
 (very sensible as descending currents), their course 
 being marked with mist, thin and filmy at first, but 
 acquiring density in its downward progress, and by 
 degrees filling the valleys with fog, which, in the morn- 
 ing before sunrise, presents exactly the aspect of a 
 winding lake or river of water, whose surface, per- 
 fectly even and horizontal, runs a sharply defined level 
 line round every promontory and into every retreating 
 nook. Descending into such a lake under a full moon, 
 a few yards below its upper surface, a lunar rainbow 
 is frequently seen in the mist. We on more than one 
 occasion have resorted to a particular spot well situated 
 for the purpose, to look for one, and have not been dis- 
 appointed. (Here then, at least, the argument of 
 Kratzenstein for vesicles is inapplicable.) By far the 
 finest lunar rainbow we have ever been fortunate 
 enough to witness (Nov. 12, 1848) was formed in a 
 dense fog, evidently close at hand , which, however, 
 was beginning to resolve itself into a fine, light, mizzling 
 rain. On this occasion the exterior or secondary bow 
 was seen. 
 
 (94.) It is a matter of ordinary remark, that the 
 
BAKOMETEIC AND DIFFUSIONAL FOGS. 
 
 93 
 
 spring frosts are severer in hollows and low grounds 
 than on slopes and heights. This is an obvious con- 
 sequence of what has been said. The cold air flows 
 downwards, and collects in the hollows, being replaced 
 on the heights by the air of a higher stratum, unchilled 
 by radiation. 
 
 (95.) A radiation-fog once formed tends to its 
 own increase, by radiating off heat from its own 
 particles, water in the liquid state being a good radiant 
 of caloric. 
 
 (96.) When the warm current in the open ocean 
 encounters a shoal, the lower water (of inferior tempera- 
 ture) is thrown up to the surface. The surface-water, 
 therefore, on the shoal is colder than that of the sur- 
 rounding ocean, and the atmospheres (saturated at the 
 respective temperatures) mingling, produce those fogs 
 which are observed to be prevalent in such localities. 
 The fogs of Newfoundland are a remarkable instance 
 in point. Togs, too, are produced in the neighbour- 
 hood of floating icebergs, on a similar principle. The 
 Arve, in its descent from Chamouni, occasionally pre- 
 sents the appearance of a river of warm water throwing 
 up steam (though, in fact, many degrees colder than the 
 air), from the mixture of the cold air above it with the 
 saturated warmer air of the valley through which it 
 flows (Obs. Aug. 1821). 
 
 (97.) Barometric fogs . — The temperature of a mass 
 of air may be lowered beneath the dew-point, indepen- 
 dent of radiation, contact of a cold body, or mixture 
 with colder air, by the simple effect of its own expansion. 
 
94 
 
 METEOROLOGY. 
 
 This may take place in two ways, viz., 1st, By a rapid 
 and considerable relief of barometric pressure from 
 above ; or, 2dly, By its own ascent into a higher region 
 of the atmosphere. The first case takes place when the 
 trough of an atmospheric wave (see art . 75) passes 
 rapidly over the place of observation. The fog so 
 produced comes on for the most part suddenly, and 
 without any obvious cause. It is not rolled in from a 
 distance by the wind, nor does a moderate wind dis- 
 sipate it. It is not confined to the surface of the 
 ground, but extends at once to great altitudes. It does 
 not resolve itself into rain, but disappears, when the 
 atmospheric equilibrium is restored, by the recon- 
 densation of the air, and the reappearance of its sensible 
 heat. Such fogs are very common, and are precisely 
 analogous to the cloud produced in the receiver of 
 an air-pump by a rapid partial expansion of the air. 
 They want a name, and that of barometric fogs seems not 
 inappropriate. 
 
 (97, a.) Dijfusional fogs . — There is a fog of not very 
 frequent occurrence in our climate, which comes on 
 gradually, in a perfectly calm state of the air, without 
 any sudden or considerable diminution of barometric 
 pressure, and which evidently arises from a gradual 
 increase of humidity in the air, at length attaining the 
 dew-point. Such fogs would seem, not unnaturally, to 
 result from the quiet lateral diffusion (see § 21, 52, 87) 
 of vapour as a gas from some neighbouring or slowly 
 approaching mass of vapour-loaded air, in anticipation 
 of its bodily arrival as a moist or rainy south-west 
 
CLOUDS. 
 
 95 
 
 wind. To sucli a fog the epithet of “ Diffusional” may 
 not improperly be applied. 
 
 (98.) III. Clouds . — When a body of vapour is gene- 
 rated from any warm evaporating surface, it ascends by 
 its relative levity, losing sensible heat, as well by its 
 own expansion as by its bodily transfer into and inter- 
 mixture with colder air. Should the supply of vapour, 
 however, not be very copious, and should it find itself, 
 in its ascent, always in a region hygrometrically dry, it 
 by no means follows that it will reach the point of 
 precipitation ; but should the reverse of these conditions 
 obtain, viz., a copious and continued supply from below, 
 and a state of vaporous tension already existing aloft 
 approaching saturation, a portion will be precipitated in 
 visible cloud on arriving at a certain level. When this 
 process takes place in a calm state of the air, and the 
 evaporating surface is limited in extent, or irregularly 
 distributed in patches (as over marshy ground, rivers, 
 lakes, &c.), or if any other cause dispose the vapour to 
 rise in columnar bodies of greater or less extent, the 
 summits of these are marked by protuberant masses or 
 piles of cloud, with generally rounded outlines, which 
 appear to repose on flat bases, indicating the “ vapour 
 plane,” or that level where hygrometric saturation 
 commences. To such clouds, in Howard’s Nomen- 
 clature of Clouds , the names of Cumulus is assigned. 
 They abound in the calm latitudes of the equatorial 
 seas, and form a distinguishing feature in the meteoro- 
 logy of that region. 
 
 (99.) That the mere self-expansion of the ascending 
 
96 
 
 METEOROLOGY. 
 
 air is sufficient to cause precipitation of some of its 
 vapour, when abundant, is rendered matter of ocular 
 demonstration in that very striking phenomenon so 
 common at the Cape of Good Hope, where the south 
 or south-easterly wind which sweeps over the Southern 
 Ocean, impinging on the long range of rocks which 
 terminate in the Table Mountain, is thrown up by 
 them (as marked by the direction of the arrows in fig. 
 5), makes a clear sweep over the flat table-land which 
 forms the summit of that mountain (about 3850 feet 
 high), and thence plunges down with the violence of a 
 
 cataract, clinging close to the mural precipices that form 
 a kind of background to Cape Town, which it fills 
 with dust and uproar. A perfectly cloudless sky 
 meanwhile prevails over the town, the sea, and the 
 level country, but the mountain is covered with a dense 
 white cloud, reaching to no great height above its 
 summit, and quite level, which, though evidently swept 
 along by the wind, and hurried furiously over the edge 
 of the precipice, dissolves and completely disappears on 
 a definite level, suggesting the idea (whence it derives 
 its name) of a “ Table-cloth.” Occasionally, when the 
 wind is very violent, a ripple is formed in the aerial 
 
NOMENCLATURE OF CLOUDS. 
 
 97 
 
 current, which, by a sort of rebound in the hollow of 
 the amphitheatre in which Cape Town stands, is again 
 thrown up, just over the edge of the sea, vertically over 
 the Jetty, where we have stood for hours watching a 
 small wiiite patch of cloud in the zenith, a few acres in 
 extent, in violent internal agitation (from the hurricane 
 of wind blowing through it), yet immovable, as if fixed 
 by some spell, the material ever changing, the form 
 and aspect unvarying. The Table-cloth is formed also 
 at the commencement of a “ north- wester,” but its 
 fringes then descend on the opposite side of the moun- 
 tain, which is no less precipitous. Fig. 1, Plate III, is 
 a careful representation of such an exhibition of it on 
 May 20, 1835. 
 
 (100.) Nomenclature of Clouds . — The forms and 
 aspect of clouds are very indicative of the circumstances 
 under which they are in the act of forming or dissipat- 
 ing. Howard ( AsJcesian Lectures , 1802) has endea- 
 voured to embody their chief characters in a determinate 
 nomenclature, which has been generally adopted. He 
 divides clouds into three primary modifications ; Cumulus, 
 Stratus, and Cirrus, with intermediate forms graduating 
 into one another under the names Cumulo-stratus, Cirro- 
 stratus, Cirro-cumulus, and, lastly, a composite form, 
 resulting from a blending or confusion of the others, 
 under the name Cirro-cumulo-stratus or Himbus. 
 
 (101.) Cumulus has been already described. Mr. 
 Howard defines it as sursum crescens , increasing upward 
 from a horizontal base. This is in conformity with its 
 origin. When sharply terminated by rounded spherical 
 H 
 
98 METEOROLOGY. 
 
 forms, which under sunshine appear as snow-heaps, the 
 form clearly indicates the act of self-dissipation in 
 invisible vapour into the upper relatively dry air. 
 
 (102.) Stratus consists of horizontal sheets. Its 
 situation is low in the atmosphere, and may he con- 
 sidered as intermediate between cloud and fog, being 
 chiefly formed at night, and under the influence of 
 radiation either from the surface of a ground fog (as 
 already described), or from impurities floating in the 
 air itself. The latter is remarkably the case in great 
 cities in which coal is chiefly consumed as fuel, and 
 gives rise to those dense, yellow, suffocating fogs 
 which infest London in the winter months. A very 
 peculiar phenomenon exhibited by the London atmo- 
 sphere has been described to us by the Astronomer- 
 Eoyal, and appears to he referable to the same cause. 
 In calm evenings after sunset, as seen from the Eoyal 
 Observatory on Greenwich Hill, the vast irregular mass 
 of smoke hovering over London appears to subside. 
 Its heaped and turbulent outline becomes flat, and 
 sinks rapidly into a low level cloud-hank, with a very 
 definite outline, and fair sky above. It would seem 
 that each particle of soot, acting as an insulated 
 radiant, collects dew on itself, and sinks down rapidly 
 as a heavy body. Stratus is also sometimes formed 
 very suddenly on a higher level, when in a clear, calm 
 night the general temperature of the air sinks by 
 radiation, or by diminution of atmospheric pressure, 
 till at some definite altitude above the surface the dew- 
 point is attained. Thus, on the night of April 19, 
 
NOMENCLATURE OF CLOUDS. 
 
 99 
 
 1827, the sky, up to 16k. 16m. Sid. T, being perfectly 
 cloudless, and not a breath of wind stirring, stratus at 
 a high level commenced in the eastern horizon, and in 
 eight minutes had extended to the western, obscuring 
 the whole sky, the calm remaining unbroken. In this 
 case the velocity of propagation of the edge of the 
 cloud from east to west (or following the sun) could 
 not have been less than 300 miles per hour (Mem. Ast. 
 Soc. iii. 51). 
 
 (103.) Cirrus consists of fibrous, wispy, or feathery 
 clouds occupying the highest region of the atmosphere. 
 The name of mares’ tails, by which cirri are commonly 
 known, describes their aspect well. Of all forms of 
 cloud these present the greatest variety. Their fila- 
 mentous structure clearly indicates them as either in 
 the act of originating from the union of aerial currents 
 running parallel to each other, or as the residues of 
 dissolving cloud drawn out into fibres by wdnd. Mr. 
 Howard is disposed to assign to them an electric origin, 
 or at least to attribute their fibrous appearance to 
 electricity, but in this view we cannot coincide. From 
 the great elevation of cirrus it is more than probable 
 that its particles are frozen, and of course crystalline, 
 and that to this constitution it is owing that halos, 
 coronse, and other optical appearances referable to 
 reflexions and refractions in ice crystals, appear almost 
 invariably in this cloud and in its derivative forms, 
 especially the cirro-cumulus. It is said to he often a 
 precursor of windy weather. 
 
 (104.) The Cirro-cumulus , most characteristically 
 
100 
 
 METEOROLOGY. 
 
 known as a “mackarel sky,” consists often of small 
 roundish masses disposed with more or less regularity 
 and connection. They usually float at great elevations 
 and often appear as a loftier stratum through the 
 intervals of lower clouds, contrasting strongly by their 
 slow (and sometimes contrary) movement, with the 
 scud and drift of the inferior masses. They are frequent 
 in summer, and attendant on dry and warm weather. 
 
 (105.) Cirro-stratus “ appears to result from the 
 subsidence of the fibres of cirrus to a horizontal 
 position, at the same time approaching laterally. The 
 form and relative position when seen in the distance 
 frequently give the idea of shoals of fish.” It often 
 precedes wind and rain, and often forms the ground on 
 which halos and parhelia are projected. 
 
 (106.) Cumulo-stratus would seem to be the modifi- 
 cation of cumulus , when the columns of rising vapour 
 which go to form it arrive in an upper atmosphere not 
 sufficiently dry to round off its summits by rapid 
 evaporation, allowing them to spread horizontally and 
 form flat-topped, mushroom-shaped masses, the upper 
 parts of which are often curled by the wind of an upper 
 current into cirrous wisps, or cleanly cut off by a 
 horizontal plane, forming an “ anvil-shaped cloud” with 
 a lateral projection, generally considered as a precursor 
 of wind below [and probably arising from its first 
 impression at a higher level due to the greater mobility 
 of the upper strata of the air, as less retarded by 
 friction]. The tendency of Cumulo-stratus is to spread, 
 overcast the sky, and settle down into the Nimbus , and 
 
DESCENT OF CLOUDS DURING THE NIGHT. 101 
 
 finally to fall in rain. When two strata of clouds on 
 different levels tend to unite, it is evident that the 
 intermediate region must he nearly or quite in a state 
 of hygrometric saturation. The cloud then forms con- 
 fusedly and in irregular masses through the whole region, 
 and finally resolves itself into heavy rain. 
 
 (107.) When cloud is present, the sun's rays are of 
 course prevented from reaching the earth directly, and 
 their heat is diffused through the general atmosphere — 
 thus softening and mitigating their ardour. When the 
 sun shines on a cloud, which absorbs its heat, the cloud 
 itself is necessarily partially evaporated, and the vapour 
 by its levity tends to produce an upward current, and 
 thus to counteract the effect of gravity on the globules 
 of which it consists. A globule of water l-4600ths in. 
 in diameter, in air of five-sixths of the density on the 
 surface, or at the height of about 5000 feet, would 
 have its gravity counteracted by resistance, with a 
 velocity of descent of one foot per second (supposing 
 no friction and no drag) ; and even if the terminal 
 velocity were reduced to half that quantity by these 
 causes, would still require some such upward action to 
 enable it to maintain its level — a circumstance which 
 sufficiently accounts for the lower level generally 
 observed of cloud during the night. It is more than 
 probable, however, that, when not actually raining, a 
 cloud is always in process of generation from below, and 
 dissolution from above, and that the moment this pro- 
 cess ceases, rain, in the form of “ mizzle," commences. 
 In a word, a cloud in general would seem to be merely 
 
102 
 
 METEOROLOGY. 
 
 the visible form of an aerial space in which certain pro- 
 cesses are at the moment in equilibrio, and all the par- 
 ticles in a state of upward movement. 
 
 (108.) IV. Rain . — In whatever part of a cloud the 
 original ascensional movement of the vapour ceases, the 
 elementary globules of which it consists being aban- 
 doned to the action of gravity begin to fall. By the 
 theory of the resistance of fluids, the velocity of descent 
 in air of a given density is as the square root of the 
 diameter of the globule. The larger globules, there- 
 fore, fall fastest, and if (as must happen) they overtake 
 the slower ones, they incorporate, and the diameter 
 being thereby increased, the descent grows more rapid, 
 and the encounters more frequent, till at length the 
 globule emerges from the lower surface of the cloud, at 
 the “ vapour plane,” as a drop of rain ; the size of the 
 drops depending on the thickness of the cloud stratum, 
 and its density. Bain indeed has been observed to 
 fall (at least apparently) from a cloudless sky, but the 
 occurrence is one of extreme rarity, and it seems hardly 
 possible to be certain that it has not been brought by 
 wind at a high level from very great distances. A very 
 minute rain from a clear sky is known in France by 
 the name of serein, and seems to be not uncommon. 
 
 (109.) The quantity of rain which falls on any given 
 place may be measured by the very simple contrivance 
 called a “ rain-guage,” which is an open vessel of a 
 definite aperture (suppose a square foot), and of a 
 funnel shape below, to conduct the rain fallen into a 
 graduated vessel where it can be measured to a nicety, 
 
OF RAIN. 
 
 103 
 
 a very minute superficial depth of rain being thus 
 read off on a magnified scale, even though hardly more 
 than enough to wet the surface. It is usually recorded 
 in inches of actual depth, and the wetness of a year or 
 of a season is expressed by the number of inches and 
 parts to which the earth’s surface would be covered, if 
 it could neither run off, sink into the soil, or evaporate.* 
 Some very extraordinary and unexpected facts respect- 
 ing the fall of rain have been disclosed by the use of 
 this instrument, which would appear to indicate that its 
 formation is by no means limited to the region of visible 
 cloud. At one and the same place a series of rain-guages, 
 placed at different elevations above the soil, indicate 
 very different quantities of rain, the amount being 
 greater at the lower level. Thus Dr. Heberden found 
 in twelve months, from July 7, 1766, to July 7, 1767, 
 the amount of rain at the top of Westminster Abbey 
 to be only 12*099 in., while on the top of a house close 
 by, but much inferior in altitude, it was 18*139 in., 
 and on the ground 22*608 in. Thus also Mr. Phillips 
 found the fall of rain at York for twelve months, in 
 the years 1833-34, at the height of 213 feet from the 
 ground, to be 14*963 in.; at 44 feet, 19*852 in. ; and 
 on the ground, 25*706 in. Again, at the Observatory 
 of Paris the ratio of the rain collected during the nine 
 
 * [It may be as well to notice that an inch of rain on a square 
 yard of surface expresses 46*7408 lbs. avoirdupois or 4*6741 
 gallons of water, — on an acre, 226,225*52 lbs., 22,622*55 gallons, or 
 100*9935 tons, and on a square mile, 144,784,333 lbs., 14,478,433*3 
 gallons or 64,635*86 tons. 100 tons per inch, per acre, is a rough 
 and ready memorial result. Feb. 1861.] 
 
104 
 
 METEOROLOGY. 
 
 years (1818-1826) on the terrace of the Observatory, 
 and 3 metres from the ground (or 27 metres = 88-^- feet 
 lower in level) was that of 1 : 1*116, the difference 
 being much less proportionally than in England, where 
 the ratio from Mr. Phillips’s observations is that of 
 1 : 1*719 at 213 feet, and 1 : 1*296 at 44 feet. The 
 usual account given of this phenomenon (Kamtz, i. 419) 
 is that rain falling from a high level, and therefore 
 colder than the temperature of the air at the surface of 
 the ground, arriving in an atmosphere nearly or quite 
 saturated with moisture, condenses on itself, or causes 
 the condensation, in the chilled air, of an additional 
 quantity of vapour. But it is evident that this cause, 
 though not uninfluential, is totally inadequate to 
 account for so great a difference. Admitting a given 
 weight of rain to arrive at 213 feet from the ground, 
 with the temperature of the region at which it was 
 formed unaltered, and supposing it to acquire in the 
 remaining 213 feet the full temperature of the air 
 (both of them extreme and indeed extravagant supposi- 
 tions), admitting too (though hardly less extravagant) 
 the mean height of formation of the rain to be 12,000 
 feet, it would bring down with it a cold of 40° Fahr., 
 which would condense (whether on the drops or in 
 saturated air if diffused through it) only 40-960ths, or 
 l-24th = 0*042 of its weight, = one- seventeenth of the 
 quantity to be accounted for. Still less can the effect 
 be due to a greater obliquity of fall at a higher than 
 at a lower level, since the same quantity of rain must 
 fall on the same horizontal surface after changing its 
 
RAIN-FALL AT DIFFERENT LEVELS. 
 
 105 
 
 obliquity as before. Dr. Heberden, in the spirit of 
 that meteorology which refers everything not clearly 
 understood to electricity, ascribes an electrical origin to 
 the phenomenon. The real cause is yet to seek, and 
 there is no more interesting problem which can fix the 
 attention of the meteorologist. Visible cloud rests on 
 the soil at low altitudes above the sea-level but rarely : 
 and from such cloud only, would it seem possible that 
 so large an accession of rain could arise.* 
 
 (110.) The amount of rain which falls habitually 
 per annum in any locality depends on a great variety 
 of circumstances, the most influential being its proxi- 
 mity to large bodies of heated water, such a prevalent 
 direction of wind as shall not drift the vapour away 
 
 * [These remarks were written in 1857. More recently 
 (March 29, 1860), a valuable and important paper was read by 
 Mr. Baxendell to the Lit. and Phil. Soc. of Manchester on this 
 subject. He arrives at the same conclusion as to the insufficiency 
 of the mere condensation of vapour on the falling drops to account 
 for the phenomenon in question, and concludes that it is im- 
 possible to account for it except by the admission of the exis- 
 tence of water 11 not in the state of true vapour ,” but already 
 deprived of its latent caloric — in the atmosphere — though not 
 affecting its transparency, so that “ a shallow stratum of the 
 lower and comparatively clear atmosphere,” may “supply as 
 much rain as a densely clouded and much deeper stratum in the 
 higher regions.” Mr. Baxendell hesitates to admit that the 
 water can be thus present in the actual state of water, on account of 
 its invisibility. If there be any justice in our remarks in the 
 note f on g 92, this difficulty will disappear. He adds a very 
 remarkable fact recorded by Mr. Binney, who, “in descending the 
 shafts of deep coal-mines, has observed that the drops of water 
 which drip from the upper part of the shaft increase to an extra- 
 ordinary size in their descent to the bottom.”] 
 
106 
 
 METEOROLOGY. 
 
 from it, and the absence of any lofty mountains in the 
 direction of the moist wind, to act as a harrier by 
 causing its depositions on them. As we recede from 
 the sea into the interior of great continents rain becomes 
 rare, especially if the soil he sandy. Thus in the Great 
 Sahara of Africa rain is unknown, as also in Arabia 
 and part of Persia, in the great desert of Gobi, in the 
 table-land of Thibet, &c. The greater part of the 
 enormous evaporation of the equatorial seas is at once 
 condensed and discharged again in rain from the cumuli 
 which mark its up-rush into the higher and colder 
 regions of the air, the rain being most continuous in 
 those latitudes between the tropics, over which for the 
 time the sun is vertical, or in the region of the calms. 
 In this zone the nights are for the most part clear, but 
 as the day advances the clouds thicken and pour down 
 torrents of rain, clearing again at sunset. 
 
 (111.) Eain is of unfrequent occurrence, however, 
 in the zones on either side of the calms, where the 
 trade-winds blow steadily and regularly. These winds 
 themselves, coming from higher latitudes, are acquiring 
 temperature and taking up moisture from the sea. 
 The returning counter- currents having discharged their 
 first overload of moisture, pursue their course aloft, 
 free from cloud and relatively dry ; and in the neutral 
 interval between them and the opposite lower current, 
 cloud is not generated, or rain produced, by the inter- 
 mixture of the two — the upper portions of the trades 
 not being saturated, for the reason just adduced. The 
 clouds which do occur in these winds belong not to 
 
TROPICAL AND EXTRA-TROPICAL RAINS. 107 
 
 their higher strata but to a much inferior level, not 
 exceeding five or six thousand feet in altitude, while 
 the medial line between the winds has nearly double 
 that elevation. Such at least are the phenomena on 
 Teneriffe, as exhibited during the late residence of Mr. 
 C. P. Smyth on the summit of that mountain for a 
 fortnight in the month of August, during the whole 
 of which time the sea horizon was never once visible, 
 a stratum of these low clouds lying uninterrupted in 
 every direction, the upper half of the peak being free 
 from cloud, and its summit , at 12,500 feet, just sur- 
 passing the medial line, and coming within the upper 
 or S.W. current. 
 
 (112.) Between the tropics there is, properly speak- 
 ing, no winter or summer. The year is divided into a 
 dry and wet season — the dry, when the sun is in the 
 opposite hemisphere, and the trade wind blows strong ; 
 the wet, when in the same, and approaching the zenith. 
 In the neighbourhood of the equator, where the sun 
 passes the zenith twice at several months’ interval, there 
 are two dry and two wet seasons, or rather two unequal 
 maxima and minima of rain. Where monsoons prevail, 
 however, the law of rain is different. Thus, on the 
 eastern coast of the peninsula of India, the rains occur 
 during the north-east monsoon, and on the western 
 during the south-east or trade. 
 
 (113.) Beyond the tropics, where the anti-trade or 
 returning current descends to the level of the earth’s 
 surface, and by degrees takes up the temperature of our 
 milder latitudes, its vapour, held so far in abeyance, 
 
108 
 
 METEOROLOGY. 
 
 becomes available for the production of rain, unless 
 intercepted, as above indicated, by some lofty mountain 
 barrier tossing up the stream and prematurely precipi- 
 tating its vapour. Where this obstacle does not exist, 
 however, the rains are distributed in the extra-tropical 
 regions with considerable indifference as to season; in 
 some, indeed, a certain approach to a wet and dry 
 division of the year prevails, as, for instance, along the 
 coast of Portugal, as well as in Italy and the south of 
 France, where scarcely any rain falls in summer, while 
 at Pekin the contrary rule prevails. Since, however, 
 the deposit of water from the air, as it travels, must of 
 necessity bear some rude proportion to the actual quan- 
 tity in transitu , the amount of rain or snow which falls 
 on any country must, on a general average, diminish 
 as the latitude increases, a conclusion confirmed by 
 observation. 
 
 (114.) The west coasts of England and Ireland form 
 a rather remarkable exception to this law. They receive 
 with the west and south-west winds which generally 
 prevail, the vapour of the Gulf Stream. In consequence 
 the annual fall of rain is not only much greater than on 
 the eastern and southern coasts, but in one district, that 
 of the Lakes of Cumberland, is quite enormous. The 
 annual fall at Seathwaite, in Borrowdale (Lake district) 
 amounted, according to the careful observations of Mr. 
 Miller, to no less than 141*54 inches on an average of 
 three years ; while that in London is only 23J. To 
 bring this result into comparison with what obtains 
 elsewhere, we subjoin a table (see page 110) of the 
 
REMARKABLE RAIN-FALLS. 
 
 109 
 
 mean annual amount of rain in some of the more 
 remarkable localities. 
 
 (115.) Rain, except in the tropical regions, is perhaps 
 the most irregular of all meteorological phenomena, both 
 in respect of the frequency of its occurrence and in the 
 quantity which falls in a given time. The quantities 
 recorded are, in some instances, truly astonishing. It 
 is considered, in the greater part of England, a heavy 
 rain if an inch fall in the course of twenty-four hours ; 
 yet at Seath waite, above mentioned, 6*62 inches are 
 recorded by Mr. Miller to have fallen on November 
 27, 1845, in that time. At Joyeuse (Ardeche), in 
 France, 31T73 inches fell in twenty- two hours; at 
 Genoa, 30 inches in twenty-four hours; at Gibraltar, 
 33 inches in twenty-six hours. “ On the mountain 
 tops overhanging Bombay, 24 inches of rain have been 
 recorded in a single night.” — {Perry, Bird’s Eye View 
 of India , p. 17). These are, however, only sudden, 
 unsustained falls. But in tropical regions we have 
 instances of what may almost be called deluges. Hum- 
 boldt collected, at Rio Negro, in the rainy season in 
 May, as an ordinary rain , If- inch in five hours. 
 Admiral Roussin found, for the amount of rain at 
 Cayenne, between the 1st and 24th February 1820, no 
 less than 12 feet 6*96 inches, and on one night, between 
 8 p. m. and 9 a.m., he collected 10^ inches. At Cherra 
 Ponjee, in the Khasyah mountains, east of Calcutta, 
 nearly 600 inches per annum are stated to have fallen. 
 [Even in England great and persevering rainfalls occa- 
 sionally occur in the rainy district of Westmoreland 
 
110 
 
 METEOROLOGY. 
 
 Thus in January 1851, 38*86 inches are recorded by 
 Mr. Miller (Tr. E. S/Edin. xxi), to have fallen at “The 
 Stye,” or “the Shoulder of Sprinkling Eell” in Wast- 
 dale, 1600 feet above the sea level.] 
 
 Mean Annual Amount of Eain in Various Places. 
 
 Place. 
 
 Latitude. 
 
 Rain 
 
 per Annum. 
 
 Singapore 
 
 + 1° 16' 
 
 Inches. 
 
 97.0 
 
 Kandy 
 
 + 7 20 
 
 52.1 
 
 Trevandrum 
 
 + 8 28 
 
 64.5 
 
 Sierra Leone 
 
 + 8 29 
 
 86.2 
 
 Uttray Mullay .... 
 
 + 8 39 
 
 267.2 
 
 Cape Comorin .... 
 
 + 8 59 
 
 28.4 
 
 Allepy 
 
 + 9 27 
 
 113.3 
 
 Cochin 
 
 + 9 58 
 
 106.1 
 
 Dodabetta 
 
 +11 23 
 
 101.3 
 
 Grenada 
 
 +12 7 
 
 112.0 
 
 Seringapatam . . 
 
 +12 26 
 
 23.7 
 
 Madras 
 
 +13 4 
 
 44.6 
 
 St Helena (very irregular) . 
 
 -15 57 
 
 45.2 
 
 Eangoon 
 
 +16 47 
 
 84.0 
 
 Mahabalishwar .... 
 
 +18 ... 
 
 254.1 
 
 St. Domingo 
 
 +18 29 
 
 107.6 
 
 Poonah 
 
 +18 30 
 
 25.4 
 
 Bombay 
 
 +18 53 
 
 75.2 
 
 Calcutta 
 
 +22 35 
 
 76,4 
 
 Cherra Ponjee 
 
 
 
 592.0 
 
 Eio Janeiro ..... 
 
 -22 54 
 
 . 59.2 
 
 Havannah 
 
 +23 9 
 
 91.2 
 
 Charleston 
 
 +32 46 
 
 54.0 
 
MEAN ANNUAL RAIN-FALLS. 
 
 Ill 
 
 Place. 
 
 Latitude. 
 
 Rain 
 
 per Annum. 
 
 Madeira 
 
 +33° 30' 
 
 Inches. 
 
 27.7 
 
 Cape of Good Hope . . . 
 
 -33 56 
 
 ... 
 
 Williamsburg 
 
 +37 13 
 
 47.0 
 
 Palermo 
 
 +38 8 
 
 22.3 
 
 Lisbon 
 
 +38 42 
 
 27.1 
 
 Washington , U. S. . 
 
 +38 54 
 
 41.2 
 
 Mafra 
 
 +38 55 
 
 44.0 
 
 Pekin 
 
 +39 54 
 
 26.8 
 
 Philadelphia (Girard Coll.) 
 
 +39 56 
 
 37.2 
 
 Cambridge, U. S. ... 
 
 +40 5 
 
 38.9 
 
 Coimbra 
 
 +40 12 
 
 118.8 
 
 Bacon 
 
 +40 22 
 
 15.2 
 
 Tiflis 
 
 +41 40 
 
 19.9 
 
 Rome 
 
 +41 54 
 
 31.0 
 
 Odd years observed ) 
 
 Hobart Town . . . . > 
 
 -42 52 
 
 ( 13.42 
 
 ] 18.4 
 
 Even years observed j 
 
 Toulon 
 
 +43 9 
 
 (23.34 
 
 18.2 
 
 Marseilles 
 
 +43 17 
 
 23.4 
 
 Siena 
 
 +43 22 
 
 34.2 
 
 Toulouse 
 
 +43 36 
 
 25.2 
 
 Toronto 
 
 + 43 40 
 
 39.7 
 
 Arles 
 
 +43 42 
 
 23.8 
 
 Florence 
 
 +43 46 
 
 41.3 
 
 Orange 
 
 +44 7 
 
 30.3 
 
 Genoa 
 
 +44 24 
 
 47.3 
 
 Bologna 
 
 +44 29 
 
 31.0 
 
 Bordeaux 
 
 +44 50 
 
 25.8 
 
 Rovigo 
 
 +45 4 
 
 32.9 
 
 Turin 
 
 +45 5 
 
 26.6 
 
 Padua 
 
 +45 25 
 
 36.9 
 
112 
 
 METEOEOLOGY. 
 
 Place. 
 
 Latitude. 
 
 Rain 
 
 per Annum. 
 
 Yerona 
 
 +45° 27' 
 
 Inches. 
 
 36.9 
 
 Vicenza 
 
 +45 32 
 
 43.8 
 
 St. Bernard 
 
 +45 50 
 
 58.5 
 
 La Bochelle . . 
 
 +46 9 
 
 24.5 
 
 Geneva ....... 
 
 +46 13 
 
 31.7 
 
 Milan 
 
 +46 28 
 
 37.8 
 
 Lausanne 
 
 +46 30 
 
 40.2 
 
 Poictiers 
 
 • +46 35 
 
 23.6 
 
 Montpellier 
 
 +46 36 
 
 32.4 
 
 Berne 
 
 +46 55 
 
 46.1 
 
 Zurich 
 
 +47 21 
 
 34.3 
 
 Troyes 
 
 +48 18 
 
 23.9 
 
 Augshurg 
 
 +48 21 
 
 39.1 
 
 Ulm 
 
 +48 25 
 
 26.8 
 
 Tubingen 
 
 +48 31 
 
 25.5 
 
 Lougan 
 
 +48 35 
 
 13.6 
 
 Stuttgard 
 
 +48 36 
 
 25.3 
 
 Paris 
 
 +48 50 
 
 22.2 
 
 Carlsruhe 
 
 +49 0 
 
 26.4 
 
 Metz 
 
 +49 5 
 
 29.0 
 
 Manheim 
 
 +49 30 
 
 22.4 
 
 Msmes 
 
 +50 3 
 
 25.3 
 
 Prague 
 
 +50 5 
 
 14.1 
 
 Cracow 
 
 +50 6 
 
 13.3 
 
 Penzance 
 
 +50 8 
 
 37.2 
 
 Gosport 
 
 +50 48 
 
 29.7 
 
 Brussels 
 
 +50 17 
 
 28.6 
 
 Nertschinsk . . . . . 
 
 +51 18 
 
 16.0 
 
 Coblentz 
 
 +51 22 
 
 22.2 
 
 Bristol 
 
 +51 27 
 
 23.3 
 
 Gottingen . . .... 
 
 +51 30 
 
 26.6 
 
MEAN RAINFALL IN VARIOUS PLACES. 
 
 113 
 
 Place. 
 
 Latitude. 
 
 Rain 
 
 per Annum. 
 
 Middleburg 
 
 +51° 30' 
 
 Inches. 
 
 27.1 
 
 London (Greenwich) . . . 
 
 +51 31 
 
 24.4 
 
 Breda 
 
 +51 32 
 
 26.3 
 
 Botterdam . . 
 
 +51 55 
 
 22.7 
 
 Oxford 
 
 +51 55 
 
 26.5 
 
 Strasburg 
 
 +52 10 
 
 27.3 
 
 Lyndon 
 
 +52 42 
 
 18.3 
 
 Nottingham 
 
 +53 10 
 
 26.4 
 
 Franeker 
 
 +53 11 
 
 30.5 
 
 Barnaoul 
 
 +53 20 
 
 10.5 
 
 Dublin 
 
 +53 23 
 
 29.1 
 
 Liverpool 
 
 +53 24 
 
 34.5 
 
 Manchester 
 
 +23 29 
 
 36.2 
 
 Lancaster 
 
 +54 3 
 
 39.7 
 
 Isle of Man ..... 
 
 +54 15 
 
 37.1 
 
 Kendal 
 
 +54 19 
 
 53.7 
 
 Seathwaite 
 
 +54 ... 
 
 141.5 
 
 Gorki 
 
 +54 45 
 
 18.2 
 
 Dumfries 
 
 +55 4 
 
 36.9 
 
 Catherineburg 
 
 +55 11 
 
 15.6 
 
 Zlatoouste 
 
 +55 11 
 
 17.7 
 
 Copenhagen 
 
 +55 40 
 
 18.5 
 
 Glasgow 
 
 +55 52 
 
 21.3 
 
 Edinburgh 
 
 +55 57 
 
 24.9 
 
 Kinfauns 
 
 +56 20 
 
 24.7 
 
 Sitka 
 
 +57 34 
 
 87.9 
 
 Stockholm 
 
 +59 20 
 
 20.4 
 
 Bogoslovsk 
 
 +59 45 
 
 17.2 j 
 
 Upsala . 
 
 +59 48 
 
 17.8 
 
 Petersburg 
 
 +59 56 
 
 17.3 
 
 Bergen 
 
 +60 24 
 
 88.6 
 
 T 
 
114 
 
 METEOROLOGY. 
 
 (116.) V. Hail . — In a balloon ascent performed by 
 Messrs. Green, Rush, and Spencer, on September 4, 
 1838, after mounting to an altitude of 19,185 feet, 
 during which ascent the thermometer, at 12,000 feet, 
 marked 46° Fahrenheit, they found, on descending 
 again to the last-mentioned level, a temperature of 22° 
 Fahrenheit only, or 24° colder than in their ascent. 
 At the same time, they found there a heavy fall of snow 
 in progress. It is evident that this arose from the 
 condensation of vapour at that level, and that, from the 
 intrusion of some current, a mass of intensely cold air 
 had been introduced, which, finding vapour near satu- 
 ration, converted it into snow. It is equally evident 
 that, had the latter condition prevailed not at the level 
 in question, but at a somewhat higher, where the con- 
 densation might have been into rain very near the 
 freezing point, the drops, in descending, would have 
 been frozen solid and fallen as hail . It might have 
 been so equally, had the precipitation been so copious 
 as to allow the coalescence of a great number of 
 minute particles in a nascent state into drops frozen 
 together instanter, since there is good reason to believe 
 that the solid form is never assumed without transition 
 through the liquid, however momentary. 
 
 (117.) The generation of hail seems always to depend 
 on some such very sudden introduction of an extremely 
 cold current of air into the bosom of a quiescent, nearly 
 saturated mass. Hailstorms are always purely local 
 phenomena, and never last long. They often mark 
 their course by linear tracks of devastation, of great 
 
OF HAIL. 
 
 115 
 
 length and very small breadth. In the hailstorm of 
 July 13, 1788, which passed across France from south 
 to north, two such tracks were marked, of 175 and 200 
 leagues in length respectively, parallel to each other, 
 the one four leagues broad, the other two, and separated 
 by a tract five leagues in breadth, in which only rain 
 fell. A similar character is very common, though not 
 to such an extent. Such linear hailstorms are always 
 attended with violent wind, sudden depression of the 
 barometer, indicating a great commotion in the air, and 
 probable mingling of saturated masses of very different 
 temperature. To attribute to hail, as is often done, an 
 electrical origin, because hail is often accompanied with 
 thunder and lightning (“ hailstones and coals of fire”), 
 seems to us to be putting the effect for the cause. 
 
 (118.) Hail may be very properly distinguished into 
 single hailstones and aggregated masses. Single stones 
 have generally a crystalline structure, radiating from a 
 centre if large, forming spherical, oval, or rounded 
 masses, often marked out (on making a section) into 
 concentric layers, like the rings in the section of a 
 branch. They fall from the size of small peas to that 
 of an egg, an orange, or a man’s head, ^and weighing 
 from a few grains up to fourteen pounds and upwards. 
 Dr. Thomson, in his Introduction to Meteorology , a 
 work in which the reader will find assembled a most 
 extraordinary collection of the recorded marvels of 
 meteorology, gives many instances of the fall of large 
 hail-stones. One, described by Captain Delcrosse, as 
 having fallen at Baconniere, July 4, 1819, fifteen inches 
 
116 
 
 METEOROLOGY. 
 
 in circumference, had a beautiful radiated structure (fig. 
 6), marking it as a single stone, formed in passing through 
 two distinct regions of condensation. Dr. Buist stated 
 to the Bombay Geographical Society, that in India the 
 hail-stones are from five to twenty times larger than 
 
 those in England, often weighing from six ounces to a 
 pound, seldom less than walnuts, often that of oranges ! 
 These storms are almost always accompanied by violent 
 wind and rain, thunder and lightning, and are frequent 
 in the delta of the Ganges, especially in the low country 
 within fifty miles of the Bay of Bengal. 
 
 (119.) Great hailstorms are often preceded by a 
 loud clattering and clashing sound, indicating the hurt- 
 ling together of masses of ice in the air. The recent 
 
OF HAIL. 
 
 117 
 
 experiments of Professor Tyndall on the reuniting of 
 broken ice by “ regelation,” or a sort of welding, fully 
 explains the formation, under such circumstances, of 
 large masses of ice of irregular forms in this aerial 
 conflict. Such are recorded to have fallen of almost 
 fabulous magnitude. In Candeish, in 1826, in a hail- 
 storm which perforated the roofs of houses like small 
 cannon shot, a mass fell which took some days to melt, 
 and must have weighed more than a hundred- weight. 
 — ( Malet .) On May 8, 1832, a mass fell in Hungary a 
 yard in length and nearly two feet in thickness. — 
 {Thomson.) And if it be true, as stated in the Boss- 
 shire Advertiser in 1849, that a block “of irregular 
 shape, nearly twenty feet in circumference,” fell in 
 August of that year on the estate of Mr. Moffat of Ord, 
 immediately after an extraordinarily loud peal of 
 thunder, Heyne’s relation of a hail-stone as large as an 
 elephant, at Seringapatam, in the reign of Tippoo 
 Sultan, may perhaps find believers. The Eoss-shire 
 mass is stated to have been composed of lozenge- shaped 
 pieces, one to three inches in size, firmly congealed 
 together. 
 
 (120.) VI. Snow . — When time is allowed, and the 
 process of precipitation and congelation takes place in 
 a less tumultuous manner, so as to allow the deposited 
 particles to accrete according to regular arrangements, 
 small spiculse form, crossing one another at angles of 
 60°, the primitive crystal of ice being a rhomboid of 
 60° and 120°, producing as one of its secondary forms 
 the regular hexagonal prism, having (as all such crystals) 
 
118 
 
 METEOROLOGY. 
 
 one axis of double refraction parallel to the axis, as is 
 easily seen in a sheet of ice formed in still water on 
 exposure to polarized light. When deposited as hoar- 
 frost in the condensation of dew, the crystallization is 
 confused by contact with and adhesion to the radiant 
 body, but when supported only by air and receiving 
 accretion on all sides, a high degree of regularity is 
 attained, and the most perfect and symmetrical six- 
 rayed star-like forms arise, of which (drawn from actual 
 observation of the falling spangles, in very cold 
 weather) Dr. Scoresby has given several figures, and 
 Mr. Lowe and Mr. Glaisher have more recently 
 published series of engravings. The variety of forms 
 affected by these delicate mechanisms is infinite ; 
 the beauty of their patterns incomparable. By Mr. 
 Glaisher’ s permission we have transferred a few of his 
 figures to our pages (PI. XIX., figs. 2-15). Mr. Lowe 
 has been fortunate enough to observe them in the act 
 of forming, and to witness the whole process of con- 
 struction of some of their most elegant and complex 
 varieties. 
 
 (121.) It can hardly be doubted that clouds at great 
 elevations consist of frozen particles. The phenomena 
 of parhelia and some species of halos are explicable 
 only by the refraction and reflection of light in prisms, 
 with angles of 120° and 60°, as M. Bravais has shewn 
 (following up the theoretical views of Mariotte and 
 Young) by a neat and elegant mechanism. Now these 
 are the angles of the primitive -rhomboid actually 
 measured by Dr. Clark. In such clouds, at all events, 
 
OF SNOW. 
 
 119 
 
 vesicles cannot exist, and in the gradual melting of 
 the snow spangles, the laws of capillary attraction, by 
 filling up all re-entering corners, would effectually 
 preclude the inclusion of the smallest air -bubble, 
 though a compound snow-flake hurriedly melted might 
 now and then entangle one. 
 
 (122.) Fallen snow of even a very moderate depth, 
 is a powerful agent in mitigating the extreme effects of 
 frost on the soil. Owing to its loose texture and its 
 inclusion of eight or ten times its bulk of air, it is a 
 very bad conductor; and although its upper surface 
 may be cooled by radiation or otherwise to a very low 
 point, its interposition cuts off the communication 
 between the chilled surface and the soil beneath it. 
 The farmer looks to a fall of snow as his best security 
 for the preservation of his autumn-sown and sprouting 
 crops through the winter. 
 
 (123.) Level of Perpetual Snow . — Since by ascend- 
 ing into the atmosphere a temperature inferior to 
 congelation is everywhere met with, it is evident that 
 a mountain of some certain elevation will have the 
 mean temperature of its summit at or below the freezing 
 point ; and although it does not follow that where the 
 mean temperature is precisely 32°, snow will necessarily 
 be found all the year round (since this will depend on 
 the greater or less accumulation of it in the cold seasons, 
 and on the greater or less evaporation in the warmer 
 ones), yet, somewhere about this limit, and at all events 
 at no great elevation above it, we must expect to 
 encounter the phenomenon of perpetual snow. If we 
 
120 
 
 METEOROLOGY. 
 
 take 1° Fahr. for the average depression of the ther- 
 mometer for 100 yards of increased altitude in mountain 
 ascents, as a rough approximation, and assume 84° for 
 the mean equatorial temperature, this would give (84 
 — 32) x 300 ft. = 15,600 ft. for the height above the 
 sea level, at which, under favourable circumstances, the 
 perpetual snow line may occur under the equator; 
 we say under favourable circumstances, for it is evident 
 that if the mean temperature of the year be Sver so 
 little above the freezing point, we cannot expect snow 
 to lie all the year round, especially on the summit of a 
 mountain where all the water produced by melting 
 immediately runs off, and therefore ceases from that 
 moment to act as a reservoir of cold. Now the mean 
 of Humboldt’s determinations of this element for the 
 mountains of equatorial America from 4°. 4 6 N. lat. to 
 1°.30 S. ( Asie Centrale, p. 461, tab.) gives 4774 metres 
 = 15,670 feet. 
 
 (124.) This, however, must be considered as a mini- 
 mum reckoning. In the celebrated work just cited,'- 
 Baron Humboldt has given a table of the most authentic 
 determinations of the snow-level for 34 mountains 
 trigonometrically measured from 71° 1ST. lat. to 54° S t 
 Of these the mean annual temperatures at the sea-lever 
 are correspondingly stated for 18 stations — calculating 
 on which it would appear that about 2100 feet on -an 
 average ought to be added to the height calculated on 
 the decrement of temperature assumed in the last 
 article, to give that of the snow line. 
 
 (125.) In fact, however, no general rule or principle 
 
LEVEL OF PERPETUAL SNOW. 
 
 121 
 
 of calculation can be laid down, and though attempts 
 are not wanting to construct formulae which shall 
 afford a close approximation to the height in any 
 geographical position, it is impossible to place any 
 reliance on them. This will be the more evident when 
 we come to consider the causes which must of neces- 
 sity influence the result. Of these the principal are — 
 1st, The situation of the slope on which the snow lies 
 on the mountain chain, with respect to the incidence 
 of the sun’s rays. Thus, on the southern declivity of 
 the Maladetta in the Pyrenees, the level in question is 
 nearly 1200 feet higher than on the northern ; 2d, and 
 more especially its situation with respect to the 
 direction of the wind, which brings the chief supply of 
 moisture to be deposited in snow, and which will 
 naturally be heaped on that side of the mountain which 
 acts as an obstacle to its progress. To these causes 
 must be added, 3dly, the greater or less steepness of the 
 slope ; and above all, 4thly, the greater or less degree 
 of habitual dryness of the region in which the mountain 
 is situated, by which the snow itself is evaporated and 
 carried off. So great is the influence of these causes, 
 that in the Himalayas, where some of the mountain 
 peaks attain' the enormous altitude of 28,000 feet, the 
 snow line on the southern side of the great chain occurs 
 .at 13,000 feet, and on the northern at 16,600, or even 
 (according to Mr. Lond) 18,300, the moist winds of the 
 S.W. monsoon depositing their snow almost wholly on 
 the southern side, while the northern is exposed to the 
 evaporation of one of the driest regions of the globe. 
 
122 
 
 METEOROLOGY. 
 
 On the other hand, on the eastern slope of the Cor- 
 dillera, in Chili, the snow-level occurs at 15,900, while 
 on the western it rises to 18,500 (Humboldt’s Asie 
 Centrale, iii. 360), the difference again being attri- 
 butable to the direction of the wind (the S.E. trade), to 
 which the chain of the Andes forms a harrier, and of 
 which, to a certain extent, it diverts the course, and 
 the excessive aridity of the region between the chain 
 and the Pacific, in which rain is a thing almost unknown. 
 Apart from the illustration it affords of the distribution 
 of temperature in different strata of the atmosphere, 
 the subjects of the level of perpetual snow, the inferior 
 prolongation into glaciers, and. the occasional instances 
 where ice occurs in caves far below the snow line, pre- 
 served throughout the summer (or even in open pits, 
 as in the quarries of the Medermennig on the Rhine), 
 belong rather to physical geography than to meteorology 
 proper. 
 
 Atmospheric Electricity, Lightning, Thunder, etc. 
 
 (126.) The community of nature between lightning 
 and electricity was suspected from the very earliest dis- 
 covery of the electric spark, by Wall, in 1708, but it 
 was not till 1752 that Eranklin suggested the idea of 
 obtaining evidences of their identity by erecting pointed 
 metallic conductors properly insulated. The experiment 
 was tried in France with success, but Franklin, tired of 
 waiting for the erection of a pointed rod on a spire in 
 Philadelphia, had the happy idea of flying a kite and 
 exploring the string for electricity. The experiment 
 
ATMOSPHERIC ELECTRICITY. 
 
 123 
 
 succeeded, meriting by its success that sublime image 
 which forms the inscription on one of his medals, 
 
 “ Eripuit fulmen ccelo, sceptrumque tyrannis.” 
 
 Franklin's kite was flown with ordinary pack-thread, 
 held by a few feet of silk line, and the electric effects 
 obtained by him were feeble, though sparks were pro- 
 duced. Eut Eomas, using in place of a string, a fine 
 wire, obtained, during a thunderstorm (1757), flashes 
 of fire nine or ten feet in length, thirty of which suc- 
 ceeded each other in an hour, besides innumerable 
 flashes of seven feet, which, by means of a conductor, 
 insulated by a glass handle, he was enabled to direct at 
 pleasure — not altogether with impunity, being struck 
 down on one occasion ; though the terrible catastrophe 
 of July 26, 1753 (when Professor Bichmann of Peters- 
 burg was killed on the spot while explaining to a 
 companion the construction and movements of an 
 electrometer attached to his conductor) might have 
 warned him of the dangers attending such experiments. 
 
 (127.) Ey means of a wire 370 feet long, attached 
 by a silk cord to the top' of a steeple at Maintenon, the 
 Abb6 Mazeas, in 1753, ascertained tfiat the presence of 
 a thunder-cloud is not an essential condition for the 
 manifestation of atmospheric electricity, but that in 
 clear, dry, and especially hot weather, electric effects 
 are produced at all hours between sunrise and sunset. 
 He even noticed a certain regularity of diurnal increase 
 and decrease. From that time the exploration of 
 atmospheric electricity has formed a part of meteoro- 
 
124 
 
 METEOROLOGY. 
 
 logical inquiry. It is performed by erecting in a clear 
 exposure, at a considerable height, a pole, carrying at 
 the top an insulated and pointed metallic rod, connected 
 with an insulated wire to convey the electricity into a 
 fitting place for examination. There it communicates 
 with an electrometer, a Leyden jar, a condenser, or an 
 apparatus for measuring the length of the spark (if 
 any), by which the kind of electricity (vitreous or 
 resinous) may be tested, and its intensity measured 
 and registered. When violent, a bell is made to ring 
 by the alternate attraction and repulsion of a metal 
 ball, suspended by a silk thread. The best collector of 
 electricity, which is often used when a rod like a fishing- 
 rod, with an insulating handle, is thrust out from an 
 upper window, is a bit of amadou, held in a metallic 
 forceps, the smouldering smoke of which being an 
 excellent conductor, as it were searches the air into 
 which it ascends, and conveys its electricity down to 
 the wire attached. A sponge moistened with alcohol, 
 and set on fire, is also an excellent collector. 
 
 (128.) Read, to whom we owe a very elaborate 
 series of researches, continued almost hourly, without 
 intermission (except for sleep), for two years (1791-2). 
 Coulomb, Cavallo, Saussure, Schubler, Colladon, and 
 others, have shewn that the normal character of aerial 
 electricity is positive or vitreous. Of 987 trials, Read 
 found that 664 gave positive indications ; but as his 
 method of observation improved, he found that the 
 ratio of positive cases increased ; and, moreover, that a 
 great number of the negative were only apparent, aris- 
 
ATMOSPHERIC ELECTRICITY. 
 
 125 
 
 ing from induction, the top and bottom of his rod 
 giving contrary indications. Out of 1 0,500 observations 
 made at the Kew Observatory in 1845-47, 10,176 
 shewed positive, and only 364 negative electricity — 
 the latter being almost always accompanied with heavy 
 rain. 
 
 (129.) Not only is the normal electricity of the 
 atmosphere positive at all seasons, hours of the day, 
 and places, hut the intensity of its manifestation is 
 invariably greater the higher in it a conductor is raised. 
 This would appear to be the case even in the very 
 highest regions. Thus in Gay Lussac’s ascent, a wire 
 150 feet long, hung from the car of the balloon, mani- 
 fested a negative state of induced electric tension at its 
 upper extremity (where only it could be tested), thus 
 indicating a higher state of positive electricity in the 
 highest strata ; or, in other words, the usual condition 
 of electric observation on the ground being reversed, 
 and the state of the lower strata being explored by the 
 wire, it was found to he relatively negative. Hence it 
 manifestly follows that, relatively to the air, the earth’s 
 surface is habitually negative — the positive electricity 
 being repelled inwards, and the negative drawn to the 
 surface. As moisture is withdrawn from the lower 
 strata of the air, by deposition in dew when evaporation 
 ceases ; so electricity, when not in the act of being sup- 
 plied from below (as presently to be shewn), is per- 
 petually, though slowly, drawn off by conduction. 
 
 (130.) Tog is, for the most part, strongly electric, 
 and invariably positive, even during the deposition of 
 
126 
 
 METEOROLOGY, 
 
 dew. Bead found the vapour near the ground, in the 
 act of condensing into dew, always highly electric. 
 The importance of this remark will presently appear. 
 
 (131). From the observations of Saussure, Arago, 
 Schubler, and others, it appears that the electric tension 
 of the atmosphere is subject to a diurnal periodicity 
 with a double maximum and minimum. The maxima 
 occur about 10 a.m. and 10 p.m., and the minima from 
 noon to 4 p.m., according to the season (summer or 
 whiter), and a little before sunrise. The nocturnal 
 minimum is much more strongly marked than the 
 diurnal. The electric tension is also stronger in winter 
 than in summer. On the open sea, except during 
 storms, there is but little indication of atmospheric 
 electricity, but the masts and rigging of ships interfere 
 greatly with the requisite arrangements for observing it. 
 
 (132.) The origin of aerial electricity has been traced 
 with every appearance of probability to evaporation. 
 Saussure and Beccaria proved by many experiments 
 that the rapid evaporation of water from heated bodies 
 gives rise to a separation of the vitreous and resinous 
 electricities, the one being carried off by the vapour, 
 the other remaining in the residue or being conducted 
 away by its support, but nothing uniform or con- 
 sistent either as to the positive or negative cha- 
 racter of the electricity thus conveyed into the air, or 
 its amount under given circumstances was obtained, 
 until the subject engaged the attention of M. Fouillet, 
 who, in a remarkable memoir read to the Academy of 
 Sciences in 1825, announced the following results: — 
 
ATMOSPHERIC ELECTRICITY. 
 
 127 
 
 ls£, Simple change of state from the solid or liquid to 
 the vaporous form of any body, is unaccompanied by 
 any electrical excitement. The evaporation of pure 
 water or of any substance not decomposed, or at least 
 partly decomposed in the act, produces none whatever. 
 2d, When evaporation is accompanied with chemical 
 change, electricity is developed. Water evaporated 
 from alkaline solutions carries off resinous and leaves 
 behind vitreous electricity. The reverse happens when 
 it evaporates from an acid, or from neutro-saline solu- 
 tions, including that of sea salt, or from heated iron 
 which it oxidizes. 3d, The processes of vegetation in 
 which water is abundantly separated from the other 
 constituents of plants, and perhaps also their disen- 
 gagement of oxygen under the influence of light, or 
 carbonic acid under contrary circumstances, are also 
 sources of electricity. 
 
 (133.) Thus we are led to look to the immense 
 evaporation both from sea and land, and to the vital 
 processes going on in the latter, as furnishing at least 
 the chief supply of electricity to the air. Volcanic 
 eruptions and conflagrations contribute their quota. 
 Thus in the great eruption of Vesuvius in 1794, 
 described by Sir William Hamilton, the dense cloud of 
 mixed vapour, smoke, and ashes, which overhung the 
 mountain, was overcharged with lightning, which 
 darted around in continual flashes (ferllie ) upon Somma 
 and the slopes of the crater. Wind, too, by its fric- 
 tion, or by that of the dust, &c., which it carries with 
 it, may also contribute somewhat to the general stock. 
 
128 
 
 METEOROLOGY. 
 
 (134.) In what state free electricity exists in gaseous 
 matter is at present a mystery. The simplest concep- 
 tion we can form, is that of its investing the ultimate 
 molecules of vapour as an electric coating of infinitesi- 
 mal tension, far too feeble to discharge itself from one 
 to the other, and so to escape by what is called “ con- 
 dudion through a moist atmosphere” If this be 
 granted, we can conceive the co-existence at a distance 
 from each other of masses of air oppositely electrified, 
 and capable of giving out a portion of their contents 
 by contad discharge, to a rod, wire, flame, &c., and 
 thus explain the collection of electricity by these 
 means from the air, and its diversity of character as to 
 plus and minus . 
 
 (135.) But whatever may be the state of the ultimate 
 molecules of vapour, it seems impossible but that when 
 a great multitude of them lose their vaporous state by 
 cold, and coalesce into a drop or snow-spangle, however 
 minute, that drop will have collected and retained on 
 its surface (according to the laws of electric equilibrium), 
 the whole electricity of its constituent molecules, which 
 will therefore have some finite, though very feeble 
 tension. Now, suppose any number (1000 for instance) 
 of such globules to coalesce, or that by successive 
 deposition one should gradually grow to 1000 times its 
 original volume. The diameter will be only 10, and 
 the surface 100 times increased. But the electric con- 
 tents being the sum of those of the elementary globules, 
 will be increased one thousandfold, and being spread 
 entirely over the surface, will have a tenfold density 
 
ATMOSPHERIC ELECTRICITY. 
 
 129 
 
 ( i.e . tension). This simple view of the subject, put 
 forward in the most distinct form, at the very , origin of 
 the discussion of the nature of lightning by Eeles (Phil. 
 Tr. 1752, p. 527), needs only to be carried a very little 
 farther than the then state of electric knowledge 
 enabled its author to do, to render a complete explana- 
 tion of all the ordinary electric phenomena. And, 
 first : the comparatively high electric state of fog (and 
 cloud is nothing else), is an obvious consequence of it. 
 Every minute globule of water, of which fog consists, 
 carries about with it an electric coating, which it is 
 ready to part with by contact discharge to the surface 
 of any conductor, and the denser the fog, and the 
 larger its globules, the greater the amount of electricity 
 given out. Again, the electricity of the superficial air 
 occasioned by the deposition of dew, is in perfect 
 accordance with this view, and is a corollary from the 
 general proposition too obvious to need insisting on. 
 Again, as regards the diurnal fluctuation, when the air 
 is exhausted of its vapour by night deposition in dew, 
 and by upward diffusion without a new supply, the 
 electricity is at its minimum. It increases as new 
 vapour rises under the influence of the ascending sun, 
 decreases again (though not much) as the increasing 
 warmth of the air renders it more capable of holding 
 the still larger amount of vapour uncondensed, and as 
 the vapour itself rises rapidly to form cloud, increases 
 again as night comes on, dew begins to form at sunset, 
 and vapour to settle into globules by atmospheric radia- 
 tion, and once more decreases as the quantity of these 
 
 K 
 
130 
 
 METEOROLOGY. 
 
 electrified globules diminishes by deposition and diffu- 
 sion. There is no doubt a certain amount of slow con- 
 duction back into the soil, the intimate nature of which 
 it is very difficult to conceive rightly, but of which the 
 phenomena of electricity of weak tension furnish abun- 
 dant examples, by which a considerable portion of the 
 electricity near the surface is returned to the earth, and 
 which is more effective, the more “ relatively moist ” is 
 the air, and by which the march of the diurnal fluctua- 
 tion, and its epochs of maxima and minima, are 
 materially influenced. 
 
 (136.) When condensation of vapour takes place 
 aloft, as when a cloud is formed, the tension on the 
 surface of its globules may increase by the process 
 explained, till a portion of the electricity is enabled to 
 work its way to the surface of the cloud, regarded as a 
 conductor, though a bad one, by the general law of 
 electric equilibrium, which tends to throw out the fluid 
 to the surface, and universally, no doubt, the exterior 
 of a cloud is in a higher state of tension than the 
 interior, and its under surface, as opposite to the earth, 
 than its upper. When the almost infinite dimensions 
 of a cloud, in comparison with one of its constituent 
 globules, is considered, it must be evident that, were 
 the whole electricity of each globule thus, at once, 
 determined to the surface, a tension so enormous would 
 arise as would discharge the whole in a single flash 
 at whatever height the cloud might be. But this is 
 assuredly not the case. Probably but a very minute 
 fraction of the interior electricity is at once conveyed 
 
LIGHTNING. 
 
 131 
 
 to the surface, the further communication being delayed 
 until the exterior tension is relieved, either by slow 
 dissipation or by self- discharge. When this happens, 
 the accumulation commences anew by the same kind of 
 percolation (if we may use the term to express the out- 
 ward struggle of the electricity of the globules), till 
 another and another discharge at length exhaust the 
 supply. 
 
 (137.) It will easily be seen, that when thousands 
 of these electriferous globules again further coalesce 
 into rain drops, a great and sudden increase of tension 
 at their surface must take place. Their electricity, 
 then, is enabled to spring from drop to drop, and 
 rushing in an instant of time from all parts of the 
 cloud to the surface, a flash is produced. Accordingly, 
 in thunder-storms, it is the commonest of all phenomena 
 to find each great flash succeeded by a sudden rush of 
 rain at such an interval of time as may be supposed to 
 have been occupied in its descent.* The sudden pre- 
 cipitation of large quantities of rain, and especially of 
 hail, which is formed in a cold region where the insu- 
 lating power of the air is great, is almost sure to be 
 
 * [Quite recently I have received from a personal friend living 
 at a short distance from my own residence, the following account of 
 his experience of an Electric Stroke. Returning home from a walk 
 a thunder-storm seemed to be brewing. It came on rapidly and 
 he found himself suddenly prostrated “on all fours ” by a flash 
 of lightning, a shock which was not, however, strong enough to 
 deprive him for more than a few instants of self-possession, and 
 not at all of consciousness. It did not rain, or but little, when he 
 was struck, but when he got up, he was drenched to the skin.— 
 Note added , Feb. 1861 .] 
 
132 
 
 METEOROLOGY. 
 
 accompanied with lightning, which the usual perversity 
 of meteorologists, where electricity is in question, long 
 persisted, and even yet persists, with few exceptions, in 
 regarding as the cause, and not the consequence, of the 
 precipitation. The theories of the electrical formation 
 of hail which have been advanced, indeed appear to us 
 too absurd to need a moment’s consideration. The 
 utmost amount of electrical agency which we can con- 
 ceive influential in determining precipitation, is the 
 sudden relief of tension on the discharge of a flash, 
 which may permit, and perhaps, by the vibration of 
 the air in the thunderclap, cause, the coalescence of 
 globules into drops , which would otherwise have been 
 kept asunder by their mutual repulsion. As a cause 
 of winds , or any atmospheric movements not merely 
 molecular , we attribute to it no importance whatever . 
 As a chemical, and still more as a magnetic agent, 
 however, there is every reason to believe atmospheric 
 electricity to play a very important part in the economy 
 of nature ; since we cannot but admit the possibility at 
 least of a connection between the diurnal variations in 
 the electric state of the general atmosphere and the 
 diurnal inequalities of terrestrial magnetism; and the 
 transformation of oxygen into ozone (the most powerful 
 of all known disinfectants) by the electric spark (and 
 therefore on a larger scale by lightning), is not a matter 
 of conjecture but of experiment. 
 
 (138.) There is one phenomenon which at first sight 
 seems opposed to the view we have taken of the pro- 
 duction of lightning — the negative electricity frequently 
 
 ft / ft yt t At Cts*** 
 
 
LIGHTNING. 
 
 133 
 
 observed during the descent of rain. But the researches 
 of Faraday {Phil. Trans . , 1843) have shewn that the 
 friction of water-drops (when pure) against all substances 
 (and therefore probably against air) developes negative 
 electricity most powerfully in the substance rubbed. 
 And the probability is converted into certainty by the 
 fact that the spray of a descending waterfall fills the air 
 around with negative electricity, sensible even at several 
 hundred feet distance. It is probably to this cause that 
 we must attribute the rapid alternations of positive and 
 negative indications in the atmosphere which always 
 attend thunder-storms. 
 
 (139.) It is certain that the flashes of lightning are 
 often some miles in length. The prolonged roar, inter- 
 rupted by explosions, of the thunder, which, excited at 
 the same instant along the whole course of the flash, 
 reaches the ear in succession by the transmission of 
 sound at a uniform rate from every point, sufficiently 
 proves this. Nothing is more common than to see 
 flashes of lightning subtending at the eye an angle of 
 30°, the nearest point of which, estimated by the com- 
 mencement of the thunder, cannot be less than two or 
 three miles distant, and which its prolongation proves 
 to be very oblique to the line of sight. We have been 
 assured by a celebrated Abyssinian traveller, that he 
 has seen flashes in that country extending from horizon 
 to horizon, and which he could not estimate as under 
 50 or 100 miles in length. It is evident, then, that 
 the electricity in lightning does not merely spring across 
 a nonconducting interval to the nearest object (which 
 
134 
 
 METEOROLOGY. 
 
 in. most cases would be the earth), but finds a path of 
 ease, and is led on from interval to interval (as its zig- 
 zags denote) along a line of least resistance, and is not 
 improbably reinforced in its course by other electricity 
 not of itself intense enough to break the obstacle 
 opposed to its escape.* By far the greater number of 
 discharges are made into air or into less electrified cloud, 
 and only a very small percentage into the earth. 
 
 (140.) Of those which do so, the destructive effects 
 are well known, and volumes might be filled with 
 instances of their amazing power, and capricious and 
 unaccountable forms of its manifestation (Arago, Bureau 
 des Long. 1838.) We shall mention only one or two 
 as specimens. In a storm at Ludgvan, in Cornwall, as 
 related by Borlase, Phil. Trans., 1753, a flash of light- 
 ning striking a chimney-stack of hewn stone four feet 
 square, carried it bodily away, and threw it into a pond 
 twenty feet distant. In another, described by Arago, 
 a wall containing twenty-six tons of brick-work was 
 carried en masse, retaining its vertical position, nine 
 feet from its place. We have seen a large oak tree, 
 near Alton, Hants, which was rent into ribands, and 
 every limb of which had been struck off as if by an axe, 
 
 * This is not a mere hypothesis. In an experiment suggested 
 by the author to the late Professor Daniell, and performed as soon 
 as suggested, the striking distance of a voltaic battery was greatly 
 increased by passing a common electric spark from the positive 
 to the negative pole. The vastly increased striking distance of a 
 magneto-electric combination in the neighbourhood of flame, in 
 which its detours may be observed, affords a perfect illustration 
 of the process described in the text. 
 
LIGHTNING. 
 
 135 
 
 and had fallen around the tree, as by mere privation of 
 support, without lateral projection. In producing these 
 effects, the electricity would seem to act immediately by 
 the expansion of vapour generated by its violent heat. 
 V/hen it strikes into deep sand, it produces those extra- 
 ordinary hollow tubes of fused quartz! known as 
 “ fulgurites/’ of which the British Museum possesses a 
 magnificent specimen, dug out near Dresden by Prof. 
 Piedler. Other effects of lightning are recorded in the 
 Athenaeum, Ho. 1535, March 28, 1857, too marvellous 
 to be recounted here, but which, should they be verified, 
 would open quite a new field of inquiry in electrical 
 research. 
 
 (141.) Thunder-storms occur with very unequal fre- 
 quency in different geographical situations. In Jamaica, 
 according to Mr. Graham Hutchinson, a thunder-storm 
 bursts over the mountains near Port Royal every day 
 from the beginning of November to the middle of April, 
 at about 1 h. p. m., continuing about an hour and a half. 
 In the neighbourhood of Cape Town, thunder-storms are 
 few and feeble, while on the eastern coast of South 
 Africa they are frequent and violent. The one region 
 is arid, the other well watered. 
 
 (142.) The quantity of electricity discharged during 
 some storms must be enormous. In the storm of Aug. 
 23-4, 1855, the blaze of lightning was almost uninter- 
 rupted for many hours, from a series of clouds passing 
 from west to east, in two lines, over the south of 
 England. The commencement of the SW. monsoon in 
 India, in May 1848, was marked by “ a thunder-storm 
 
136 
 
 METEOROLOGY. 
 
 extending over 600 miles from N. to S., and measuring 
 50 miles in breadth.” The thunder-storm of September 
 3, 1841, “visited at the same time London, Paris, 
 Eouen, Magney, Lille, and Evereux.” — (Thomson). 
 The mere evaporation of water would seem at first sight 
 inadequate for the supply of so vast an expenditure, 
 were it not that we learn from Dr. Earaday that the 
 chemical action of a “ grain of water on four grains of 
 zinc can evolve a quantity of electricity equal to that of 
 a powerful flash of lightning!” — (Phil. Trans., 1834, 
 p. 117.) 
 
 Systematic View of Meteorological Periodicities — 
 General Principles of Climatology. 
 
 (143.) The climatology of the globe is the summary 
 of our knowledge of the climates of all the places on 
 its surface, so presented to our minds as to convey the 
 notion of law, and give it an ideal unity. To do this it 
 is necessary to study seriatim the elements which enter 
 into our estimate of climate, and follow out the course 
 of the variations of each, — first, independently of the 
 others, and then in connection with them, or, in other 
 words, to determine for each of these elements, ls£, its 
 mean or average amount, as measured in its appropriate 
 units ; %dly, the extent and laws of its deviations from 
 that amount ; and, Zdly, their mutual interdependence, 
 or the reaction of each element on the rest. Such 
 features as are not susceptible of definite measurement, 
 as have no appropriate units, or as we have no instru- 
 
OF METEOROLOGICAL PERIODICITIES. 137 
 
 merits competent to measure, must of course be ex- 
 cluded. Looked upon in this general point of view, 
 the science in question can hardly be considered as 
 advanced beyond its infancy. 
 
 (144.) It is a dynamical law absolutely universal, 
 and one which extends even beyond the domain of 
 mere dynamics, that all periodicity in the action of a 
 cause propagates itself into every , even the remotest , 
 effect of that cause , through whatever chain of inter- 
 mediate arrangements the action is carried out . When 
 the effect is indirect, and especially when it is the 
 result of one and the same law of periodicity in the 
 same cause operating circuitously through several systems 
 of intermediate connection, the numerical valuation of 
 the effect (which, in the simplest case of direct action, 
 depends on the calculation of an expression of the form 
 A + B . sin. ( nt + C), 
 
 where A is the mean or average value of the result, B, 
 C constant quantities, and nt an arc proportional to the 
 time directly, and the length of the period inversely) 
 resolves itself into that of a series of similar terms, con- 
 taining not merely nt 9 but its multiples 2nt, Znt 9 &c., 
 each with its own appropriate constants, and which 
 therefore run through their periods respectively in half, 
 one-third, etc., of the period from which they originate. 
 Thus, if the original period be a diurnal one, and 0 be 
 the time converted into arc at 15° per hour, the ultimate 
 expression of the effect will always put on the form, 
 
 E = A 4- B sin. (0 + C) -f B' sin. (2 0+ C') + &c., 
 in which A is the mean or average value of the effect 
 
138 
 
 METEOROLOGY. 
 
 in question, and B, C, B', C', &c. constants determined 
 a \ priori , if such determination be possible ; if not, by 
 observation from the comparison of as extensive a series 
 as possible of registered values corresponding to de- 
 terminate instants of time. The term containing 0, 
 which runs through its period in a day, expresses the 
 leading feature of the effect — that which gives it its 
 character of a diurnal fluctuation ; the others, which 
 run through theirs respectively in 12h., 8h., 6h., &c., 
 express subordinate fluctuations, more or less materially 
 modifying the law of its increase and diminution, and 
 the epochs of its maximum and minimum, and in 
 certain cases giving rise to double maxima and minima in 
 the twenty-four hours. In meteorology, it has hitherto 
 been seldom found necessary to carry such series out 
 beyond their third or fourth terms. 
 
 (145.) When the acting cause is subject to two or 
 more distinct periodical fluctuations, these make their 
 appearance in the numerical expression of the effect 
 under the form of periodical combinations, such as may 
 arise from multiplying together terms of a similar form 
 containing nt , and another arc n't similarly derived from 
 the other period. In astronomical researches these are 
 usually resolved into sines and cosines of the sums or 
 differences of nt , n't, and of their multiples. But in 
 meteorology this would be inconvenient, and a different 
 mode of regarding such combinations is found prefer- 
 able for the following reason : — 
 
 (146.) The sun’s action being the ultimate efficient 
 cause of all meteorological change, every meteorological 
 
OF METEOROLOGICAL PERIODICITIES. . 139 
 
 fluctuation of a regular character will arrange itself, 
 on the principle above laid down, into diurnal and 
 annual periodicities, including under this expression 
 semi-diurnal and semi-annual ones, &c., and such 
 as may result from their superposition (leaving out of 
 question the period of 11*11 years, depending on the 
 constitution of the sun itself, see art. 7). But the year 
 being a very great multiple of the day, we may regard 
 the solar agency as practically invariable during a single 
 day, or such a small number of successive days as may 
 suffice to bring out the full diurnal effect, which comes 
 to the same thing as adopting in general the diurnal 
 form of expression, 
 
 E = a + b . sin. (0 + c) + b'. sin. (2 Q + c) + &c. 
 where 0 is the sun’s hour angle reckoned from midnight 
 for the fluctuating effect, and regarding the co-efficients 
 a, b , c, &c., as constant for any single day, but each 
 subject to an annual periodicity, and as being, each of 
 them, expressible under the same general form, sub- 
 stituting for 0 the corresponding annual arc — for which, 
 if we choose, we may use the sun’s mean longitude. 
 Thus each of the co-efficients of the diurnal formulae, 
 a + b . sin. (0 + c) 4- b\ sin. (2 0 + c) + &c. 
 comes to be regarded as itself a periodical function of 
 the form 
 
 A + B . sin. (© + C) + B\ sin. (2 0 + O') + &c., 
 
 0 being the sun’s mean longitude. 
 
 (147.) Every one of these co-efficients, whether 
 diurnal or annual, generally considered, is dependent 
 on the geographical position of the place of observation ; 
 
140 
 
 METEOKOLOGY. 
 
 in other words, is the function of the latitude, longitude, 
 and elevation above the sea-level of that place, which, 
 being arbitrary and of unknown form, may be con- 
 sidered as embodying all the local peculiarities of what- 
 ever nature ; and it is not until all these co-efficients 
 are determined, or at least all which have an appreti- 
 able magnitude, for each meteorological element — in 
 temperature, barometric pressure, tension of vapour, 
 rain, &c., wind, and electricity — that the climate of the 
 place can be said to be fully known. 
 
 (148.) Any one of these functions, though its analy- 
 tical form may be quite beyond the reach of our inquiry, 
 yet, by a sufficiently extensive and continuous combina- 
 tion of observation and calculation, carried on upon a 
 system presently to be explained, may become known nu- 
 merically, and tabulated for every accessible part of the 
 globe ; and being so tabulated, the points at which it 
 has equal values may be laid down on a globe or chart. 
 These points being connected by a continuous line, and 
 this done for a succession of values, progressing by con- 
 venient and regular intervals in the scale of magnitude 
 of the function, from the maximum which it has in any 
 part of the globe down to the minimum which occurs 
 anywhere ; a series of level lines, or isometeoric lines 
 (if we may coin a word to convey the general notion) 
 will arise, which will present to the eye the progression 
 and connection of this ^particular co-efficient over the 
 world. Exactly as if wishing to convey, for instance, 
 an idea of the exterior form of the solid surface of the 
 globe, we should commence by delineating the coast- 
 
ISOMETEORIC LINES. 
 
 141 
 
 lines of the continents and islands, which are the level- 
 lines for 0 ft. from the sea-level, and similarly laying 
 down points wherever the height of 100 ft. above, or 
 depth of 100 ft. below the sea occurred, and connect- 
 ing them, should get the level lines of + 100 ft. or 
 — 100 ft., i.e., what would be the coast-lines were the 
 sea to rise or sink 100 ft. ; and so on, to the tops of 
 the mountains and extreme depths of the ocean. 
 
 (149.) This mode of exhibiting to the eye by a pic- 
 ture (a picture which might become a model by execut- 
 ing it in relief) the law of variation of a function 
 known only by observation, over the surface of the 
 globe, or any particular district of it, was first devised 
 by Halley to express the law of the variation of the 
 magnetic compass, but first introduced into meteorology 
 by Humboldt, to exhibit the law of distribution of 
 temperature, by laying down a system of Isothermic 
 lines , or those in which the mean annual temperature 
 is alike throughout ; that is to say, in which the co- 
 efficient, A, in the expression for the mean temperature 
 of the whole year, viz., A + B . sin. (0 + C) -f &c., is con- 
 stant ; and which, therefore, serve to connect in idea, 
 as places having at least one very eminent meteorolo- 
 gical feature in common, all those points in the globe 
 which receive (from whatever cause) the same annual 
 total of heat. To these lines we shall recur hereafter. 
 Climatology as a science (or .rather as a branch of 
 physical geography, to which, rather than to meteor- 
 ology, it properly belongs), would be complete, or nearly 
 so, if we possessed a complete atlas of such charts, each 
 
142 
 
 METEOROLOGY. 
 
 I 
 
 containing the isometeoric lines for all the really 
 influential co- efficients, both annual and diurnal (which 
 are not very numerous), exhibiting the mean values of 
 each of the annual co-efficients from the observations 
 of many years, and the mean values and annual maxima 
 and minima of each of the diurnal ones. Hitherto 
 only a few of such lines have been traced, and that 
 imperfectly, viz., the lines suggested by Humboldt, or 
 the Isothermal , Isotheral and Isocheimonal lines, or 
 those in which the general mean temperature, the 
 mean summer temperature, and the mean winter tem- 
 perature, are respectively constant ; the Isogeothermal 
 lines of Kupffer, in which the mean temperature of the 
 soil is constant (and which are not always identical 
 with the Isothermals), the Isobarometric lines of 
 Kamtz, in which the limits of fluctuations of barometric 
 pressure are equal (a series of which it is not easy to 
 see the use), and a few others. We shall now pro- 
 ceed to consider by what means such knowledge can 
 most readily and effectually be "attained. 
 
 (150.) Determination of Meteorological Averages 
 and. Co-efficients . — The general form into which, as we 
 have seen, every meteorological quantitative expres- 
 sion can be thrown, clearly indicates the system of 
 observation which ought to be followed, so as to lead 
 most directly to a knowledge of their mean values. It 
 is a well-known property of the sine or cosine of an 
 arc, that if the circumference be divided into any 
 number, n , of equal parts, 0, we shall have, 
 sin. (f + c) + sin. (2 Q + c) + sin. (n^-f c) = 0. 
 
AVERAGES AND LAWS OF FLUCTUATION. 143 
 
 Suppose, then, we would ascertain the diurnal mean, 
 a, of any element, E, supposed to he expressible as in 
 art. 144. Were we sure that E contained only one 
 periodical term, b . sin. (0 -j- c), it would suffice to make 
 a series of observations at intervals of 12 hours, on 
 summing up which, as the + and — values of this term 
 would destroy each other, the sum divided by the 
 number would afford the value of a. If an eight-hourly 
 interval be substituted for a twelve, a like summation 
 will eliminate the terms depending both on Q and 2 Q ; 
 if a six-hourly one, those depending on 0, 2 & and 3 0, 
 and so on. So far as meteorological computation has 
 hitherto been carried, this would appear to be in most 
 cases sufficient, the co-efficients of the successive terms 
 diminishing rapidly. From a simple observation per 
 diem , no average can be concluded, except it be made 
 at such an hour as experience shews to be that on 
 which the quantity observed has usually its mean 
 value. This differs for each element and for each 
 locality, and is itself a desirable item of meteorological 
 inquiry. 
 
 (151.) Annual means may be obtained by summing 
 diurnal ones. If the series be incomplete, two courses 
 may be followed, viz., 1 st, By subdividing the year into 
 monthly groups, calculating the means for each month 
 from the observations recorded, and taking a mean of 
 the twelve results; or, Zdly, by striking out days 
 corresponding to those deficient at 3- or 4- monthly 
 intervals from each. 
 
 (152.) The law of fluctuation requires us to know 
 
144 
 
 METEOROLOGY. 
 
 the values of the several constants which enter into 
 the periodical terms. To do this effectually from a 
 series of recorded observations, requires the application 
 of the “ method of least squares.” If the observations 
 be numerous, and made at irregular hours, this is 
 attended with a frightful amount of calculation; but 
 if they form a regular series made at definite hours 
 of the day, and either complete, for many days, or 
 capable of being completed by the insertion of the 
 deficient observations according to any observed law 
 of progression, or in the absence of such law , by a 
 mean of the adjacent day's observations at homologous 
 hours , nothing can be simpler or more expeditious 
 than the treatment of such a series by least squares, 
 so as to give the most probable values of the constants. 
 The following practical rule, the investigation of 
 which is, we believe, originally due to Bessel, will give 
 them : — 
 
 (153.) Suppose we have such a series of observations 
 
 at epochs d, 2 3 Q, n 6 = dividing any entire period 
 
 into equal intervals, reckoning from and up to the end 
 of the period, or any other convenient epoch. Let S x , 
 S 2 , . . . . S w be the sums of the observed values, at 
 homonymous epochs, throughout the series. Look 
 out, in a table of sines and cosines, for the sines and 
 
 cosines of 9, 2 Q, n 0 converted into degrees at the 
 
 rate of 15° per hour for the diurnal, or 30° per month 
 for the annual fluctuation (or their logarithms, if we 
 proceed logarithmically), and call the sines in succession 
 s l9 s 2 , ... . s n , and the cosines c v c 2 , . . . c n , observing 
 
CALCULATION OF MOST PROBABLE AVERAGES. 145 
 
 that s n = 0 and c n = 1. This done, compute the quan- 
 tities a 0 , a l9 a n , b l9 ... . b n , by the following 
 
 formulae, in which U is the total number of observations 
 at all the epochs : — 
 
 « o = ^(Sx + S 2 +....S n ) 
 
 2 
 
 a i ~ ipi c 2 S 2 + . • • . c n S n ) 
 
 2 
 
 = ( C 2 + c 4 S 2 + c 2n SJ 
 
 2 
 
 a 3 = jj ( c 3 S x + C 6 S 2 + . . . . c 3w S n ) &c. 
 
 2 
 
 = ^; (^i Si + ^ 2 S 2 H- . . . . S n ) 
 
 and so on. These will be the most probable values , 
 respectively, of the co-efficients in the general expres- 
 sion of E under the periodical form, 
 
 E = a 0 +cq . cos. Q-\-b x . sin. &+a 2 . cos. 2 . sin. 2 &f&c. 
 
 which may then be transformed into 
 E = A + B x . sin. (6 + C x ) + B 2 . sin. (2 & -f C 2 ) + &c. 
 
 by taking A = a 0 • B = \/a 2 + b 2 ; tan. C = 
 
 (154.) In the practical application of this formula, 
 it is not necessary that the number of the terms of 
 which the final result E is to consist, should be pushed 
 farther than necessity or convenience may require, and 
 it is a peculiarly valuable property of these expressions, 
 that if the approximation be stopped at any one term, 
 as, for instance, at the term B x . sin. (0 -f C^), and the 
 co-efficients B x and G 1 be determined accordingly, then 
 should it be considered afterwards desirable to carry it 
 
 L 
 
146 
 
 METEOROLOGY. 
 
 a term farther, so as to include the next sub-period 
 expressed by the term B 2 . sin. (2 Q + C 2 ), it is not neces- 
 sary to recompute the former co-efficients, their values 
 remaining unaltered, so that the several sub-periodic 
 terms are separately and independently calculable from 
 any complete series of observations, just as if the others 
 had no existence. And moreover, the constitution of 
 the formulae is such that any number of complete cycles 
 of observation may be treated as a single cycle, by 
 taking the means of the recorded observations at 
 homonymous epochs, and thus forming from them a 
 single cycle. 
 
 (155.) For example, supposing we have a series of 
 mean monthly results, obtained during a series of years, 
 for any meteorological element, such as temperature, 
 and we wish to deduce from them the law of the annual 
 fluctuation. In the first place, we take the mean of all 
 the results for January as a .new January mean, of 
 February for February, and so on, and denoting their 
 means so obtained in their order, by S x , S 2 , S 3 , . . . . S 12 . 
 If we wish merely to obtain the most probable mean 
 annual temperature, we use the expression, 
 
 a=JL{s 1 + s 2 + ....s4 
 
 If we would now carry the inquiry one step farther, 
 and determine the amount of fluctuation regarding the 
 curve of temperature as one of a single undulation, 
 neglecting subordinate flexures and sub-periods, we 
 retain the same value of A, and calculate B 2 and C x by 
 the formulae. 
 
CALCULATION OF MOST PROBABLE AVERAGES. 147 
 
 6 o l =(S 1 -S f -e T +S u ) . cos. 30° 
 
 + (S 2 -S 4 -S 8 + S 10 ). cos. 60° 
 
 — S 6 + s 12 
 
 6& 1 = (S 1 4 -S 5 -S 7 -S 12 ).sin. 30° 
 
 4 - (S 2 + S 4 — S 8 — S 10 ) . sin. 60° 
 
 4- S 3 — S 9 
 
 B 1 = >J(A 4* b\ ; tan. C a = ^ 
 
 And if we would now go on farther to investigate the 
 semi-annual sub-period, or that depending on 2 Q, we 
 retain the means of A, B 1? C 1? already computed, and 
 still using the same sums S 1? S 2 , &c., go on to find a 2 , 
 & 2 , and from them B 2 and C 2 by the formulae, 
 
 6 a 2 = (Sj — S 2 — S 4 -f S 5 + S 7 — S 8 — S 10 4- S u ) 
 x cos. 60° 
 
 - S 3 4- S 6 — S 9 4- S 12 
 
 6 b 2 = (S x + S 2 - S 4 - S 5 4 - S 7 + S 8 - S 10 - S u ) 
 x sin. 60° 
 
 a 2 
 
 B 2 = y/at 4 - b \ ; tan. C 2 = ~r • 
 
 o 2 
 
 In applying which it will be remembered, of course, 
 that as the means S x , S 2 , &c., belong to the middle of 
 the months, the values of 0 corresponding to them are 
 30°, 60° &c., so that the commencement of the year 
 from which 0 reckons, is, in effect, placed in the middle 
 of December. If we reckon the time, then, from the 
 beginning of January, this amounts to putting 0 4-15° 
 for © ; or, retaining the same values of the co-efficients 
 A, B 1? B 2 , &c., increasing Cj by 15°, C 2 by 30°, &c. 
 
148 
 
 METEOEOLOGY. 
 
 For the third term, the co-efficients are still more 
 simple in their expression, viz., 
 
 6 a 3 = — S 2 + S 4 — S 6 + S 8 — S 10 + S 12 
 6 b z = -f* S* — S 3 + S 5 — S 7 + S 9 — S n 
 
 (156). The apphcation of the formulae is equally 
 simple and easy in every other case ; and, in fact, such 
 is its facility, that it leaves no excuse to meteorologists 
 for not reducing their observations, and should act as a 
 powerful recommendation to induce them, in all cases, 
 to conform to its requisitions in arranging the times of 
 their observations. 
 
 (157.) All that depends on regular periodic action 
 may he represented in this manner by periodic functions, 
 the co-efficients of which, as determined by observations 
 for any place, embody the resultant of the mode in 
 which the action is propagated to the place. Each of 
 them is therefore, no doubt, inherently a function of 
 the latitude and longitude of the place, but one com- 
 plicated with and dependant on the whole geographical 
 system of the globe, as one of its data— the configura- 
 tion of its land, the height and arrangement of its 
 mountain chains, nay, even the depths of its seas and 
 the form of their beds ; since all these elements enter 
 into the list of causes which determine the arrival of 
 heat, wind, and moisture at the place. 
 
 (158.) It is the task of the practical meteorologist, 
 each at his own station, to furnish his quota of recorded 
 observation towards carrying out this great work — a 
 task tedious, perhaps, and requiring, like all scientific 
 
HOURS ADVANTAGEOUS FOR OBSERVATION. 149 
 
 operations, care in observing and precision of statement, 
 but easy in itself, and full of interest at least to such as 
 are able and willing to execute the reduction of their 
 own observations, and thereby to furnish (so to speak) 
 not merely a lump of material rude from the quarry, but 
 a stone hewn and squared on the spot, and ready to take 
 its fitting place in the general edifice. Having fixed on 
 the range and scope of his observations, the instruments 
 whose indications he proposes to record, and the hours 
 at which his personal convenience, and the dependable 
 means at his command will enable him to record them, 
 all he has to do is to pay scrupulous attention to obviate 
 everthing which may tend to derange the adjustment of 
 his instruments, or affect the fairness of their exposure 
 — to read them off accurately, and register the readings 
 faithfully, and to adhere precisely to system in their 
 reduction. It should be remembered, however, that no 
 series of observations can be considered of any value for 
 the determination of the diurnal co-efficients in which 
 the twenty-four hours are not equally divided by the 
 epochs of observation, and of comparatively little if they 
 be fewer than four in number ; the most advantageous 
 hours for which, generally speaking, will be found to 
 be 3 h. and 9 h. a.m. and p.m., or 4 h. and 10 h. a.m. 
 and p. m., should the habits of the observer render the 
 3 h. a.m. observation very irksome. 
 
 (159.) To those observers, however, whose means 
 will allow them to avail themselves of the resources 
 which modern art affords, the principles of photographic 
 and mechanical self-registry, which have of late been 
 
150 
 
 METEOROLOGY. 
 
 applied to all the most important instruments, affords 
 an alleviation of all the tedium of personal attendance, 
 and supplies what personal observation never can do 
 — an unbroken record of the march of each instrument 
 during the night as well as the day. On the occasion 
 of a reward of £500, offered in 1846 by the Lords 
 Commissioners of the Admiralty, for the discovery of 
 an available application of photography for such pur- 
 poses, two systems of procedure were devised and 
 carried into effect by Mr. Brooke and Mr. Bonalds, the 
 one at the Boyal Observatory at Greenwich, the other 
 at the observatory of the British Association at Kew, 
 both of which have been found perfectly adequate to 
 the object, not only of meteorological, but of magnetic 
 self-registry. Without going into minutiae (which the 
 reader will find stated for the former system in the 
 Introduction to the Greenwich Observations for 1847, 
 and for the other in three papers published in the 
 Transactions of the Boyal Society for 1847), we may 
 state the general principle of Mr. Brooke’s method in 
 few words, as follows : — Paper being prepared sufficiently 
 sensitive to receive an impression from the light of an 
 argand or camphine lamp by night, and the reflected 
 light of the sky by day, is stretched between two rollers, 
 so as to be wound on one and unwound from the other 
 uniformly by clock-work, receiving, as it travels, punc- 
 tures or marks made on it by an appropriate mechanism, 
 at equal intervals of time, suppose hourly, and which, 
 therefore, convert the space travelled over into a scale 
 of time capable of being read off by a scale of equal 
 
PHOTOGRAPHIC SELF-REGISTRY. 
 
 151 
 
 parts, if necessary. The direction of the motion of the 
 paper is perpendicular to that in which the indicating 
 point of the instrument to be registered moves, whether 
 that be the end of a column of mercury rising and fall- 
 ing (as in the stem of a thermometer, or in the tube of 
 a barometer), on an index arm, capable of carrying a 
 screen pierced with a hole to transmit a small pencil of 
 light. If the former, the light is so arranged that only 
 the vacant 'part of the stem or tube above the mercury 
 shall allow a free passage for it to reach the paper, the 
 shadow of the mercury cutting off all below. If the 
 latter, the whole paper is shaded except that point 
 which happens at each instant to be behind the hole. 
 In the one case, the boundary of light and shadow is 
 marked by a curve terminating the continuous photo- 
 graphic impression formed by the unrolling of the paper ; 
 in the other, the impression itself takes the form of a 
 curve line, of which the ordinate indicates the reading 
 of the instrument at the moment of time indicated by 
 the abscissa. To facilitate the subsequent reading off 
 of these curves, the graduation of the scale (in the case 
 of the thermometer), is marked on the paper by the 
 shadows of wires carried across the stem at each degree. 
 In Mr. Konalds’ second or improved method, described 
 in the third of the papers above cited, an image of the 
 index point, terminal line of mercury, or other object 
 which defines the reading of the instrument, is formed 
 by an achromatic lens on the moving paper. One or 
 other of these systems of self-registry, or some equiva- 
 lent one, is, or ought to be, adopted wherever meteoro* 
 
152 
 
 METEOROLOGY. 
 
 logical observation is caried on as a part of the regular 
 business of a public establishment. Taken in conj unction 
 with the mechanical self-registry of the anemometer, and 
 with that by which the rain-gauge is made to empty 
 itself whenever a definite quantity of rain is collected, 
 and to record the number of such emptyings, and the 
 weight of water it contains at each hour, the system of 
 self-registry may be regarded as complete. 
 
 (160.) For the special reductions which each kind 
 of instrument requires, the nature of its adjustments, 
 and the precautions to be observed in its use, we must 
 refer the reader to the descriptions of the several instru- 
 ments in other parts of this work* under their proper 
 heads ; to the Admiralty Manual of Scientific Inquiry 
 already referred to, and the report of the Eoyal Society 
 on the occasion of Captain Ross’ Antarctic Expedition 
 in 1840 ; and to the former of these separate works for 
 a detail of the particulars which a complete meteoro- 
 logical register ought to embrace, and the most conve- 
 nient and advantageous form of statement it admits. 
 
 Of the Distribution of Barometric Pressure, and 
 its Pebiodical Fluctuations. 
 
 (161.) The mean barometric pressure on any place 
 is of course dependent on its height above the sea 
 level, so that each locality has corresponding to it 
 a certain individual correction or reduction to the 
 
 * This refers to the Encyclopaedia Britannica in which this 
 Essay originally appeared. 
 
LOCAL INEQUALITIES OF BAROMETRIC PRESSURE. 153 
 
 sea level, which affects equally all its barometric 
 observations. When the level of the place is tri- 
 gonometrically ascertained, the mean temperature of 
 the station being known, this reduction may be 
 exactly computed; and were it a fact that the mean 
 barometric pressure at the sea level were everywhere 
 the same, the height of every place might be determined 
 from the mean height of the barometer as given by 
 observation. This, however, is not the case. We have 
 already seen (art. 54) that in the open ocean the 
 pressure diminishes on approaching the equator from 
 either side, as well as the reason for this diminution. 
 Eut this is not all. The atmosphere is not in a state 
 of statical equilibrium, nor are the forms of its strata 
 of equal density identical (as they would be in that 
 case) with the ellipsoids of equal level, for the very 
 obvious reason, that the surface of a fluid in motion 
 (even when unagitated by waves), is not necessarily and 
 in all cases that of the same fluid at rest. The surface 
 of a river, though smooth, is not a horizontal, but an 
 inclined plane. That of a swift stream with an unequal 
 bottom is not a plane at all, but a surface of ridges and 
 depressions, fixed in place and permanent in form, as 
 is seen in the familiar case of the ripple caused by a 
 smooth round stone at some depth below the surface; 
 hence we might be prepared to expect great differences 
 between the surfaces of equal level and of equal density 
 in the interior of extensive continents, where the atmo- 
 sphere, swept en masse from the sea, up the gradual 
 slope of the land surface, is lifted with all its strata 
 
154 
 
 METEOROLOGY. 
 
 preserving their relative bearings on each other: the 
 extent of elevated country on all sides tending to pre- 
 vent lateral overflow. Under such circumstances there 
 may, or rather must, exist great discordances between 
 the trigonometric and barometric determinations of 
 altitudes (the only form in which the cause in question 
 can make its appearance), and which, it may be remarked 
 generally, go to render all barometric determinations 
 uncertain in windy weather. 
 
 (162.) What may not, however, be so obvious, or 
 rather what, when first proposed, appears quite para- 
 doxical, is that, even in the open ocean, there exist 
 extensive tracts in which a permanent depression of 
 the barometer to the enormous extent of an inch and 
 upwards (equivalent to an elevation of 800 feet above 
 the sea level), is found to prevail. Such a tract is the 
 whole extent of the Antarctic Ocean, from 63° to 74° 
 S. lat., and 8° to 7° W. long, as ascertained by Sir 
 James C. Eoss ( Voyage of the Erebus and Terror , ii. 
 376, 385); and a corresponding depression, though not 
 to so great an extent, appears, by the observations of 
 Ermann, to exist in the region nearly diametrically 
 opposite, about the Sea of Ochotzk, and in the interior 
 of the Asiatic continent of that neighbourhood. 
 
 (163.) It is impossible not to perceive, in these 
 singular phenomena, at least a prima facie evidence of 
 the existence of what must be regarded as a fixed 
 system of ripples in the general atmosphere, caused by 
 the great system of circulation in both hemispheres of 
 the trades and anti-trades reacting on the general mass 
 
ANNUAL OSCILLATION OF THE BAROMETER. 155 
 
 of the continents as obstacles in their path, and depen- 
 dent for their depths and limiting forms on the con- 
 figuration of the surface of the land. The progressive 
 change of mean atmospheric pressure at sea, in pro- 
 ceeding from the equator southwards, is stated by Sir 
 J. Eoss as follows : — 
 
 Lat. South. 
 
 Mean Pressure. 
 
 Lat. South. 
 
 Mean Pressure. 
 
 0 ° 0 ' 
 
 29.974 
 
 51 9 33 ' 
 
 29.497 
 
 13 0 
 
 30.016 
 
 54 26 
 
 29.347 
 
 22 17 
 
 30.085 
 
 55 52 
 
 29.360 
 
 34 48 
 
 30.023 
 
 60 
 
 0 
 
 29.114 
 
 42 53 
 
 29.950 
 
 66 
 
 0 
 
 29.078 
 
 45 0 
 49 8 
 
 29.664 
 
 29.469 
 
 74 
 
 0 
 
 28.928 
 
 (1 64.) For northern latitudes, the results hitherto col- 
 lected run very irregularly. Meteorologically, however, 
 this is not a cause [in so far as it can be taken as an 
 account of the whole of the phenomena in question 
 ( vide § 171)], which would appear to be productive of 
 any marked train of consequences. And in relation to 
 the matter at present in hand, it goes only to show, that 
 the first term of the periodic function expressing the 
 barometric pressure is not an absolute constant, even for 
 the ocean ; but that it has to be tabulated and worked 
 out by local observation into a system of isobarometric 
 lines, carried indifferently over both sea and land, and, 
 as regards the latter, distinct from the level lines. 
 We are far, indeed, from any approach to the con- 
 struction of such a system. 
 
156 
 
 METEOROLOGY. 
 
 (165.) The periodic fluctuations of the barometer 
 are annual and diurnal. The consideration of the 
 former will enable us to form a neater conception of 
 the mode in which the latter arise. When it is sum- 
 mer in one hemisphere it is winter in the other. Hence 
 (See art. 7 8), the air generally incumbent on the heated 
 hemisphere is dilated, and expands both upwards and 
 laterally, not only by its own increased elasticity but 
 also by the increased production of vapour. It there- 
 fore not only encroaches on the other hemisphere by 
 lateral extension, but what is far more influential, flows 
 over upon it. In order to perceive clearly the nature 
 of the process, we must separate in idea the aqueous 
 and aerial constituents of the portion of atmosphere so 
 transferred. The generation of the former goes on in 
 the heated hemisphere, and replaces, in part at least, 
 the loss of pressure arising from the transfer of air, 
 while in the other the excess of vapour so introduced is 
 constantly undergoing precipitation, and is thus con- 
 tinually being withdrawn from the total mass, leaving 
 behind it, however, to accumulate, the dry air which 
 accompanied it. Thus, if we regard the total barometric 
 pressure as subdivided into that of the dry air and of the 
 aqueous vapour, and denote the former by P, the latter 
 by Y, we see that the dry pressure P is diminished in 
 the hot, and increased in the cold hemisphere, without 
 any countervailing action, while V is in process of 
 increase from below by evaporation, and of diminution 
 from above by overflow, in the former : and vice versd 
 in the latter. If, then, the observed barometric pres- 
 
DISTINCT PRESSURES OF DRY AIR AND VAPOUR. 157 
 
 sure at every point in either hemisphere be analysed 
 by calculation into its two constituents, by taking 
 account of the hygrometric state of the atmosphere, 
 and subtracting from the total pressure P + V the 
 portion V due to the amount of vapour present, the 
 remainders ought to exhibit, as a general result, an 
 excess of dry pressure P in the winter hemisphere over 
 that in the summer. 
 
 (166.) So far as observation has hitherto gone, this 
 result is perfectly corroborated, though unfortunately 
 there are not yet accumulated sufficiently numerous 
 and extensive series of observations in which the effects 
 of the aqueous pressure can be duly separated from the 
 dry. As examples, we shall select the series for the 
 Indian stations, Calcutta, Benares, Seringapatam, and 
 Poonah, calculated by Dove from the observations of 
 Prinsep, Sparmann and Colonel Sykes, as compared 
 with that at Apenrade from those of Neuber, and with 
 the results obtained at the Meteorological Observatories 
 of Prague, Toronto, and Hobart Town, v.d.l. 
 
 Stations. 
 
 P, PRESSURE OF DRY AIR. 
 
 V, PRESSURE OF VAPOUR. 
 
 Max. in 
 
 Min. in 
 
 Differ. 
 
 Max. in 
 
 Min. in 
 
 Differ. 
 
 Calcutta 
 
 Jan. 
 
 July 
 
 inches. 
 
 1.019 
 
 Aug. 
 
 Jan. 
 
 inches. 
 
 0.551 
 
 Benares 
 
 Dec. 
 
 July 
 
 1.244 
 
 July 
 
 Dec. 
 
 0.645 
 
 Seringapatam 
 
 Jan. 
 
 June 
 
 0.455 
 
 May 
 
 Jan. 
 
 0.217 
 
 Poonah 
 
 Dec. 
 
 June 
 
 0.760 
 
 July 
 
 Dec. 
 
 0.435 
 
 Apenrade 
 
 Feb. 
 
 July 
 
 0.450 
 
 July 
 
 Jan. 
 
 0.346 
 
 Prague 
 
 Dec. 
 
 July 
 
 0.383 
 
 July 
 
 Jan. 
 
 0.285 
 
 Toronto 
 
 Dec. 
 
 July 
 
 0.271 
 
 Aug. 
 
 Feb. 
 
 0.380 
 
 Hobart Town 
 
 July 
 
 Nov. 
 
 0.218 
 
 Feb. 
 
 July 
 
 0.125 
 
158 
 
 METEOROLOGY. 
 
 These differences are large quantities ; "but we see that 
 as the maxima of P correspond in point of time with 
 the minima of V, it is only their differences which 
 constitute the total or observed annual fluctuation of 
 barometric pressure. 
 
 (167.) Since, as observed (art. 165), the annual 
 fluctuation of Y is the result of an excess of supply 
 over expense in one hemisphere, and of expense over 
 supply in the other, it may very well happen that the 
 annual fluctuation of Y in certain localities may exceed 
 that of P, and being in a contrary direction, may either 
 neutralize the fluctuation of the gross pressure P + Y, 
 or convert it into one of an opposite character. This, 
 however, is but rarely the case, and where instances of 
 it do occur, as at Sta. Fe de Bogota, and Bangalore 
 ( Kamtz , ii. 299), they are for the most part readily 
 enough accounted for by the influence of local pecu- 
 liarities. 
 
 (168.) If we consider that in general the values of 
 P and Y, regarded independently, fluctuate in opposite 
 directions, and hence the maximum of the one corres- 
 ponds, or nearly so, in epoch with the minimum of the 
 other, we shall easily see that, representing P by 
 
 P = A + B . sin. (0 + C) -j- B . sin. (2 0 -f- C ) + &c* 
 
 we shall have, at least approximately, for Y an expres- 
 sion such as, 
 
 Y = a+/3 . sin. (0+C-J- 180°)+/3\ sin. (2 04-7')+ &c. 
 the value of C in the term 0 differing by 180°, while 
 
EXPLANATION OF THE DOUBLE MAXIMUM. 159 
 
 those in other terms (C", /, C"> y", &c.) may or may 
 not stand to each other in a similar relation — the only 
 condition being, that they shall he such as to render 
 the co-efficients B, B', &c., j3, /3', &c., all positive. The 
 gross pressure P + V, then, will come to he expressed 
 by the form, 
 
 P + V = (A + a) + (B — j3) . sin. (0 + C) + M . sin. 
 
 (2 0 + N) + M" . sin. ( 3 0 + N') + &c. , 
 
 Since B' . sin. (2 0 +C ')+/3' . sin. (20 + /) may always 
 be reduced to the form, 
 
 M . sin. (2 0 + N), &c. 
 
 (169.) Thus we see that the tendency of the cotem- 
 porary action of the two elements composing the gross 
 pressure is, 1st , to produce a mean annual pressure 
 (A + a) equal to the sum of the separate pressures ; 
 2 dly, to subdue the influence of the term depending on 
 0 , by reason of the opposition of signs affecting B and 
 j 8 in the joint co- efficient B — j3; and thus, 3 dly, to give 
 a greater comparative influence to the terms depending 
 on 2 0 , 3 0 , &c. Now it will be observed that a series 
 thus constituted, of sines of 0 , 2 0 , &c., when made to 
 run through its whole period by varying 0 from 0 to 
 360°, will have only a single maximum and minimum 
 when the co-efficient of sin. (0 + C) is large in compa 
 rison with those of the other sines, but when the 
 contrary is the case, a double, or even triple or mul- 
 tiple maximum and minimum may result from such 
 mutual relations among the co-efficients as may very 
 
160 
 
 METEOROLOGY. 
 
 easily occur. The principal terms nearly neutralizing 
 each other by their mutual opposition, leave the general 
 character of the law of periodicity of the compound 
 effect to be decided by the relations inter se of the 
 subordinate ones, and thus is explained, without preju- 
 dice to the general reasoning in art. 77, 78 (which 
 remains true as regards the form of the atmosphere as 
 disturbed by the sun’s action), the fact, which appears 
 on first sight in opposition to that conclusion, that the 
 annual oscillation of the gross barometric pressure 
 presents in a great many localities the phenomenon of 
 a double maximum, or even a still more complex cha- 
 racter. Thus, in Paris, to take a single instance, from a 
 mean of eleven years’ observations (1816-1826), the 
 total pressure exhibits two maxima in January and in 
 July, the former being highest, and two minima in 
 April and October, the latter being the lowest ( Kamtz , 
 ii. 295). 
 
 (170.) The great length of time in which the effi- 
 cient causes are acting in one direction, to produce the 
 annual oscillation in question, admits of a very con- 
 siderable fraction of the atmosphere to be transferred 
 from hemisphere to hemisphere, and to allow a range 
 in the values of P, for instance, to the large extent (as 
 we have seen in the case of Benares) of nearly an inch 
 and a quarter of mercury, partially neutralized by a 
 fluctuation of more than half an inch of aqueous vapour. 
 Thus the effects are brought out into prominence, in 
 both elements, by the long- continued action of the 
 causes ; and thus, by the study in the first instance of 
 
DIURNAL OSCILLATION OF THE BAROMETER. 161 
 
 the annual oscillation, we are led to an easy under- 
 standing of the perfectly analogous phenomena in the 
 diurnal oscillations (or, as they have sometimes though 
 in fact improperly been called, “ atmospheric tides ”) 
 which have a good deal perplexed meteorologists, but 
 whose analysis, into what we have for convenience 
 called wet and dry pressure, has happily been suggested 
 by M. Dove as affording a rational explanation. 
 
 (171.) To simplify our conception of the diurnal 
 oscillation, we will suppose the sun to have no declina- 
 tion, but to remain constantly vertical over the equator. 
 The surface of the globe will then be divided into a 
 day and a night hemisphere, separated by a great circle 
 passing through the poles, coincident with the momen- 
 tary horizon, and revolving with the sun from east to 
 west in twenty-four hours. The contrast of the two 
 hemispheres, both in respect of heat and evaporation, 
 in this case will evidently be much greater than in that 
 of art. 165, and therefore the dynamical cause, the 
 motive force, transferring both air and vapour from the 
 one to the other, will be much greater. But on the 
 other hand, much less time is afforded for this power to 
 work out its full effect, and long before this can be 
 accomplished for any locality, the circumstances are 
 reversed, and a contrary action commences. The causes, 
 then, and the mode of their agency, are perfectly analo- 
 gous, in the production, whether of the annual or diurnal 
 oscillation ; but in the former, the feebler acting cause 
 is aided by the very much greater length of the period ; 
 in the latter, its superior intensity is in great measure 
 
 M 
 
162 
 
 METEOROLOGY. 
 
 neutralized by the frequency of its reversal. There is 
 another consideration, moreover, which cannot be with- 
 out a great effect in establishing a distinction between 
 the two cases. By far the larger portion of the land is 
 distributed over the northern hemisphere, and of the 
 water over the southern. The former is more uniformly 
 terrene, the latter more uniformly aquatic ; and as, 
 under the circumstances now considered, the transfer 
 of air does not take place in the direction of meridians, 
 but at right angles (mainly) to their direction, we 
 should be led to expect that the amount of counter- 
 action in the diurnal fluctuations of the dry pressure 
 p by those of the wet v, would be, generally speaking, 
 very different in the two hemispheres, and that there- 
 fore the extent of fluctuation in the gross pressure 
 p + v would, generally speaking, present a corresponding 
 difference. A sufficient amount of observation has not 
 yet been accumulated to bring this conclusion to the 
 test of experience ; but we cannot help remarking that 
 the very same cause (the excess of water in the southern 
 hemisphere), acting according to the difference of condi- 
 tions, ought, in the case of the annual oscillation, to 
 result in an average uncompensated action on the dry 
 air, urging it towards the northern hemisphere, and to 
 its replacement, bulk for bulk, by vapour, which being 
 lighter than air, [is assuredly one, and it may be the 
 most efficient] of the causes of the generally lower 
 atmospheric pressure over the Southern Ocean — a 
 certain percentage of the due proportion of dry air 
 being permanently driven out and prevented from 
 
DIURNAL OSCILLATION OF THE BAROMETER. 163 
 
 returning by the constant outflow of vapour. See § 
 164. 
 
 (172.) It ought to be observed, that the oscillations 
 in question are only in appearance analogous to those 
 of the oceanic tides. In the latter, the tide wave is 
 merely a circulating form without any [bodily transfer 
 to any great distance]. The sun’s heating action on the 
 atmosphere is not one which, destroying a portion of its 
 gravity, tends to alter its form of equilibrium, but one 
 which, leaving its gravity unaltered, tends to throw its 
 strata by their dilatation, and by the introduction of 
 vapour from below, into forms incompatible with 
 equilibrium, and therefore necessarily productive of 
 lateral movements. When anemometry is further per- 
 fected, we may expect to trace the influence of this 
 chain of causation into a morning and evening tendency 
 of the wind (on a long average of observation), to draw 
 towards the points of sunrise and sunset, to compensate 
 the overflow from off the heated hemisphere, which 
 takes place aloft in the contrary direction. 
 
 (173.) The diurnal oscillation of the barometer is a 
 phenomenon which invariably makes its appearance in 
 every part of the world where the alternation of day 
 and night exists , on reducing any considerable series of 
 hourly observations, though in extra-tropical latitudes 
 it is for the most part so overlaid by casual variations 
 as not to be remarked in a single day. On the other 
 hand, between the tropics, and especially in the equa- 
 torial regions, its regularity of progress is most striking. 
 Thus Colonel Sykes remarks {Phil. Trans., 1850) that, 
 
164 
 
 METEOROLOGY. 
 
 among many thousand observations taken personally by 
 himself on the plateau of the Deccan (1825-30), there 
 was not a solitary instance in which the barometer was 
 not higher at 9-10 a.m. than at sunrise, and lower at 
 4-5 p.m. than at 9-10 a.m., whatever the state of the 
 weather, &c., might be. Humboldt also observes 
 (tom. i. p. 308) : — “ this regularity is such that, in the 
 daytime especially, we may infer the hour from the 
 height of the column of mercury without being in error 
 on an average more than 15 or 17 min. In the torrid 
 zone of the hTew Continent I have found the regularity 
 of this ebb and flow of the aerial ocean undisturbed 
 either by storm, tempest, rain, or earthquake, both on 
 the coasts and at elevations of nearly 13,000 English 
 feet above the level of the sea. The amount of horary 
 oscillation decreases from the equator to 70° N. lat., 
 where we have very accurate observations made by 
 Bravais at Bosekop, from 0.117 in. to 0*016 in.” 
 Within the Arctic Circle however, the diurnal, for very 
 obvious reasons, dies out, or rather merges in the 
 annual oscillation. 
 
 (174.) Generally speaking, the diurnal oscillation 
 presents the phenomenon of a double maximum. The 
 epochs of the maxima are about 9 h. or 91 h. a.m., and 
 10|- h. or lOf- h. p.m., and the minima at 4 h. or 4ih, 
 p.m. and 4 h. a.m. The fact that the barometer fre- 
 quently, “ both in summer and in winter, stands higher 
 in the cold mornings and evenings than in the warmer 
 midday,” seems to have been first made matter of 
 remark by Dr. Beale in 1666. In 1682, Messrs. Des 
 
DOUBLE DIURNAL BAROMETRIC MAXIMUM. 165 
 
 Iiayes and Be Glos observed that at Goree the barometer 
 was usually lowest when the thermometer was highest, 
 that it stood higher by night than by day, and that the 
 daily depression (between the morning and evening 
 maxima) exceeded the nightly. At Surinam the same 
 phenomenon was noticed by an anonymous observer, 
 and distinctly described in 1722. Towards the middle 
 of the last century (1735-61), its existence at QuitOj in 
 the Antilles, in India, and at Sta. F6 de Bogota, was 
 severally established by Godin. The observations of 
 Humboldt as to the extreme regularity of its progres- 
 sion in equatorial America are corroborated by those of 
 Colonel Wright in Ceylon. That the double maximum 
 and minimum of its march really originates in almost 
 all cases in the manner above explained, by the ap- 
 proximate destruction of the second term in the series 
 
 (A + a) + (B — b ) . sin. (HC) + /3. sin. (2 Q+ y) + &c. 
 
 owing to the opposite march of the dry and wet ele- 
 ments of the total pressure, has been put out of doubt 
 by the calculations of Dove. Yet there are localities, 
 as for instance at Bombay, in which even in the ex- 
 pression of p, the co-efficient of the second term is so 
 small in comparison with the others as to give rise 
 to the appearance of a double maximum in the dry 
 pressure itself, and the mode in which this is accom- 
 plished is evidently referable to the more complicated 
 local relations which arise from the juxta-position of 
 land and sea under exaggerated circumstances of tem- 
 perature and radiation, giving rise to alternating sea 
 
166 
 
 METEOROLOGY. 
 
 and land breezes — one minimum of the dry pressure 
 being found to coincide with the greatest strength of 
 the sea breeze, the other with that of the land breeze, 
 and the maxima with the minima of force of the 
 wind. 
 
 (175.) If we regard only the gross pressure p + v, 
 the following table will exhibit the amount of its daily 
 fluctuations above and below the mean value, as deduced 
 from the calculations of Kamtz (ii. 254, &c.) — 
 
 Place. 
 
 Latitude. 
 
 Morning 
 
 Min. 
 
 Forenoon 
 
 Max. 
 
 Afternoon 
 
 Min. 
 
 Evening 
 
 Max. 
 
 Atlantic Ocean 
 
 0° 0’ 
 
 in. 
 
 -0.056 
 
 in. 
 
 +0.069 
 
 in. 
 
 -0.045 
 
 in. 
 
 +0.045 
 
 Pacific Ocean 
 
 0 0 
 
 -0.032 
 
 0.040 
 
 0.045 
 
 0.028 
 
 Payta 
 
 5 6 S. 
 
 +0.004 
 
 0.051 
 
 0.082 
 
 0.050 
 
 Sierra Leone 
 
 8 30 N. 
 
 -0.022 
 
 0.032 
 
 0.038 
 
 0.031 
 
 Cumana 
 
 10 28 N. 
 
 0.022 
 
 0.043 
 
 0.050 
 
 0.037 
 
 La Guayra 
 
 10 36 N. 
 
 0.023 
 
 0.054 
 
 0.048 
 
 0.029 
 
 Callao 
 
 12 3 8. 
 
 0.038 
 
 0.045 
 
 0.044 
 
 0.035 
 
 Lima 
 
 12 3 S. 
 
 0.071 
 
 0.065 
 
 0.067 
 
 0.050 
 
 Pacific Ocean 
 
 16 0 S. 
 
 0.021 
 
 0.040 
 
 0.040 
 
 0.028 
 
 Otaheite 
 
 17 29 S. 
 
 0.035 
 
 0.052 
 
 0.030 
 
 0.018 
 
 Pacific Ocean 
 
 18 0 N. 
 
 0.020 
 
 0.034 
 
 0.044 
 
 0.027 
 
 Calcutta 
 
 22 35 N. 
 
 0.017 
 
 0.052 
 
 0.038 
 
 0.018 
 
 Rio Janeiro 
 
 22 54 S. 
 
 0.036 
 
 0.040 
 
 0.040 
 
 0.030 
 
 Cairo 
 
 30 2 N. 
 
 0.008 
 
 0.035 
 
 0.055 
 
 0.030 
 
 Padua 
 
 45 24 N. 
 
 0.004 
 
 0.012 
 
 0.014 
 
 0.007 
 
 Munich 
 
 48 8 N. 
 
 0.011 
 
 0.011 
 
 0.008 
 
 0.009 
 
 Halle 
 
 51 29 N. 
 
 0.006 
 
 0.013 
 
 0.012 
 
 0.005 
 
 Abo 
 
 60 57 N. 
 
 0.009 
 
 0.002 
 
 0.005 
 
 0.008 
 
 (176.) As examples of the application of the general 
 form of expression in cosines of the sun's hour angle 
 from noon, we shall subjoin only the values obtained 
 by Kamtz by the method of least squares from the 
 
DIURNAL OSCILLATIONS ON MOUNTAINS. 167 
 
 whole series of observations recorded for three of the 
 above localities, viz., Payta, CalJao, and Padua. 
 
 For Payta. 
 
 p + v = 29*- -840 + 0 in - *050 sin. (0 + 203° 2') 
 
 + 0 -037 sin. (2 0+ 153° 43'). 
 
 For Callao. 
 
 p + v = 29 in - *824 + 0 in - *099 sin. (0+180° 590 
 + 0 ^ *036 sin. (2 0 + 171° 6'). 
 
 For Padua. 
 
 p + v = 29^ *797 +0^ *005 sin. (0+183° 46') 
 
 0*- -010 sin. (2 0+ 135° 59'). 
 
 (177.) The stations in the foregoing table are (except 
 in the cases of Munich, Halle, and Abo), at the sea 
 level. On mountain stations, or at least on such as 
 rise abruptly from that level, or from an extensive 
 plain, there exists a cause of diurnal oscillation in the 
 barometric pressure of quite a different nature from 
 that above considered. The whole vertical column of 
 air, from the sea level to the top of the atmosphere, 
 being dilated by the increase of diurnal temperature, it 
 is evident that in the hotter portion of the twenty-four 
 hours, a certain portion of the air below the cistern of 
 the barometer must be lifted above it, and vice versd for 
 the colder. The actual weight of air incumbent on the 
 mercury at a fixed altitude above the sea level must thus 
 be alternately varied in excess and defect of its mean 
 amount, and the mercurial column balancing it must 
 rise and fall accordingly. The effect of this cause 
 
168 
 
 METEOROLOGY. 
 
 (whose action is explained in art. 77, a), is easily cal- 
 culable for any given elevation and diurnal change of 
 temperature. Supposing that of the whole aerial 
 column between the sea and the station uniform, and 
 equal to the mean of the upper and lower, it is easily 
 shewn that the effect in question will attain its maxi- 
 mum value at an altitude where the barometric pressure 
 is one 2‘7182818th of that at the sea level, i. e., 
 1 1 in * -03, corresponding to about 26,100 feet, and at 
 this height the total diurnal fluctuation due to a change 
 of temperature of 30° Fahr. would amount to the very 
 considerable quantity 0 m - *672. The effect at inferior 
 elevations for 10° of diurnal oscillation of temperature 
 is calculated in the following table : — 
 
 Alt. in 
 Feet. 
 
 Diurnal 
 Oscillation 
 for 10° F. 
 
 Alt. in 
 Feet. 
 
 Diurnal 
 Oscillation 
 for 10° F. 
 
 Alt. in 
 Feet. 
 
 Diurnal 
 Oscillation 
 for 10° F. 
 
 1000 
 
 2000 
 
 3000 
 
 4000 
 
 5000 
 
 inches. 
 
 0.022 
 
 0.043 
 
 0.062 
 
 0.080 
 
 0.096 
 
 6000 
 
 7000 
 
 8000 
 
 9000 
 
 10000 
 
 inches. 
 
 0.111 
 
 0.125 
 
 0.137 
 
 0.148 
 
 0.159 
 
 11.000 
 
 12.000 
 
 13.000 
 
 14.000 
 
 15.000 
 
 inches. 
 
 0.168 
 
 0.176 
 
 0.184 
 
 0.191 
 
 0.197 
 
 These quantities, when increased in the ratio of the 
 actual diurnal changes of temperature, are quite large 
 enough at any considerable elevation to overlay and 
 mask the real diurnal oscillation, and ought therefore 
 to be applied as a reduction to the sea level, whenever 
 local circumstances are such as to render such reduction 
 safe and possible, which is seldom the case. [We cannot 
 
DIURNAL MARCH OF TEMPERATURE. 
 
 169 
 
 therefore help recommending the special investigation 
 of the laws of diurnal fluctuation at considerable alti- 
 tudes, by direct observation, and as compared with 
 those at the nearest sea level, to the attention of 
 meteorologists, as a matter hitherto somewhat unduly 
 neglected.] 
 
 Diurnal and Annual Fluctuations of Temperature, 
 and Climatological Distribution of Heat. 
 
 (178.) We have seen (arts. 11, 107) that moisture 
 in the form of visible clouds, or even in that excessively 
 divided , yet unevaporated state which is sufficient to 
 injure the transparency of the atmosphere, and which 
 must be confessed to belong to the yet unresolved 
 problems of meteorology, produces absorption of the 
 sun’s rays, and the conversion of sensible into latent 
 heat. The diurnal march of temperature, then, in the 
 general atmosphere is intimately connected with its 
 hygrometric state, and especially with its degree of 
 relative dryness, i. e., its more or less near approxima- 
 tion to a state of saturation. And for the same reason 
 that the heat of the day is mitigated by the evapora- 
 tion of the diffused moisture, so. is also the cold of night 
 by its deposition, and hence arises a phenomenon of 
 very general prevalence, viz., that the difference between 
 the daily and nightly extremes of temperature, or the 
 extent of its diurnal fluctuations, is greater in summer 
 than in the winter, or rather to speak more generally, 
 and in language applicable alike to inter and extra 
 
170 
 
 METEOKOLOGY. 
 
 tropical localities, in those seasons where the air is 
 relatively drier or moister . In fact, it is evident that 
 when the air is relatively dry, evaporation during the 
 day is more active, and a larger portion of the incident 
 heat becomes latent. On the other hand, as it is 
 necessarily the dew-point which limits (at least approxi- 
 mately) the temperature of the lowest stratum of air at 
 night (see art. 45), since in the act of condensation the 
 vapour gives out its latent heat, and therefore so long 
 as the supply is continued prevents its further depres- 
 sion; the farther removed from saturation the air is, 
 the greater depression can he effected by radiation 
 before that limit is reached. The near coincidence of 
 the dew point with the lowest nightly temperature, at 
 every season of the year, has been shewn by Anderson 
 from observations made at Kinfauns Castle during the 
 year 1815, and the calculations of Kamtz shew that 
 the difference between the daily extremes of tempera- 
 ture is universally greatest in those months of the year 
 when the relative dryness of the air is the greatest. 
 
 (179.) In India, again, where, properly speaking, 
 there cannot be said to exist a winter, the moist and 
 cloudy season is that in which the least diurnal fluctu- 
 ation of temperature occurs — a circumstance sufficient 
 of itself to shew that it is not merely to the difference 
 in the lengths of day and night, or to the low altitude 
 of the sun in winter that the phenomenon in higher 
 latitudes must be attributed, since between the tropics 
 these causes can have but little influence. The east 
 and west coasts of Ceylon exhibit in this respect a 
 
DIURNAL MARCH OF TEMPERATURE. 
 
 171 
 
 pointed contrast. At Colombo, on the western side of 
 the island, the least diurnal change of temperature 
 takes place in July, and the greatest in January, the 
 rainy season being that of the S.W. monsoon, when the 
 sun is north of the equator; while at Trincomalee, on 
 the eastern side, the reversed conditions as to moisture 
 obtain, accompanied with a corresponding reversal in 
 the extremes of temperature. 
 
 (180.) The uniformity of temperature which prevails 
 at sea, and the greater general uniformity of an insular 
 as contrasted with a continental climate, has already 
 been noticed (art. 40), and is at least partly referable 
 to the same cause, viz., the alternate conversion of 
 sensible into latent heat, and vice versa , by the evapo- 
 ration and condensation of moisture disseminated 
 through the atmosphere during day and night, in 
 addition to the causes there enumerated. In conse- 
 quence, in the neighbourhood of the sea, on an average 
 of the whole year, the twenty-four hours are unequally 
 divided into the hotter and the colder portions; that 
 is to say, those in which the temperature is above, and 
 in which below the mean — the comparative shortness 
 of the hotter portion being compensated by a greater 
 absolute elevation of temperature, and the length of 
 the colder by a less absolute depression. 
 
 (181.) The foregoing considerations sufficiently shew 
 how vain would be any attempt to conclude even an 
 average of the progression of daily temperature, a 
 priori ; setting out with a knowledge of the declination 
 of the sun and the latitude of the place, and thence 
 
172 
 
 METEOROLOGY. 
 
 calculating the amount of heat received even in a calm 
 atmosphere. Observation only can lead to any just 
 conclusion, and the general process indicated in art. 
 150 must he resorted to, leaving to subsequent theo- 
 retical enquiry the difficult (indeed at present imprac- 
 ticable) task of assigning to direct solar and terrestrial 
 radiation, moisture, and wind, their share in producing 
 the final result. As instances, however, of the kind of 
 results which are attainable in this direction, w r e shall 
 here set down the formulae for the mean diurnal tem- 
 perature, calculated by Karntz from the hourly obser- 
 vations of Chiminello at Padua, and those instituted 
 by Sir David Brewster, at Port Leith, near Edinburgh, 
 viz., for Padua — 
 
 t - 56°. 7 5 + 4°. 7 9 sin. (0 + 51°.47') + 1°.00 sin. (2 0 + 
 66°.33') + 0°.22 sin. (3 0 + 233°) 
 
 and for Fort Leith — 
 
 t = 48°.24 + 3°.03 sin. (0 + 44°. 4 3') + 0°. 43 sin. (2 0 
 + 44°.43') + 0°.14 . sin. (3 0 + 175°.11'). 
 
 (182.) It is a matter of much importance, in cases 
 where a complete and continued series of meteorological 
 observations cannot be obtained, and in sea voyages, 
 where no lengthened stay is made at any one place, to 
 ascertain the mean temperature approximately from the 
 least possible number of observations. This may be 
 accomplished in different ways, viz. — 1st , By taking 
 care to observe at those hours, or one of them, in which 
 the temperature is habitually, exactly or very near its 
 mean through the twenty-four hours, or at such hours 
 
ANNUAL MARCH OF TEMPERATURE. 173 
 
 as shall have the mean of their temperatures very 
 nearly coincident with that of the day. Such hours 
 are 4 a.m. and 4 p.m., or more conveniently 10 a.m. 
 and 10 p.m. If four observations per diem can be 
 made, these four epochs should be chosen in preference. 
 2dly , By taking the mean of the maximum and mini- 
 mum for the mean temperature. This, however, is a 
 coarse and rude approximation, as is obvious on consi- 
 dering what has been above stated, art. 180, as to the 
 greater length of time during which, at stations near 
 the sea, and still more at sea, the temperature ranges 
 below the mean than above it. Kamtz recommends 
 (from a discussion of the observations at Padua and 
 Fort Leith above mentioned) to employ the formula 
 
 m + ^ — —(5*07 6 + x) 
 
 36 
 
 where x is a variable co-efficient, fluctuating from 0*366 
 in December to 0*560 in August; and which may, for 
 the purpose in question, be taken quite near enough at 
 0.44. sin. (0 + 120°), 0 being sun’s mean longitude. 
 The mean temperature of the day may also be very 
 approximately obtained from three temperatures t , 
 if\ observed at 7 a.m., 2 p.m., and 9 p.m., by the 
 formula 
 
 t + t' + 2 t" 
 
 4 
 
 or if observed at 8 a.m., 3 p.m., and 10 p.m., from the 
 expression 
 
 7 t+7 t' + lO f 
 
 24 
 
174 
 
 METEOROLOGY. 
 
 (183.) The annual fluctuation of temperature is 
 derived from the consideration of the consecutive 
 values of the mean temperatures of each day, or of the 
 constant co-efficient A in the expression of the diurnal 
 temperatures, considered as a periodical function of 0, 
 the sun’s mean longitude ; or, if we please, of the arc 
 proportional to the time commencing from any given 
 date. For simplicity we shall suppose, however, that 
 the value 0 = 0 commences on the 1st of January, so 
 that 0 = 15° corresponds to the middle of January, 45° to 
 that of February, &c., or rather to the exact days 
 nearest the middle of each month, which divide the 
 year into 12 equal parts. The monthly mean of tem- 
 perature being obtained by taking the arithmetical 
 means of the daily ones for each month, the annual 
 formula 
 
 T = A + Bj . sin. (0 + + B 2 . sin. (2 0 + C 2 ) + &c., 
 
 will be obtained, as in art. 155. The following values 
 for a series of stations in order of latitude calculated 
 by Kamtz, will serve as examples for extra-tropical 
 latitudes : — 
 
ANNUAL MAECII OF TEMPERATURE. 
 
 175 
 
176 
 
 METEOROLOGY. 
 
 To which, as a further example, we shall add the 
 expression of the annual variation of temperature at 
 St. Petersburg, from the Correspondance Meteorologique 
 of M. Kupffer, 1848, where the terms beyond the 3d 
 order, though given in the original, are suppressed as 
 insignificant, viz. — 
 
 T = 38°*73 + 23°32 . sin. (© + 263° 42') 
 
 + 0°*89 .sin. (2 0+ 115° 27') 
 
 + 0°-39 .sin. (3 0 + 234° 31') 
 
 (184.) The general coup-d’oeil of the annual pro- 
 gression of temperature afforded by these results is not 
 a little remarkable. The values of C, upon which the 
 epochs of the maximum arid minimum and mean tem- 
 perature mainly depend, are very nearly alike, and 
 have but little reference to the latitude of the place, 
 and as we see the epochs set down (those for Cape 
 Town, whose latitude is south being reversed), all 
 agree in placing the extreme of heat and cold nearly 
 about the 26th July and the 14th January. The 
 epochs of the mean computed from the formulae offer a 
 similar agreement ; all fall within a very few days of 
 the 24th April and 21st October. A general mean of 
 the whole, which may be taken as a very near approxi- 
 mation to the law of annual temperature over at least 
 the whole of the extra-tropical northern hemisphere, 
 and probably also of the southern, may be expressed 
 thus : — 
 
 T = A + i (M ~m) . sin. (0 + 263° 54') 
 
 + -cfc (M — m ) . sin. (2 0+ 23° 46') 
 
SEMI-ANNUAL FLUCTUATION OF TEMPERATURE. 177 
 
 Where M and m are the maximum and minimum 
 respectively of the mean diurnal temperatures ( Kamtz , 
 i. 126). As the co- efficient of the second term is 
 1-1 5th that of the first, which is the precise fraction by 
 which the intensity of solar radiation fluctuates by 
 reason of the change of the sun’s distance — this might 
 almost lead to a surmise, that the semi-annual term has 
 its origin in this cause (since it is obvious that it can- 
 not have a purely local origin). In effect, if we 
 consider the simple expression, T = A + B . sin. (0 + C) 
 as varied by regarding A and B (which are evidently 
 proportional, cceteris paribus , to the force of direct solar 
 radiation) each to be variable by reason of the varying 
 proximity of the sun, and to be represented respectively 
 in general by A + a . sin. (0 + a) and B + b . sin. 
 (0 + /3) • A and /3 being still the mean values of these 
 co-efficients in a whole revolution, the expression for T 
 will become 
 
 A -fa. sin. (0 + a) + B . sin. (0 + C) + b . sin. 
 (0 + /3) . sin. (0 + C), which is reducible to the form 
 
 M + N . sin. (0 + n) 4- sin. (2 0+ p), 
 
 M, N, P, n, p, being constants. This cause, then, 
 would in fact introduce a term depending on 2 0, or 
 having a semi-annual period, into the ultimate effect of 
 the sun, and proportional to the eccentricity of the 
 earth’s orbit. We are quite ready to admit that this 
 reasoning is not very strict, but the coincidence is a 
 remarkable one, and it is rather thrown out as a surmise 
 than as a demonstration. 
 
 N 
 
178 
 
 METEOROLOGY. 
 
 (185.) Between the tropics, however, other and 
 powerful causes, having obvious reference to geogra- 
 phical situation, tend to increase the semi-annual term, 
 depending on 2 ©, and by rendering it more nearly 
 comparable to that depending on 0, disturb the regular 
 increase and decrease in a very marked manner. Not 
 only does the sun between the tropics pass twice a year 
 through the zenith of each station, but the interception 
 of his beams by cloud during the afternoon at least of 
 almost every day in the wet season, the descent of a 
 large quantity of cold rain from the upper regions of 
 the air, and its evaporation from a heated soil, all go to 
 disturb the simple law of increase and diminution of 
 heat with the sun’s meridian altitude and the length of 
 the days, which moreover vary but little in these 
 regions. Owing to these causes, then, the heat in those 
 regions near the tropics where a rainy monsoon prevails, 
 instead of continuing to increase as the sun becomes 
 more nearly vertical, so as to produce a burning sum- 
 mer, remains nearly stationary, and even in some 
 localities undergoes a slight depression, thus producing 
 a double minimum with the progress of the rains, while 
 in others, where this cause does not act, no such dupli- 
 cation takes place. 
 
 (186.) To determine with precision the mean annual 
 temperature of a place requires the accumulation of 
 many years’ observation. This is abundantly shewn 
 by comparing the results obtained in successive years 
 for a long period, wherever records exist of a depend- 
 able character, which can hardly be said to be the case, 
 
MEAN ANNUAL TEMPERATURE. 
 
 179 
 
 however, earlier than the year 1770, owing not only to 
 absence of due care in ascertaining the zero points, and 
 verifying the scales of thermometers, but also to the 
 want of sufficient attention to circumstances of expo- 
 sure, &c. Where, however, such records do exist, it is 
 found that differences to the extent of two or three 
 degrees of Fahrenheit in the means for individual years 
 from a general mean of the whole occur. Thus in a 
 series of annual temperatures deduced by Mr. Glaisher 
 from the records kept at the Eoyal Observatory at 
 Greenwich, during the 85 years elapsed from 1771 to 
 1855 (both included), we find the extremes of cold and 
 hot years to be respectively 51°. 3 and 45°. 1, differing 
 by 6°. 2 inter se, and 3°.l each from the general average. 
 So also in the series of mean temperatures for Man- 
 chester for 25 years from 1794 to 1818, derived by 
 Dalton, we find a variation of 5° F. in hot and cold 
 years ; and in a similar series for Paris, as deduced by 
 Bouvard from the records of the Observatory of that 
 city for 21 years, nearly as much. Such differences 
 might be expected when we consider the exceedingly 
 variable influence of winds and cloudy and rainy 
 seasons ; and the differences, moreover, from year to 
 year, succeed each other with great irregularity, so that 
 it becomes exceedingly difficult to form any judgment 
 as to the existence of a law of periodicity in this respect. 
 The observations of Mr. Luke Howard, indeed, in the 
 neighbourhood of London, have led him to suspect a 
 decennial period of fluctuation ; and the records of the 
 Greenwich Observatory above mentioned, shew a marked 
 
180 
 
 METEOROLOGY. 
 
 tendency to a regular increase and diminution, with a 
 period of 14 years from minimum to minimum ; but 
 these two results partly contradict each other, and, so far 
 as other similar records have been examined, no distinct 
 conclusion on the subject would appear to have been 
 arrived at. We shall not long, however, remain in 
 ignorance on this point. Multiplication of stations, in 
 which normally accurate observations are made, will 
 furnish data in 15 or 20 years fully competent to decide 
 the question ; since any cause of a general or astro- 
 nomical nature (such as that alluded to in art. 7) must 
 of necessity make its appearance on the comparison of 
 a great many stations, in the lapse of a single period, 
 quite as evidently, indeed more so, than at one and the 
 same station in the lapse of many. 
 
 (187.) As the mean annual temperature at any place 
 is a very important element in its climatological rela- 
 tions, it is desirable to point out means by which it 
 may be obtained with the least possible amount of 
 observation and registry by residents whose avocations 
 will not allow them to perform a complete series of 
 meteorological observation. From what has been said 
 (art. 184), it will easily be collected that from observa- 
 tions of the daily temperature from a week before to a 
 week after the 24th April and the 21st October, in any 
 part of the world beyond the tropics, will afford a 
 certain approximation to the temperature in question; 
 so will also a mean between the extreme temperatures 
 (similarly observed at about epochs of maximum and 
 minimum, January 14 and July 26). Another method 
 
MEAN ANNUAL TEMPERATURE. 
 
 181 
 
 consists in deadening and weakening the effect of casual 
 diurnal fluctuation by recording twice in the 24 hours, 
 at 12 hours' interval, the readings of a thermometer 
 with a long stem, having the bulb and lower part of 
 the stem packed in a tin box of dry sand or saw-dust, 
 but otherwise fairly exposed. A few days' attention 
 to such a thermometer will shew at what interval 
 beyond the hottest and coldest times of the day its 
 indications attain their maxima and minima, the means 
 of which will give very nearly indeed the mean diurnal 
 temperatures. The enclosure of a maximum and a 
 minimum self-registering thermometer in a large cask 
 of dry sand, which might be opened and read off twice 
 a year, would also probably afford a very accurate mean 
 result. 
 
 (188.) From what is said in art. 39, it is evident 
 that the temperature of the soil at some considerable 
 depth below the surface will never vary greatly from 
 the mean annual temperature of the air, and that there- 
 fore the temperature of the last-drawn portions of large 
 quantities of water, freshly drawn from deep closed 
 wells, or that of copious perennial springs, which there 
 is reason to believe do not rise from any very great 
 depths (and so bring up the higher temperature of the 
 interior of the earth), or descend from much higher 
 land in the neighbourhood, will also afford a considerable 
 approximation. At four feet deep the mean tempera- 
 ture of the soil in extra-tropical regions may be con- 
 sidered as attained about the 10th of June and the 6th 
 of December, at which times, therefore, its observation 
 
182 
 
 METEOROLOGY. 
 
 will give nearly the yearly mean temperature. Bous- 
 singault states that under the equator it is sufficient to 
 observe the temperature of the soil at that or even a 
 less depth, at any time, to obtain a very near approxi- 
 mation to this element. 
 
 (189.) As this element of all other meteorological 
 data is that which it is desirable to obtain with the 
 greatest precision, it is necessary to be on our guard 
 against receiving, as final, results so obtained. The 
 temperature of the soil is necessarily influenced by that 
 of copious rain, which brings with it the temperature 
 of the upper strata of the atmosphere, and carries it 
 rapidly down below the surface, in a very different 
 manner from that of sunshine, nocturnal radiation, or 
 aerial conduction. Where the rains are distributed 
 with tolerable equality over the year, the aberration of 
 the mean temperature of the soil from that of the air 
 from this cause is not likely to be material. But it is 
 otherwise where the reverse of this condition prevails. 
 Thus Smith found, in Congo, the temperature of a well 
 100 feet deep 73° F., being 5° below the mean tempe- 
 rature of the place of observation. Again, when the 
 earth is long covered with snow, which during its melt* 
 ing preserves a uniform temperature of 32°, and while 
 unmelted, greatly impedes the free communication of 
 heat between the air and the earth, it cannot be that 
 the same law of the downward propagation of tempera- 
 ture should be followed as if the same amount of water 
 had fallen in a liquid form. M. Kupffer has constructed 
 a series of lines analogous to Humboldt’s isothermal 
 
MEAN TEMPERATURE OF THE SOIL. 
 
 183 
 
 lines, which he terms isogeothermal lines, and which 
 connect the points at which the mean temperature of 
 the soil is constant, thus forming a series of curves for 
 0°, 5°, 10°, ... as far as 25° Cent. These are by no means 
 coincident with the isothermal lines of the same tempe- 
 ratures. Thus, for instance, the two curves for 10° C., 
 which coincide over the southern part of England, begin 
 to diverge where they enter on the continent of Europe, 
 — the isogeothermal curve deviating northwards in its 
 eastern progress, until at a point in Asia, about half 
 way between the Baikal Lake and the Caspian Sea (or 
 in lat. 50°, long. 80° E.) it meets the isotherm of 5 ° C., 
 thus indicating a difference of 5° C. = 9° F. between the 
 air and soil ; and again, at a point north-east of Peters- 
 burg, in lat. about 63°, long. 40° E., a similar encounter 
 between the isotherm of 0° (32° E.) and the isogeotherm 
 of 5° (41° E.) takes place.* It is probable, however, 
 that in most places where the soil is porous or gravelly, 
 and where well-water is not found but at some con- 
 siderable depth, the temperature of the soil at three or 
 four feet deep under an area extensively roofed over 
 and well drained around, and where no artificial tem- 
 perature is kept up (and in cities many such may be 
 found), a very exact annual temperature might be 
 obtained. 
 
 (190.) But it is rather to careful observations of the 
 temperature of the equatorial seas (according to a sug- 
 gestion of Arago) at a few feet below the surface that 
 
 * We are bound to state what we find recorded, but we must 
 confess that such results appear to us hardly credible. 
 
184 
 
 METEOROLOGY. 
 
 we should look for normal results, capable of being 
 compared from year to year with a view to bring into 
 view any secular or periodic change of mean annual 
 temperature. There are vast regions of the Pacific 
 where, “over thousands of square miles, a wonderful 
 uniformity of temperature prevails,” and where both 
 the diurnal and annual fluctuations are reduced within 
 exceedingly narrow limits. In these, therefore, the 
 accumulation of observations during voyages made with 
 instruments really dependable, and executed with really 
 scientific precautions, would very soon put us in pos- 
 session of some decisive conclusion on this most inter- 
 esting point. 
 
 (191.) The influence of the alternate annual approach 
 and recess of the sun, consequent on the eccentricity 
 of the earth’s orbit, to produce an annual fluctuation of 
 the mean temperature of the whole earth , has been 
 shewn in art. 12 to be nil. But Prof. Dove has shewn, 
 by taking at all seasons the mean of the temperatures 
 of points on its surface diametrically opposite to each 
 other, that the average temperature of the whole earth’s 
 surface in J une considerably exceeds that in December. 
 This is owing to the great excess of land in the northern 
 and of water in the southern hemisphere, which gives 
 to the general climate of the former more the character 
 of a continental, to the latter more that of an insular 
 or oceanic one (art. 40). Suppose A and a to be the 
 summer and winter average temperatures in the former, 
 and B and b in the latter. Then the summer falling 
 in June in the northern, and in December in the 
 
ISOTHERMAL LINES. 
 
 185 
 
 southern, the June temperatures in both will he A, b, 
 and their mean, or the average June temperature of the 
 
 A-f b 
 
 whole earth, — - — . Similarly the average December 
 A 
 
 a + B 
 
 temperature will be — - — , and the difference, or (June 
 
 tn t.\ -ii i. A + b a + B A -a B-6 
 
 — December) ■will be — — = — — , 
 
 A A A A 
 
 which is a positive quantity, because the fluctuation 
 A— a is (for the reason assigned) greater than B — b. 
 
 (192.) The best general idea of the distribution of 
 heat over the globe is to be gathered from a chart of 
 the isothermal lines; and as the limits of this article 
 forbid our entering into any detailed account of a sub- 
 ject which properly belongs rather to the department 
 of physical geography, we shall content ourselves with 
 referring to that given in Plate II. The curves about 
 the north pole bear no inapt resemblance (as remarked 
 by Sir David Brewster) to the isochromatic lines, or 
 coloured sphserolemniscates exhibited by polarized light 
 in a biaxal crystal, whose optic axes are inclined to 
 each other about 30°, having the pole itself almost 
 centrally situated between them, and their line of junc- 
 tion nearly coincident with that diameter of the polar 
 basin which bisects it and passes through its two great 
 outlets into the Pacific and Atlantic oceans — a most 
 remarkable feature, strongly indicative of the absence 
 of land, and of the prevalence of a materially milder 
 temperature (possibly not averaging below 15° F.) at 
 
186 
 
 METEOROLOGY. 
 
 the actual pole. Of the point or points of maximum 
 cold in the southern hemisphere we know nothing. 
 
 (193.) The general equation of the optical curves in 
 question is, 
 
 sin. & . sin. S = T. 
 
 T being a number expressing what is called in optical 
 language the order of the tint exhibited (and which 
 varies in arithmetical progression, on passing from one 
 curve to another in succession of the same colour) and 
 $, @9 the distances of any point in one and the same 
 curve from the two poles respectively. Thus in fig. 7, 
 
 D 
 
 Fig. r. 
 
 S and S' being the poles, P the middle point between 
 them, A B C D the optic equator of the polarizing 
 crystal, A P C, D P B meridians, the one passing 
 through S S', the other at right angles to it, and M N 
 any one of the isochromatic curves of the order T, we 
 
ISOTHERMAL LINES. 
 
 187 
 
 shall have S M = 0, S' M = ^. There can he no doubt 
 then, from the general resemblance of the two sets of 
 curves that supposing a mean temperature thermome- 
 trically indicated by T to prevail at any point, M, in 
 north latitude, a curve KLMNO traced by calcu- 
 lation from the equation a . sin. 0 . sin. S ~ T — r (a 
 being some certain numerical constant independent of 
 t), would approximate at least in some rude and general 
 way to the isothermal line corresponding to T. Suppose 
 this done for temperatures varying by equal therw.ometric 
 intervals and a series of curves so drawn. It is obvious, 
 then, that these curves, in respect of their magnitudes, 
 distances from their foci and the pole P, as well as in 
 their general gradations of flexure, will coincide, or 
 nearly so, with a series of isochromatic curves equidistant 
 in their orders of tint. Now, this latter series will 
 divide the meridians B P D and A P C, in a succession 
 of points distributed over them, not at equal differences 
 of distance from the pole P, nor alike in the two meri- 
 dians, but following a certain law of progression in each. 
 Let us inquire what this law is ; and to begin with the 
 meridian P D, passing through the poles : — Take X = 
 A L, the latitude of L, then, for the values of & ti corres- 
 ponding to the point L, we have & = 90°— (c + X) and 
 = 90°— (c — X) and therefore 
 T — r = sin. & . sin. (f = cos. (c + X). cos. (c — X) 
 
 = !{cos. 2 c + cos. 2 x| 
 
 or, which comes to the same thing, putting y = 90—c 
 ( = 75°, since c = 15° or thereabouts). 
 
188 
 
 METEOKOLOGY. 
 
 T — r = a (cos. X 2 — cos. y 2 ) . . . (1) 
 
 Now it is remarkable that this is precisely the form in 
 which Mayer endeavoured to express empirically the 
 decrement of temperature in proceeding from the equator 
 towards the pole, from such observations as could be 
 obtained about the middle of the last century, and which 
 has been adopted by Kirwan and most other meteoro- 
 logists since his time with various more or less successful 
 attempts to assign values to the constants a and a . cos. y 
 (regarded as a single co-efficient). M. Kamtz, who has 
 taken vast pains to combine by the method of least 
 squares, the mean temperatures on different meridians, 
 so as to afford the most probable value of the co-efficient 
 of Mayer’s formula a. cos. X 2 +/S, assigns for the meridian 
 now under discussion, running from Melville Island 
 through the interior of the American continent, as the 
 centigrade reading of the mean temperature T = 56° 77'+ 
 cos. X 2 -21°.56, which it is obvious agrees with our 
 equation (1) by a proper assumption of a and r. On the 
 prolongation of this meridian on the other side of the 
 pole, the stations are too few in number and probably 
 too loosely determined to afford any satisfactory com- 
 parison. 
 
 (194.) Let us next consider the meridian BD at right 
 angles to the former. Here we have for the point N, 
 0 = d', and a. sin. f = T —t ; but we have also cos. 0 = 
 sin. X. cos. c, X being now the latitude BN reckoned on 
 this meridian ; so that our equation becomes in this case, 
 
 cos. X 2 + tan. c*. ..(2) 
 
 T- 
 
 ■t - a. cos. 
 
 
INTERIOR AND COAST CLIMATES. 
 
 189 
 
 which again agrees in its form with Mayer’s formula. 
 Comparing this with the formula (1), it appears that the 
 co-efficients of cos. X 2 in the two meridians are to each 
 other in the proportion of 1 : cos. c 2 , or about 100 : 93. 
 The mean of the results obtained by Kamtz in the 
 northern portions of the Atlantic and Pacific Oceans, 
 compared with that similarly derived for the opposite 
 meridian, gives 100:69 for the same ratio, which at 
 least is so far satisfactory in the way of agreement, that 
 the difference lies in the right direction. It will, of 
 course, be understood that we have not the smallest 
 intention of tracing any physical analogy between the 
 two sets of curves, our only object being to point out 
 the coincidence between them (which we do not 
 remember to have seen before noticed), in respect of the 
 arithmetical progression of temperature in the one series 
 corresponding to that of chromatic sequence in the 
 other, as something different from and additional to a 
 mere general resemblance of form. 
 
 (195.) Another consequence of the general causes 
 pointed out in arts. 37, 38 of the different habitudes of 
 land and water as regards their reception and retention 
 of heat, is the general law which appears to prevail in 
 respect of the comparative severity of the winters and 
 heat of the summers in the interior of the great con- 
 tinents of the northern hemisphere and on their coasts, 
 and of the general mildness of climate on west coasts 
 as compared with east, in the extratropical latitudes. 
 The former is a very obvious result, and is strongly 
 exemplified in the interior of Eussian Asia. Thus 
 
190 
 
 METEOROLOGY. 
 
 Tobolsk, Barnaoul, and Irkutsk, with summers in 
 which the thermometer for weeks together attains 86° 
 or 88° F., have winters in which the mean tempera- 
 tures are from — 0° to + 4° F. Thus too, at Astrachan, 
 the mean summer temperature averages 70° F., allowing 
 the production of the most magnificent grapes in the 
 open air, with a mean annual temperature of only 48°, 
 that of London. At Kislar, at the mouth of the Terek, 
 in 44° N. latitude, that of the south of France, the ther- 
 mometer sometimes falls in winter to —22° F. It is to 
 Leopold Yon Buch that we owe the first notice of this 
 remarkable contrast of climates, the subject of which has 
 been extensively pursued by Humboldt, Schouw, and 
 others. The other consequence is not so obvious. Where 
 the prevalent winds (the anti-trades) blow from the south- 
 west, they carry with them an oceanic temperature and 
 an abundant supply of vapour (which, as we have seen, 
 tends to equalize the extremes of temperature) to coasts 
 having a westerly exposure, while, on the other hand, the 
 same winds arriving on eastern coasts after passing over 
 extensive continents, propagate forwards in that direction 
 the extreme climates of their interior. Again, those 
 winds which are incident on eastern coasts from the sea- 
 ward side, having mainly a north-eastern character, 
 bring with them the cold of a higher latitude. This 
 latter effect is strongly felt on the east coast of our 
 island, while the extreme mildness of the west coast of 
 Ireland and the north-west coast of Scotland equally 
 testifies to the powerful influence of the there prevalent 
 south-westerly winds. 
 
PENTHEMERAL TEMPERATURES. 
 
 191 
 
 (196.) Before quitting the subject of temperature 
 and its variations, we must notice a conclusion which 
 has been supposed to be obtained by dividing the year 
 into penthemers or portions of five days each (with one 
 of six in leap years), and calculating from extensive 
 series of observations the mean temperature of each 
 penthemer. This task has been executed by Ofverbom 
 for a series of fifty years’ observations taken at the 
 Observatory of the Academy of Sciences at Stockholm, 
 and by Brandes for a great many other European 
 stations from Petersburg to Pome. The results go to 
 indicate two rather remarkable hesitations, ot even 
 slight retrogressions in the generally regular increment 
 of temperature from winter to summer, viz., one about 
 the 12th of February, the other between the 4th and 
 14th of March, the date being later as the station lies 
 more to the south. Both would seem to be attributable 
 rather to northerly or north-easterly winds setting in 
 about those dates than to any general cause, though 
 some speculations would go to assign them a very 
 remote origin, and even to trace them up to a peri- 
 odical partial obscuration of the sun by flights of 
 meteors (!) 
 
 Of the Periodical Fluctuations in the Hygrometric 
 State of the Atmosphere, and of the Distri- 
 bution of Aqueous Vapour on a large scale. 
 
 (197.) With exception of a few very limited regions 
 in which fogs are habitually prevalent, and certain 
 
192 
 
 METEOROLOGY. 
 
 points here and there occurring in which rain is almost 
 constantly falling, the general state of the atmosphere 
 is one of more or less hygrometric dryness, so that, as 
 a rule, evaporation may be considered as going on 
 continually over the whole surface of the globe, being 
 only interrupted where that surface is during certain 
 hours of the night cooled by radiation below the dew- 
 point. During these, the earth is actually abstracting 
 moisture from the air, at all other times supplying it ; 
 but far more copiously during the day than the night. 
 Meanwhile, the very highest regions of the atmosphere 
 being from time to time drained of their moisture by 
 precipitation, there is always a demand for vapour 
 upwards, which (in the view we have taken of cloud, 
 art. 107) is no way intercepted in its ascent by the 
 existence of a region where it assumes for a while a 
 visible form, and which can only be looked upon as 
 a temporary halting place, the upper surface of the 
 cloud evaporating while the cloud itself is renewed 
 by condensation of the ascending vapour at the lower; 
 unless, indeed, the radiation from the cloud itself 
 should for a time so far lower its temperature as to 
 suspend for a while or even reverse the process. (See 
 art. 95.) 
 
 (198.) At the epoch of maximum cold, when the 
 surface of the earth is at or near the dew-point, the 
 hygrometric state of the air, to a considerable altitude, 
 is near saturation, and frequently either a stratus cloud 
 rests on the ground or exists at a much lower altitude 
 than in the day, and when this is not the case, still 
 
PERIODICAL HYGROMETRIC FLUCTUATIONS. 193 
 
 the whole column of air, by reason of the general 
 depression of temperature, is much nearer to its point 
 of saturation than in the day time. 
 
 (199.) It is the practice of meteorologists to desig- 
 nate by the expression “ humidity of the air,” the 
 degree of its approach to complete saturation with 
 vapour, and to give precision to this language by 
 attributing to that degree a numerical value, viz., the 
 ratio of the quantity of vapour actually present per 
 cubic foot, as calculated from the dew-point, or other- 
 wise determined (art. 89), to that which would exist 
 per cubic foot were the air saturated, or were the dew- 
 point identical with the actual temperature. Thus a 
 scale of degrees of humidity is formed, 1 *00 being that 
 of complete saturation, and 0 that of absolute dryness. 
 In this sense of the word it will, of course, be readily 
 understood that a low degree of “humidity” is com- 
 patible with the presence of a large quantity of aqueous 
 vapour. It is not the vapour as such (which, while it 
 exists as a gas, is, like other gases, “dry”), but its 
 readiness to be deposited in a “ wet ” state on a surface 
 but little lower in temperature, that is intended to be 
 expressed. To obviate the discordance between this 
 language and that of common parlance, the terms 
 “relative humidity” and “relative dryness” are some- 
 times used. 
 
 (200.) As a general meteorological fact, however, 
 there is not merely a want of accordance, but an actual 
 opposition between both the diurnal and annual pro- 
 gress of the “ degree of humidity ” or “ relative 
 o 
 
194 
 
 METEOROLOGY. 
 
 humidity” of the air and the “ tension of vapour” as 
 indicated by hygrometric observation — a seeming para- 
 dox, but one very easily explained. To take the case 
 in hand — the diurnal variation — we have seen that at 
 those epochs of the night when the temperature has 
 reached its lowest point, and dew is either actually 
 deposited or nearly so, the humidity is at its maximum. 
 But it is precisely at that moment that the supply of 
 vapour from the earth having been for several hours cut 
 off, or even a reverse process in progress, while yet 
 vapour has been diffusing itself into the non-saturated 
 regions aloft, and is still continuing to do so, the actual 
 amount of moisture per cubic foot is small, and is still 
 in process of diminution. This epoch is usually a little 
 before sunrise. As the day advances, the temperature 
 increases, and becomes more and more in excess of the 
 dew-point. The air, therefore, becomes relatively drier, 
 evaporation goes on more rapidly, the lower strata 
 become fuller of vapour, as measured by its tension, 
 which at length becomes such as to keep pace with the 
 upward diffusion, which now in its turn is stimulated. 
 The cloud level, or vapour-plane, rises ; and if the 
 night has been clear, the air calm, the sun powerful, 
 and the soil wet, the appearance of cumuli soon begins 
 to render visible testimony to the nature of the process 
 in progress. When the heat of the day has reached 
 its maximum, this process is in its greatest activity. 
 The “ humidity” has now reached its minimum, and the 
 evaporation, which is in the direct ratio of the tempera- 
 ture and relative dryness, its maximum. From this 
 
DIURNAL MARCH OF HUMIDITY. 
 
 195 
 
 epoch, however, the supply of vapour from below being 
 most copious, while the temperature no longer increases, 
 it is evident that the humidity must begin to increase, 
 while the tension also, for a longer or shorter time, will 
 do the same, until by the decline of the sun the increase 
 of humidity so far puts a stop to the evaporating pro- 
 cess as to render it barely competent to supply the 
 expense of upward diffusion, at which moment the 
 tension becomes a maximum, and from which it also 
 decreases, and continues to do so, the humidity increas- 
 ing, during the remainder of the twenty-four hours 
 until next sunrise, when the same cycle of causes and 
 effects will recur. 
 
 (201.) Such at least will be their succession in calm 
 and clear weather, and in a normal state of circum- 
 stances ; and as regards the generally contrary march 
 of the relative humidity as compared with that of the 
 temperature and the vapour-tension, such is really the 
 course of the phenomena. The epochs, however, and 
 their order of priority, are obviously very liable to be 
 disturbed by a variety of circumstances, among which 
 the most influential are rain, winds (especially such as 
 recur in daily periodicity, as sea and land breezes), and 
 cloud which cuts off the sunbeams from the soil, and 
 puts a stop to the increase of evaporation before the 
 temperature has attained its maximum, thereby tending 
 to bring the epoch of maximum tension towards coin- 
 cidence with that of maximum heat. We find, for 
 example, on comparison of the three elements in 
 question, as derived from six years two-hourly obser- 
 
196 
 
 METEOROLOGY. 
 
 vations at the Boyal Observatory at Greenwich (1842- 
 1847), the following results : — 
 
 Maximum. Minimum. 
 
 Temperature, 55°* 22 F. at lh. 20m. P.M. 44°* 85 F. at 4h. 10m. a.m. 
 Vapour-tension, 0*345 in. at lh. 20m. p.m. 0*303 in. at 3h. 40m. a.m. 
 Humidity, 0*938 in. at 4h. 30m. a.m. 0*753 in. at lh. 20m. p.m. 
 
 Where it should be observed that the amount of cloud 
 at Greenwich is a maximum at 0 h. 20 m. p.m., at 
 which hour 73 per cent of the sky, on a general 
 average, is covered, and a minimum at 9 h. 44 m. p.m., 
 when 60 per cent of cloud prevails, the general average 
 of the year being two-thirds cloudy. For other exem- 
 plifications of the same law, the reader is referred to the 
 table of normal results in fixed observatories at the end 
 of this article. 
 
 (202.) The annual march of humidity and vapour- 
 tension as compared with that of temperature depends 
 on the same principles, and is governed by the same 
 laws ; the humidity, however (as is also the case with 
 the diurnal cycle), being much more regular in its pro- 
 gress than the vapour-tension, and the limits between 
 which the latter element oscillates being much wider, as 
 might he expected, from the greater duration of the 
 cycle, and the consequently longer time given for the 
 causes in action to work out their full effect before 
 removal. Thus in Greenwich the annual maxima and 
 minima, and their approximate epochs, as appears from 
 the series of observations already referred to, are for the 
 
 Annual Maximum. Annual Minimum. 
 
 Temperature, 63°* 37 F. in July. 34°* 20 Jan.-Feb. 
 
 Vapour-tension, 0*466 in. in July. 0 195 in. Jan. 
 
 Humidity 0*930 in. in Jan. 0*783 in. June. 
 
DISTRIBUTION OF MOISTURE. 
 
 197 
 
 (203.) Of the general distribution of moisture 
 through the atmosphere . — Locally and temporarily, 
 nothing can be more capricious than either the hu- 
 midity or the vapour-tension, as we ascend into the 
 higher regions of the air. Meteorologists, from Saus- 
 sure and Deluc downwards, have sought in vain for 
 anything like a regular law of decrement like that 
 which at least approximately prevails respecting tem- 
 perature. Mr. Eush relates that in his sixteenth 
 ascent to the height of 19,440 feet in the Nassau 
 balloon, June 29, 1850, with Mr. Green, they traversed 
 a stratum of air 8600 feet in thickness, in which 
 absolute hygrometric dryness , the zero of vapour- 
 tension, existed. This must of course be received 
 with some reserve ; but it suffices at least to shew that 
 in regions of the globe where cloud is the rule and 
 pure sky the exception, masses of air are occasionally 
 intermingled with the generally moist atmosphere, 
 which would seem to have been all but absolutely 
 drained of their moisture, either by long sojourn in 
 the polar regions, or in the highest and coldest strata 
 of the atmosphere. Meanwhile, at the ordinary levels, 
 we know little at present of the average or climatic 
 distribution of vapour. Of some things, however, we 
 may be certain, viz., 1st , That on the open ocean, far 
 from land, the dew-point, in the day time, can never 
 be many degrees below the actual temperature of the 
 air, and at night must always be very nearly identical 
 with it. 2dly, That the mean vapour-tension in hot 
 climates must necessarily be greater than in cold. 
 
198 
 
 METEOROLOGY. 
 
 3 dly, That, cceteris paribus , the relative humidity of 
 the air must be a maximum over the sea, and a mini- 
 mum in the interior of continents, especially where 
 there is much sand, which allows the rain-water to 
 sink, and which speedily dries at the surface : or much 
 bare rock, which, never being more than superficially 
 moistened, affords no supply of vapour to the air. For 
 it is obvious that in such regions there must be less 
 evaporation for an equal incidence of sunbeams; that 
 therefore less of their heat will become latent, and 
 their efficacy in heating the air will be in consequence 
 greater, so that the temperature will rise in the day- 
 time faster than the dew-point, and that in an in- 
 creasing ratio; and, moreover, that from the very 
 combination of these causes, there will be less tendency 
 to the formation of cloud over such regions, and 
 therefore a greater amount of direct sunshine thrown 
 on the soil. Thus we have a system of mutually 
 reacting causes and consequences (no uncommon ar- 
 rangement in meteorology), all tending to exaggerate 
 both the heat of the climate and its relative dryness : 
 the only counteracting power being that of radiation, 
 both diurnal and nocturnal, but especially the latter. 
 Where, in addition to all these causes, those winds 
 which blow from warmer regions or from tropical seas, 
 before arriving over the place in question, have to 
 pass over lofty mountain ranges, and have been chilled 
 in so doing, and drained of their moisture, by the 
 precipitation of snow or rain, it may well be imagined 
 that a state of extreme relative aridity will prevail. 
 
UPWARD DIFFUSION OF MOISTURE. 
 
 199 
 
 4 thly and lastly , We may be very sure that the upper 
 regions of the atmosphere (not only as being colder, 
 and therefore incapable of retaining without deposition 
 a quantity of vapour equal to that of the lower, but 
 for the reasons assigned in art. 88) must be habitually , 
 and on a general average , both absolutely and relatively 
 drier than the lower : though the existence of cirrus 
 cloud at very high levels (certainly sometimes exceeding 
 30,000 feet) sufficiently proves that even at such alti- 
 tudes saturation with moisture occasionally takes place. 
 During the sojourn of Mr. P. Smyth on the Peak of 
 Teneriffe, the aridity of the air was found to be always 
 excessive. On one occasion at Guajara (alt. 8843 feet) 
 the depression of the dew-point below the temperature 
 of the air was observed to be no less than 54° P., and 
 on another, at Alta Yista (10,707 feet), 40°, the depres- 
 sion at the sea level being habitually about 10° in the 
 middle of the day. 
 
 (204.) In actual cloud (although in the earlier history 
 of hygrometry the fact was questioned, owing to the 
 imperfection of the hygrometers used), both common 
 sense and observation go to prove that the extreme 
 point of humidity is attained, since where water is 
 bodily present in every cubic inch of air, and refuses to 
 disappear by evaporation, a state of absolute saturation 
 must exist, just as in brine in which finely-powdered 
 salt is suspended without solution we conclude a state 
 of saline saturation. Hence we are led to some singular 
 enough conclusions with respect to the law of decre- 
 ment of humidity , as distinct from vapour- tension. 
 
200 
 
 METEOROLOGY. 
 
 (205.) In the day time, so long as the sky is cloud- 
 less over any spot, it is evident that there is no point 
 in the aerial column above it at which the dew point is 
 surpassed, so that the supply of moisture from below 
 is carried off by diffusion upwards, and it will depend 
 entirely on the copiousness of this supply, and the 
 rapidity with which it ascends into the higher regions, 
 whether, as the day advances, the vapour-tension and 
 humidity shall follow a contrary or similar progression. 
 If the supply be abundant and borne up rapidly to a 
 colder level, a cloud will be formed, and it is obvious 
 that for some time before its actual visible appearance, 
 the air in that region where it is about to be formed 
 must be gradually approaching saturation, and attain it 
 at the moment of deposition of the first molecule of 
 water in a liquid state (and here we cannot help remark- 
 ing, obiter , that it is utterly inconceivable how, under 
 such circumstances, a vesicle should be formed). From 
 the ground, then, up to the vapour-plane, wherever 
 such plane exists, whatever be the law of vapour-ten- 
 sion, the humidity (perhaps with some interruptions in 
 respect of regularity) continually increases up to 1 *000, 
 its natural limit, which it maintains through the whole 
 thickness of the cloud stratum. This level passed the 
 upper surface of the cloud performs , to all intents and 
 purposes , as regards the higher atmosphere, the office of 
 a lake or sea, being a thoroughly wet surface on which 
 that atmosphere reposes. Henceforward, therefore, the 
 law of decrement of moisture will be the same as it 
 would be over the sea itself under the same circum- 
 
MULTIPLE VAPOUR-PLANES. 
 
 201 
 
 stances of temperature and pressure. Nor does anything 
 prevent (the sun striking on and evaporating it) why a 
 second layer of cloud should not be formed again at a 
 higher level, and so on — a phenomenon, in fact, of no 
 rare occurrence. In such a case, if we take the height 
 for an abscissa, as A B, the curve of humidity will be 
 an undulating one, such as E F G H I attaining its 
 maximum, 1 *000 ( = B F or C H) at F or H, and 
 having a minimum between them as at G, while the 
 
 curve of tension P Q R S T follows a progression totally 
 different — the relation between any pair of their re- 
 spective ordinates, C H, C S, being that which subsists 
 between the temperature, tension, and humidity gene- 
 rally, a relation expressible by the equation, 
 
 V = H. f (t) 
 
 where V is the vapour-tension, H the humidity, and <p 
 
202 
 
 METEOROLOGY. 
 
 (i t ) the function of the temperature t , which expresses 
 the force of saturated vapour at that temperature (art. 92). 
 
 Dependency of Atmospheric Pressure, Tempera- 
 ture, and Moisture on the Direction of the 
 Wind. Dove’s General Views of this Depen- 
 dence. 
 
 (206.) There can he no doubt that by persevering 
 and long-continued observation, the same laws of diur- 
 nal and annual periodicity will be found to be observed 
 in the direction and force of the wind as in the other 
 meteorological elements ; but they are so much more 
 masked by what we must at present term casual and 
 accidental causes, that, except in certain great features 
 (such as have already been described, art. 58, et seq.) 
 and in certain geographical situations, they cannot 
 emerge from the mass of overlying irregularities except 
 in very long periods. The extreme mobility of the air, 
 the powerful agencies at work to set it in motion, and 
 the extensive propagation and prolonged duration of 
 movements once communicated to an elastic fluid so 
 constituted, all go to mix up, at each particular spot 
 and moment, into one common resultant, motions which 
 have originated at many very remote points, and at 
 very different epochs. Along the coasts of heated 
 continents, or even islands in tropical regions, indeed, 
 the diurnal alternation of sea and land breezes is a 
 result obvious enough of itself and confirmed by obser- 
 vation; and in the temperate zones, the approach of 
 
INFLUENCE OF WINDS. 
 
 203 
 
 the sun to their respective poles is masked by a bias in 
 the general direction of the wind towards an easterly, 
 and its recess by one towards a westerly direction, the 
 more marked the nearer the point of observation is to 
 the exterior limit of the trade winds. But as regards 
 the wind in general, it is found more advantageous to 
 abandon this point of view, and to regard it, not in its 
 remote connection with the general cause of periodicity, 
 but in its immediate relation to the other meteoro- 
 logical elements with which it stands in more obvious 
 connection. 
 
 (207.) The winds, which are originally caused by 
 the equatorial heat and generation of aqueous vapour, 
 or by extensive local agencies of the same kind else- 
 where produced, act as their transporters from place to 
 place, and as their distributors over the globe. It is, 
 therefore, very obvious that a wind blowing with any 
 degree of continuance and force from a lower to a 
 higher latitude must bring with it to the latter both 
 the superior temperature and moisture of the region it 
 has left, and vice versd. Thus in our latitude, a south- 
 west wind is warm and moist, a north-east cold and dry. 
 The excess of vapour in the former has a powerful 
 tendency to form cloud in coming into a colder climate, 
 and to be deposited in rain ; the latter arriving with a 
 low vapour- tension in a warmer region, absorbs both 
 heat and moisture, clearing the sky of cloud, and, 
 while depressing the temperature, gives that peculiar 
 “ bracing” quality which is the effect of a cold, dry air, 
 in contrast with the “relaxing” influence of moist 
 
204 
 
 METEOROLOGY. 
 
 warmth. These effects are familiar to every one, and 
 have been remarked from the earliest times. The 
 general indication thus afforded has been, however, 
 pursued into minute detail by M. Dove in his excellent 
 work entitled Meteorologische Untersuchungen (Berlin, 
 1832), in which he has succeeded in exhibiting in a 
 very distinct manner, by an extensive induction from 
 observations in almost every region of the globe, the 
 close and immediate dependence of all the three great 
 meteorological elements, temperature, moisture, and 
 atmospheric pressure, on the direction of the wind, or 
 the point of the compass from which it blows. In 
 other words, assuming Q to represent the angle which 
 that direction makes with the meridian of the place 
 (reckoned from the north or south according to the 
 denomination of the elevated pole), any one of these 
 elements, E, is found to be expressible, on an average 
 or mean value during a whole year or series of years, 
 by the equation of the form, 
 
 E = A + B x .sin. (0+0!) + B 2 . sin. (20 -f C 2 ) + &c...(a) 
 
 (208.) The mode in which a law of this kind may 
 originate is not difficult to understand. Suppose, 1 st, 
 the earth without diurnal rotation, and the sun to move 
 round it from east to west, and at any given spot (sup- 
 pose in the northern hemisphere) let a wind blow 
 direct from the south with a certain force and during 
 a certain time, this will bring over the place of obser- 
 vation the warmth and moisture of a latitude more 
 southerly (suppose) by 10°. But now suppose a wind 
 
INFLUENCE OF WINDS. 
 
 205 
 
 of the same force to blow for the same time, not from 
 the south, hut from the eastward or westward of south, 
 at an angle 0° with the meridian; the atmosphere of 
 a place 1 0° remote, measured on a great circle, will 
 he still transferred to the place, but owing to the 
 inclination of its path, only 10° x cos. & more south. 
 If, therefore, the former wind brought with it an acces- 
 sion of temperature or moisture, represented by e , this 
 will bring the accession e . cos. & proportional to the 
 difference of latitude travelled over. It may happen, 
 however, from the circumstances of the locality, that 
 the warmest or moistest region in the neighbourhood 
 may lie, not due south of the place, but in a direction 
 making an angle 90°— C with the meridian. In this 
 case, then, the extraneous temperature, or moisture so 
 induced, will obviously be represented, not simply by 
 e . cos. Q, but by e . cos. (0 + C — 90°) or e . sin. (0+ C). 
 
 (209.) The effect of the earth's diurnal rotation is 
 to cause a wind setting in from the southward to veer 
 more and more westerly the longer it has continued to 
 blow, and from the northward more easterly, so that, 
 to use M. Dove’s expression, the direction of the wind 
 belies the region from which it has travelled. The 
 wind, therefore, which really reaches the spot in ques- 
 tion from the most southern region (and which brings 
 the greatest amount of extraneous heat and moisture) 
 will not be a south wind on its arrival, but one having 
 more or less of a westerly character, according to the 
 latitude of the place and other circumstances of local 
 resistance, and vice versd for the opposite influences. 
 
206 
 
 METEOROLOGY. 
 
 In so far, then, as the great equatorial and polar system 
 of wind-currents is concerned, the general effect will 
 be represented nearly by the formula, 
 
 e . sin. (0+C') 
 
 on a mean of every season and of every direction of 
 the wijid; and if to this be added the subordinate 
 influences which may be propagated to the locality in 
 question from regions nearer at hand than the equator, 
 and which may each and all of them give rise to similar 
 effects, represented by e , sin. (Q + o'), e". sin. (Q -f c"), 
 the total effect, being the sum of all these, will, as is 
 easily seen, be reducible to a single term of the general 
 form, E. sin. + C). 
 
 (210.) The effect of any wind in heating a place 
 will evidently be proportional not merely to its excess of 
 temperature, but to the quantity of air having that excess 
 which passes over the place, and which has changed 
 its latitude, that is to say, in the absence of any infor- 
 mation as to its velocity, to the degree of frequency and 
 duration of that particular wind. The co-effleient 
 e, then, in the expression e . sin ( Q + C) is dependent 
 on this degree, which itself, in any given locality, is 
 dependent on 0, the north-east and south-west winds 
 being most frequent, and the other winds rarer, in some 
 definite relation to their duration. In other words, e 
 is a function of 0, having two maxima, viz., for ^ = 45° 
 and 225°, and two intermediate minima, not neces- 
 sarily at right angles to these, e, then may be con- 
 ceived as generally capable of expression in some such 
 
DEPENDENCE OF VAPOUR-TENSION ON WINDS. 207 
 
 form as ( e ) +/ . sin. (Q + g) -\-h. sin. (2 6 -f i), the com- 
 bination of which with sin. (0 + 45°), or sin. (6 + C), 
 will give rise to a set of terms containing the sines and 
 cosines of d and its multiples, with co-efficients depend- 
 ing on (e), /, g , etc., and which are reducible, in their 
 ultimate expression, to the general form in art. 146. 
 
 (211.) The dependence of the barometric pressure 
 on & in a similar form of expression is not so evident 
 on these principles. But it must be remembered that 
 a warm and moist atmosphere is lighter, bulk for bulk, 
 than a dry and cold one, and that as the effect of a sur- 
 face wind (at least of one of any continuance) is to 
 transfer bodily the lower strata of the atmosphere of 
 one place to another, so the barometer, apart from all 
 other causes of periodical fluctuation, will vary in inverse 
 correspondence with the temperature and moisture. 
 
 (212.) M. Dove, and after him Kamtz and others, 
 following out in greater detail this train of inquiry, 
 have come to very positive and distinct practical con- 
 clusions on all these several heads. In fact, it appears, 
 as a general law, that in the “ wind-rose,” or compass- 
 card, there are two points not far from diametrically 
 opposite each other ; the one in the neighbourhood of 
 the N. E. point, the other in that of the S. W., from 
 which when the wind blows, on the long average , both 
 the temperature and the vapour-tension have their 
 maxima and minima, the former at the ]ST. E., and the 
 latter at the S.W. The same, or nearly the same, 
 points or poles of the compass-card indicate, reversely 
 the minimum and maximum, of barometric pressure. 
 
208 
 
 METEOROLOGY. 
 
 Particular localities shew deviations from each other 
 and from the general and normal form of expression, 
 both in respect of the precise situation of these 
 “ weather-poles” on the compass-card, and in their 
 exact diametral opposition, as also in the situation of 
 the intermediate mean position. On the whole, how- 
 ever, for each locality, and for each of the three ele- 
 ments in question, it is found practicable to represent 
 its variation in terms of the azimuth Q of the direction 
 of the wind, by the expression, 
 
 E = A + Bj . sin. (Q + C x ) + B 2 • sin. (2 & 4- C 2 ) 
 
 in which C x is very nearly the same angle for all of 
 them, and in which B 2 the co-efficient of the term of 
 the second order, is found to be small in comparison of 
 B x , that of the first. And it is evident that the total 
 barometric pressure P + V, and the vapour-pressure V, 
 having both this form of expression, their difference P, 
 or the pressure of dry air, will admit of a similar one 
 by a proper determination of its co-efficients, which are 
 easily deduced from those of its component elements 
 by putting 
 
 P„ + P x . sin. (0 + C x ) + P 2 . sin. (2 0 + C 2 ) 
 
 + V 0 + V, . sin. (0 + cj + V 2 . sin. (2 0 + c 2 ) 
 
 = P'„ + P' x . sin. (0 + O',) + P' 2 . sin. (2 6 + C' 2 ) 
 
 where P' represents the mixed pressure, and the several 
 numbered and accented letters the respective co- efficients 
 of the general formula, and which, reduced by the 
 usual trigonometrical transformations, afford equations 
 by which any one set of these values may easily be 
 
DEPENDENCE ON THE WIND’S DIRECTION. 209 
 
 derived from the other two. It is evident, moreover, 
 without any calculation of this kind (as M. Dove 
 observes), that since the elastic power of the vapour has 
 its maximum at the SW. point, where the total baro- 
 metric pressure has its minimum, the dry pressure P 
 must have its minimum there also; in other words, 
 that being approximately = 180°, will be 
 
 nearly identical with C. 
 
 (213.) Pursuing the inquiry still further, M. Dove 
 finds, as indeed might be expected, that these co- 
 efficients are severally and separately, like all meteo- 
 rological local elements, periodical functions of the 
 season of the year, or of the sun’s mean longitude; 
 and he has been enabled to assign for several localities 
 their spring, summer, autumn, and winter values, his 
 conclusions having been completely established, in their 
 general expression, by all subsequent observation. 
 
 (214). It is sufficiently obvious, from the principle 
 with which we set out (art. 208), that a similar series 
 of relations ought also to subsist in the southern hemi- 
 sphere, mutatis mutandis ; that is to say, that the 
 directions of the maxima and minima, instead of NE. 
 and SW., will be SE. and NW., in conformity with 
 the general law of the winds in the two hemispheres. 
 
 (215.) As an example of the results obtained in this 
 branch of meteorological inquiry, we shall here set 
 down the values of the co-efficients in the expression 
 
 E = A + B x . sin. (0 + C x ) + etc as calculated by 
 
 Prof. Johnson from the series of meteorological obser- 
 vations made under his superintendence at the Eadcliffe 
 p 
 
210 METEOROLOGY. 
 
 Observatory at Oxford. These are ( Radcl . Ohs. 1854, 
 p. xx vi.) for the 
 
 1 
 
 A 
 
 Bi 
 
 Ci 
 
 b 2 
 
 Temperature T 
 
 48°*60 F. 
 
 2°*34 
 
 254°35 
 
 0 
 
 Dry Pressure P 
 
 29*404 inch. 
 
 0'108 inch. 
 
 75 33 
 
 0 
 
 Vapour-Press. V 
 
 0‘307 inch. 
 
 0'026inch. 
 
 259 39 
 
 0 
 
 where it will be noticed, that 180°+ 75° 33' = 255° 33', 
 and therefore, conformably to the theoretical views 
 above delivered, the dry pressure has its minimum very 
 nearly corresponding to the maximum of temperature 
 and of vapour-pressure. Whenever, as in this case, 
 which is the most common, the terms of the second 
 and higher orders, are insensible or nearly so, the co- 
 efficient B x determines the maxima and minima, so 
 that the respective values of 2 B x will express the 
 total amount of fluctuation in temperature, pressure, 
 etc., at the stations which have their origin in changes 
 of wind. 
 
 (216.) It is very easy to perceive that with this 
 dependence of the great elements of weather upon the 
 direction of the wind, the other features which stand 
 to them in the relation either of immediate consequences 
 or proximate causes, must go hand in hand — such as 
 cloud, rain, etc. Tor instance, at Karlsbad, from the 
 calculations of Eisenlohr, it appears that, during the 
 prevalence of SW. wind, 1 day out of 17.29 on an 
 average only is free from cloud, and during that of NE. 
 
DEPENDENCE ON THE WIND’S DIRECTION. 211 
 
 I out of 3*04, the intermediate winds being accompanied 
 with intermediate degrees of frequency. So also for 
 rain: 1 day out of 2*75 during SW., and one out of 
 11*92 NE. ; the minimum of rain, however, here occur- 
 ring with an E. or ENE. wind ; stormy weather 1 out 
 of 17*36 of SW., and 401*50 NE., clearly indicating 
 the influence of the headlong down-rush of the upper 
 equatorial current of the anti-trades in the manner 
 indicated (art. 62). 
 
 (217.) Not less distinctly marked is the degree of 
 frequency of each particular direction of wind in con- 
 nection with the direction itself. Out of 40 places 
 enumerated by Dove in every part of Europe in which 
 sufficiently prolonged series of observations of the 
 direction of the wind had been collected by him, 21 
 have a very large and decided predominance of days of 
 west wind, 16 of SW., 2 only of NW., and only one 
 (Kasan) SE. We have already seen (art. 83) that the 
 prevalent wind in Europe generally is WSW. or there- 
 abouts. After these, the other or inferior maximum 
 occurs at E. in 18 places, NE. in 11, N. in 5, and SE. 
 in 6, the average direction of this maximum being 
 about ENE., so that the position advanced in art. 216 
 is fully borne out by observation. 
 
 (218.) At the end of this work the reader will find 
 a table containing the mean, the maximum, and the 
 minimum values (with their epochs diurnal and annual) 
 of the principal meteorological elements obtained from 
 the data afforded by the best and most systematically 
 conducted series of observations, being for the most 
 
212 
 
 METEOKOLOGY. 
 
 part those which have been carried on since 1840, in 
 the magnetic and meteorological observations established 
 by the British, Russian, American, Belgian, and other 
 governments, and national and local institutions, on a 
 concerted system of hourly or bi-hourly observation. 
 They afford numerous and striking exemplifications of 
 the laws explained above, and clearly shew their general 
 applicability, especially as regards the contrary march, 
 both annual and diurnal, of the humidity and vapour- 
 tension; the greater range of the annual as compared 
 with the diurnal fluctuations, and the dependence of 
 the average amount of vapour present in the air, and 
 the extent of both kinds of fluctuation on the latitude. 
 It would have been easy to have covered our pages, 
 indeed to fill volumes with climatological records and 
 statements, such as the reader will find in Humboldt 
 ( Asie Centrale , vol. iii.), amassed by the diligence of 
 Mahlman ; in the more extensive collections of the 
 latter and Prof. Dove, in the 4th vol. of the Rejper - 
 torium. der PhysiJc ; and in the Reports of the Senate of 
 the University of Hew York to Congress; the Corre- 
 spondance Meteorologique of the Russian observatories, 
 &c. Hot only, however, do the limits allowed us forbid 
 the adoption of such a course, but we consider it more 
 instructive to concentrate attention upon a few carefully 
 determined and selected cases than to diffuse it over a 
 larger field of bewildering particulars. 
 
OPTICAL PHENOMEMA. 
 
 213 
 
 Optical Phenomena of Meteorology. 
 
 (219.) I. The Rainbow . — The explanation of the 
 rainbow, suggested by Roger Bacon, but only first 
 clearly made out by Newton, is so familiar an illus- 
 tration of the laws of coloured refraction in every 
 treatise on optics, that we should not have thought of 
 introducing it into this essay but for the vagueness of 
 idea and misconception which are generally prevalent 
 respecting the origin of the “ supernumerary bows,” 
 i.e., those coloured fringes which are often seen in the 
 interior of the primary rainbow, and more rarely (on 
 account of the comparative faintness of the whole 
 phenomenon) at the exterior of the secondary rainbow. 
 They have been explained by Dr. Young on his fertile 
 principle of interferences, but his explanation {Phil. 
 Trans. 1804) is so obscurely expressed, or rather indi- 
 cated, as to be hardly intelligible, which is perhaps 
 the reason why Kamtz, the most exact and industrious 
 of reporters in matters of meteorological theory, while 
 assembling all the other explanations which from time 
 to time had been put forth by Pemberton, Venturi, 
 Brandes, and others (some of them very absurd, and 
 with none of which he appears to feel satisfied), passes 
 this, the only correct one, in silence. Neither is it 
 noticed by M. Pouillet in his recent elaborate Elemens 
 de Physique, who in place of it, offers a surmise as to 
 their origin which cannot be the true one, and which 
 is refuted by an experiment of M. Babinet, which he 
 cites in illustration. Mr. Coddington, in his treatise 
 
214 
 
 METEOROLOGY. 
 
 on reflexion and refraction, explains only the Newtonian 
 Bows, his subject not extending to the phenomena of 
 interferences, while Dr. Lloyd, in his treatise on light 
 and vision, contents himself with mentioning the fact 
 of their having been explained by Dr. Young, without 
 giving the steps of the explanation. We shall not, 
 therefore, scruple to devote some small portion of our 
 allotted space to rescuing this very beautiful illustration 
 of the law of interference from unmerited neglect. 
 
 (220.) Let 0 be the angle of incidence of a solar ray 
 on the surface of a spherical drop of water (0 being 0° 
 when the ray enters at the vertex next the sun, and 
 passes diametrically through the drop, and 90° where it 
 just grazes its circumference), p the corresponding angle 
 of refraction, and (Jj the refractive index for a ray of 
 any given colour. being greatest for violet and least 
 for red rays. Then shall we have sin. 0 = ^ . sin. p, 
 and the deviation of the ray by refraction will be 0 — p. 
 If the ray be reflected internally after entering the drop, 
 it is easy to see, by tracing its course within the sphere, 
 that at each reflexion an additional deviation in the 
 same direction of 180° — 2p will take place, and at its 
 final emergence a further deviation (still in the same 
 direction) equal to that at entering or = 0 — p, so that 
 the total deviation after n reflections will amount to n . 
 180° + 20 — 2 (n + 1) p, which is a function of 0 in 
 virtue of the relation sin. 0 = il . sin. p ; (a). Now this 
 function, which is n. 180° when 0 = 0, diminishes as 0 
 increases (since ^ being nearly -|, 2 (n + 1) p is 
 necessarily greater than 2), and continues to diminish 
 
OPTICAL PHENOMENA — THE RAINBOW. 215 
 
 until it attains a minimum, when its differential vanishes, 
 or when d $ = + \) d <p, which by eliminating d <p by 
 
 combining this with the differential of equation (a) gives 
 
 . A /n + iy-V 
 
 sin. 0 = k/i 7 
 
 >+l) 2 -l 
 
 and for the case of the primary how, where n— 1, sin. Q 
 
 ,4 _ 
 
 = V — 5 — in which substituting for the exact refrac- 
 
 tive indices of the extreme red and violet rays for water, 
 we find for the red rays & = 59° 32', <p — 40° 22', and 
 A (the deviation) = 137° 36', and for the violet the cor- 
 responding values 58° 46', 39° 30', 139° 32'. When 
 the deviation is a minimum, the rays incident more and 
 more remotely from the vertex of the drop, and which, 
 up to that point, were dispersed at their emergence by 
 their change of deviation, cease to be so, and emerge 
 parallel. An eye, then, properly situated with respect 
 to the drop will receive a parallel red pencil of rays in 
 a direction 137° 36' remote from that of the sun, and 
 one of violet in a direction 139° 32' remote from it ; or 
 in other words, at the angular distances 42° 24' and 
 40° 28' respectively, from the point of the heavens 
 opposite to the sun, which are therefore the angular 
 radii of the elementary red and violet rainbows. 
 
 (221.) So far the Newtonian explanation of the bow. 
 As regards the fringes, if we put D = 180° — A ? it is 
 evident that D will represent the deviation of the 
 emergent ray, not from the direction in which the 
 sun’s rays 'proceed , but from that in which the sun is 
 
216 
 
 METEOROLOGY. 
 
 seen , and will therefore express the dispersion outwards 
 of the emergent ray from the latter direction, and will 
 he a maximum when A is a minimum. The parallel 
 pencil of rays, therefore, by which the rainbow is seen, 
 has the maximum angle of dispersion outwards from 
 the sun, and all other rays at their emergence will 
 have a less, whether their points of emergence be 
 nearer to or farther from the vertex of the drop. For 
 every such point, then, more remote from the vertex, 
 it will be possible to find a corresponding point less 
 remote, such that individual rays (not pencils) emerging 
 from both shall have the same angle of dispersion ; and 
 which, of course, shall pursue parallel directions, and 
 when incident on the eye shall be collected on* the 
 same precise point of the retina, and shall therefore be 
 in a condition to interfere with, and destroy or reinforce 
 each other, according to the difference of their total 
 paths traversed both within and without the drop, 
 before reaching the eye. 
 
 (222.) Let A B D be a section of the drop through 
 the sun (in the direction C S from the centre C). Draw 
 D E perpendicular to C S; and taking the principal 
 focus for rays refracted at the convex surface E A D, 
 let D GF be the caustic of the quadrant D A. Let 
 S Q G q, be the course of the pencil of rays which 
 emerges parallel along q M (as the drop’s contribution 
 to the rainbow), and taking any point P between A 
 and Q, draw P c H, touching the caustic in H, and 
 cutting the surface in c. Then will P c be the course 
 of the refracted ray before, and c p after reflection, and 
 
INTERNAL FRINGES OF THE RAINBOW. 217 
 
 p L its ultimate diversion on emergence. From c draw 
 c K E touching the caustic in E. This will be the 
 direction of another ray S E after refraction, and sup- 
 posing c r to be its reflected course, the incidences of 
 the rays c p, c r, on the one side of the sphere will be 
 symmetrical to those of c P, c E, on the other, and 
 therefore P S and E S (regarded as rays from c refracted 
 outwards) being parallel to each other, r 1ST and p L, 
 
 the courses of c r and c p after emergence, will also be 
 so ; and P, E will lie on opposite sides of Q, and p , r of 
 q } because as c approaches to G the point where the 
 caustic meets the sphere, H and K both do so also. 
 P and E approach and ultimately coincide at Q, and 
 p r at q, the latter being the point at which contiguous 
 rays emerge parallel. Thus, for every point of emer- 
 gence p nearer the vertex than q , another r more remote 
 
218 
 
 METEOROLOGY. 
 
 has been found, under the condition appropriate to the 
 interference of the emergent rays. 
 
 (223.) Thus we see that every ray emerging between 
 A and q will have a fellow ray emerging parallel to it 
 between q and E, and interfering with it by a difference 
 of undulations, determined by drawing p m perpen- 
 dicular to r N, and r n a circle, having c for its centre ; 
 for the difference in question (^) will be expressed by 
 
 IT r fYb 7X V 
 
 where v, v are the velocities of light in air 
 
 v v 
 
 and in water, that is, since v ' : v : : 1 : fi, by r m — . n 
 p. It is not necessary to go into any calculation of the 
 value of this; it is sufficient that it increases regularly 
 from 0 (when r and p coincide with q ) not merely 
 because both r m and n p vanish there, but because 
 at q and its neighbourhood rm:np:fi: 1 , so that the 
 parallel rays which form the rainbow have no difference 
 of phase, while as the inclination of the emergent rays 
 r N, p l, to the visual ray of the rainbow q M increases, 
 so does also their difference of phases. 
 
 (224.) The larger the drop the greater are the linear 
 magnitudes of all the elements composing its form, and 
 therefore of r m and n p, and consequently b. Hence, 
 to the same difference of angular directions between 
 the rainbow and any pair of interfering rays will cor- 
 respond a larger value of d the larger the drop, and 
 therefore a greater difference of phase and number of 
 fringes ; or, in other words, the angular breadths of the 
 successive fringes are inversely as the diameters of the 
 drops. If, then, the drops differ much in diameter, 
 
INTERNAL FRINGES OF THE RAINBOW. 219 
 
 and there be no greatly prevalent average diameter, 
 the fringes formed by one drop will confuse those by 
 another. It is only, then, when owing to some exist- 
 ing condition in the formation of the rain, there is a 
 large preponderence of drops having very nearly the 
 same diameter that these fringes will be visible. They 
 are especially well seen, and the whole phenomenon of 
 the primary bow is exhibited with peculiar distinctness, 
 when on a sunny morning the eye is held close to a 
 gossamer covered with dew (in perfectly distinct micro- 
 scopic globules of nearly equal magnitude), the back 
 being turned to the sun and the head so placed as to 
 allow his light to fall laterally on the net-work on 
 which the globules are strung like beads. Four or five 
 internal fringes may be distinctly traced within the 
 bow formed by an even undisturbed gossamer. 
 
 (225.) The angle of dispersion D being a maximum 
 for rays forming the rainbow, it is obvious that no drop 
 outside of the bow can send to the eye any ray once 
 internally reflected from the sun. Hence the greater 
 apparent illumination of the ground of the sky inside 
 of the bow. The rainbow ray is, in fact, the asymptote 
 of the exterior caustic for rays twice refracted and once 
 reflected. 
 
 (226.) In reference to the formation of a rainbow on 
 cloud or fog in the entire absence of rain (art. 93), 
 Colonel Sykes, in his paper on the Meteorology of the 
 Deccan (Phil. Trans. 1835), relates a remarkable instance 
 of one seen by him from the top of a precipice from 
 2000 to 3000 feet in perpendicular height, forming the 
 
220 
 
 METEOROLOGY. 
 
 north-west scarp of the hill fort of Hurrachandarnaghur, 
 among the Ghauts, overlooking the plains of the Concan 
 (Konkhun), densely covered with fog-cloud, rising some- 
 what above the level of the precipice, but not covering 
 it. Under these circumstances, having the sun at a 
 low elevation at his back, he says, “ A circular rainbow 
 appeared, quite perfect, of the most vivid colours, one 
 half above the level on which I stood, the other below 
 it. Shadows in distinct outline of myself, my horse, 
 and people, appeared in the centre of the circle, as in a 
 picture to which the bow formed a resplendent frame.” 
 “ From our proximity to the fog, I believe the diameter 
 of the circle at no time exceeded 50 or 60 feet. The 
 brilliant circle was accompanied with the usual outer 
 bow in fainter colours.” In the same paper, he also 
 records his observation of a white rainbow in a fog-bank 
 near Poonah, within which he was riding. “ Suddenly 
 I found myself emerge from the fog, which terminated 
 abruptly in a wall some hundred feet high. Shortly 
 after sunrise, I turned my horse’s head homewards, and 
 was surprised to discover in the mural termination of 
 the fog-bank a perfect rainbow, defined in its outline, 
 but destitute of prismatic colours.” “ Niehbuhr in his 
 Voyage to Africa, describes a white rainbow, and Mr. 
 St. John, in his Lives of Celebrated Travellers (iii. 121), 
 mentions having seen one, on the 21st May 1830, in 
 Normandy, on ‘the morning mist.’” On the other 
 hand, it should be mentioned that Mr. Smyth, in his 
 recent sojourn on the Peak of Tenerifie, with a cloud- 
 less sky and perpetual sunshine above, and with a 
 
HALOS AND CORONAS. 
 
 221 
 
 boundless sea of cloud continually extended in all 
 directions below him, makes no mention of a rainbow 
 being at any time formed upon it.* 
 
 (227.) II. Halos . — These are of two kinds : the first, 
 large circles of definite and constant diameters, one of 
 45°, the other of 92°, and which are seldom both seen 
 together. The colours are very feeble, especially of the 
 larger, which is usually almost or quite white. The 
 formation of the lesser of these, as explained by Mariotte, 
 is due to the existence of minute prisms of ice floating 
 in the air, having refracting angles of 60°, and their 
 axes turned in all possible directions. If we take a tri- 
 angular prism of glass, and turn it about in a sunbeam, 
 
 * [The external portion of a very remarkable appearance 
 observed by Mr. Cockin in Lancaster [Phil. Trans. 1780 157) 
 in a mist would seem also to have been the lower portion of a 
 colourless rainbow. I may observe here in reference to the note 
 on p. 90 (£ 92), that in this account Mr. Cockin does distinctly 
 notice, as a matter of surprise, “the little humid particles which 
 occasioned the mist, and which were floating around the bushes 
 at about half an inch distance from one another,” “where the sun 
 shone” on them. But he does not call them bubbles, and it is 
 evident that what he saw was not the watery globules themselves, 
 but the infinitesimal spark of light from each of the globules con- 
 stituting its contribution to the rainbow, which, if the focus of 
 the eye were not adjusted to its distance, might easily have been 
 dilated into an annular appearance, or a disc mistakeable for a 
 bubble. In reference to the usual want of colour in lunar and 
 fog rainbows, it may be observed that the prismatic colours are 
 not well distinguished in either very brilliant or very feeble 
 spectra. And as regards the non-formation of rainbows on 
 clouds at very great altitudes, anyhow they evidently could not 
 be so formed, the particles of the cloud being not globules, but 
 crystallized bodies.] 
 
222 
 
 METEOROLOGY. 
 
 it will refract out from one of its angles a coloured 
 beam, whose deviation from the direction of the incident 
 light varies as the prism is turned, being at first very 
 great, but diminishing until at one point of the rotation 
 the deviated beam becomes for a while stationary, and 
 then (the rotation continuing in the same direction) 
 begins again to increase. There exists, then, for every 
 refracting angle of the prism a minimum angle of devia- 
 tion, dependent on the refractive density and the angle 
 of the prism. In ice, with a refracting angle of 60° 
 this deviation is about 23° for red light, and therefore, 
 among an infinite multitude of such prisms scattered 
 through the air, a far greater number will throw out a 
 refracted beam 23° inclined to the direct ray of the 
 luminary than in any other direction, since about the 
 position of the maximum a considerable amount of 
 rotation of the prism causes but a very trifling change 
 in the direction of the refracted ray. At the angular 
 distance of 23°, then, from the apparent place of the 
 luminary, there will be a much larger percentage of 
 prisms in the visual line capable of sending a refracted 
 beam to the eye than at any other, and a dim circle 
 faintly coloured with red internally, and better defined 
 within than without, will be seen. 
 
 (228.) The halo of 92° diameter is accounted for in a 
 similar manner by refraction through the angle of 90°, 
 at which the sides of hexagonal or triangular prisms 
 intersect their basis, and which in ice gives a minimum 
 deviation for red rays of about 46°. Besides the agree- 
 ment of these angles assigned by theory with the 
 
HALOS AND CORONAS. 
 
 223 
 
 measured semidiameters of the halos, we have a direct 
 proof, in the fact observed by Arago, that their light 
 is partially polarized in a plane tangent to the circumfe- 
 rence of their circles, that they consist of refracted light. 
 The light of the rainbow, similarly examined, indicates 
 reflexion as its principal origin, being polarized in a plane 
 at right angles to the arc, or passing through the sun. 
 
 (229.) Besides these principal halos there are smaller 
 ones which are frequently seen encircling the moon, 
 often two, very rarely three, and which are sometimes 
 called coronas , a very proper distinction, their origin 
 being quite different from that of the large ones as 
 well as their colours, which are much more lively and 
 inverse as to their order, the red being outward and 
 the violet inward. When two or more are seen at once, 
 the diameter of the second is double that of the first 
 — of the third triple. But the diameter of the 
 interior corona (the unit of the scale) is not always the 
 same, varying from 2° to 4°. The succession of colours 
 is approximately that of the reflected series of thin 
 plates, and they are obviously interference fringes, 
 and as such have been very satisfactorily explained by 
 Dr. Young, who considers them to arise from the 
 interference of rays passing on either side of minute 
 globules, all (or a preponderant average) of which 
 have at the time very nearly the same size, assimilating 
 them to the colours of fine even-stapled wool or to 
 lycoperdon dusted over glass, and held between a 
 candle and the eye. Dewed glass so held often exhibits 
 similar rings, and occasionally the cornea of the eye 
 
224 
 
 METEOROLOGY. 
 
 itself becomes filmy by the diffusion over it of minute 
 particles which (such at least is our personal experi- 
 ence) exhibit round a candle two or three beautiful 
 coronas, the second of 17° 57' in diameter, of vivid 
 colours and most perfect definition. The reason why 
 coronas are seldom seen round the sun is the dazzling 
 brightness of that luminary. If its light be enfeebled by 
 reflection in water, or by a coloured glass, they are often 
 visible. Newton observed three such on one occasion 
 by this means. 
 
 (230.) Interference colours are frequently seen ir- 
 regularly distributed over cloud masses. We had the 
 satisfaction of witnessing a fine display of them from 
 the Col du Mont Cervin on the occasion of an ascent of 
 the Breithorn (Kleine Monte Rosa) in 1821, and since, 
 in cirrostratus covering the sun, on Sept. 17, 1852, 
 when the pink, blue, and green colours of a mackerel's 
 skin were visible in irregular patches. But the beauti- 
 ful phenomenon which it was our good fortune to 
 observe on the 14th July 1841, at 4h. 50m. p.m., 
 being, so far as our reading extends, unique in meteor- 
 ology, appears to merit a particular description. While 
 riding on that occasion near Hawkhurst, in Kent, with 
 a companion, the attention of both was attracted by 
 the pale well-defined silvery disc of the sun as seen 
 through a very high cloud, of a character between 
 cirro-stratus and cirro-cumulus — like a high “ mackerel 
 sky" blotted by a remarkably uniform fog. After a 
 few moments we perceived the edges of the cloud to be 
 beautifully tinged with bands of colour, not disposed in 
 
PARHELIA AND LUMINOUS ARCS 
 
 2 25 
 
 a circular form round the sun as a centre, but following 
 all the sinuosities of the outline of the cloud. The 
 colours, commencing from the white area forming its 
 interior, and proceeding outward to the edge, were — 
 white ; 2d, very pale pink ; 3 d, blue-green, a stronger 
 colour ; 4 tli (at the edge), purplish pink, considerably 
 intense ; beyond which pure blue sky. At one place a 
 5 th hand of colour, blue-green (very different from the 
 blue of the sky) formed the edge ; the line of demarca- 
 tion between this and No. 4 distinctly running out at 
 the edge so as to cut the outline of the cloud. What, 
 however, was especially remarkable, was that the same 
 fringes were observed bordering detached portions of 
 neighbouring clouds of similar character, the colours 
 having obviously no reference to more or less proximity 
 to the sun, hut depending on the thickness of the cloud 
 or the length of the path within it traversed by the 
 visible ray. After watching this phenomenon for a 
 quarter of an hour, the coloured hands grew broader 
 and the tints very strong, and a tendency to form a 
 corona about the sun was perceived. Probably with a 
 darkening glass, one or more might have been well made 
 out. It seems impossible to regard these colours other- 
 wise than as the resultants of the super-position of a 
 series of interference fringes following a regular progres- 
 sion of breadth (due to a progressively increasing size 
 of the drops) from the exterior to the interior of the 
 cloud. 
 
 (231.) III. Parhelia and Arcs of light passing 
 through the sun. — A horizontal hand of light is occa- 
 Q 
 
226 
 
 METEOROLOGY. 
 
 sionally seen to pass through the sun when at a low 
 altitude, and to he prolonged into a circle parallel to the 
 horizon. This is evidently what would result from 
 reflection on, or refraction through, the faces of innume- 
 rable ice prisms floating in 'perfectly calm air with their 
 axes vertical, but having their lateral faces disposed 
 equally in all azimuths. Minute crystals, when formed 
 by precipitation in a liquid at rest, always arrange 
 themselves with their axes parallel as they sink, which 
 may often be rendered sensible by a silky appearance 
 in the liquid produced by agitation (of which iodide of 
 lead precipitated from a dilute solution containing 
 ether affords a beautiful example). Under this condi- 
 tion, then, the dispersed light, which in the halos is 
 scattered in all planes equally, is here confined to a 
 horizontal one, resulting in a bright horizontal circle, 
 the parhelia being the intensified effects of a greater 
 condensation of the dispersed rays at the angles of 
 minimum dispersion, corresponding to the halo itself as 
 the circle does to the diffused illumination of the cloud 
 on which the halo is depicted. 
 
 (232.) Any one who considers the complicated forms 
 of snow crystals (art. 120), and the various ways in 
 which refractions and reflections, both external and 
 internal, may take place among them, bearing in mind 
 also that ice is doubly refractive , and that at the planes 
 of junction of macled crystals, phenomena of coloration 
 of an intricate nature are presented, will not be sur- 
 prised to find a great variety and complication of lumi- 
 nous arcs, more or less coloured, and intersecting one 
 
PARHELIA, LUMINOUS ARCS, AND GLORIES. 227 
 
 another in such a way as to form singular interlaced 
 patterns occasionally developed under the influence of 
 a bright sun, intense frost, and generally clear sky, on 
 the principles above explained; such, for instance, as 
 the superb exhibition witnessed by Schemer at Eome in 
 1629, and repeated in higher perfection, and with 
 fuller detail for several days in succession, at Moscow, 
 when occupied by the French army in 1812.* This 
 most striking phenomenon, which is very seldom more 
 than partially visible, consists of two brilliant halos 
 about the sun, cut diametrically across by a horizontal 
 circle continued all round the heavens, with well- 
 developed parhelia at their intersections, and a third at 
 a very large angular distance, more feeble, the intersec- 
 tions also marked with parhelia. At the summits of 
 the two inner halos, and touching them externally, 
 other circles, as it were their reflected images, pass 
 upwards and include the zenith, that which touches the 
 inner halo having a parhelion at the point of contact. 
 Circles of this description are clearly not phenomena of 
 interference, and can only admit of explanation by the 
 intervention of ice crystals. 
 
 (232, a.) Fringes or glories of light, more or less 
 coloured, are also often seen in fogs surrounding the out- 
 line of the shadow of the head or of the whole person of 
 the spectator. The inner portion of Mr. Cockin’s pheno- 
 menon referred to in the note on § 226 would seem to 
 have been of this nature — at least he refers it to his 
 own shadow. It consisted of two very regular concentric 
 elliptic hands of light surrounding the “ shadow” and 
 
228 
 
 METEOROLOGY. 
 
 separated from each other by a broad dark band : — the 
 inner, yellowish flame colour — the outer, rainbow-tinted; 
 on a base (the shorter axis of the Ellipse) about 10° or 
 12° in extent. 
 
 (233.) IV. Polarization of Shy Light , — This is a 
 very mysterious and a very beautiful phenomenon, 
 when observed by the aid of a polariscope, consisting 
 of a tourmaline plate, with a slice of Iceland crystal 
 or nitre, cut at right angles to its optic axis, and 
 applied on the side of the tourmaline farthest from the 
 eye. In a cloudless day, if the sky be explored in all 
 parts by looking through this compound plate, the 
 polarized rings will be seen developed with more or 
 less intensity in every region but that nearest the sun 
 and that most distant from it — the maximum of polari- 
 zation taking place on a zone of the sky 90° from the 
 sun, or in a great circle having the sun for one of its 
 poles. The plane of polarization, whatever the direc- 
 tion of the visual ray, passes through the sun, so that 
 the cause of polarization is evidently a reflection of the 
 sun’s light on something. The question is, on what 1 ? 
 Were the angle of maximum polarization 76°, we should 
 look to water or ice for the reflecting body, however 
 inconceivable the existence in a cloudless atmosphere 
 and a hot summer day of unevaporated molecules of 
 water. But though we were once of this opinion (art. 
 Ltght, Encycl. Metropol. § 1143), careful observation 
 has satisfied us that 90°, or thereabouts, is the correct 
 angle, and that therefore, whatever be the body on 
 which the light has been reflected, if polarized by a 
 
POLARIZATION OF SKY LIGHT. 
 
 229 
 
 single reflexion, the “polarizing angle” must be 45°, 
 and the index of refraction, which is the tangent of that 
 angle, unity ; in other words, the reflection would 
 require to be made in air upon air ! The only imagin- 
 able way in which this could happen would be at the 
 plane of contact of two portions of air differently heated, 
 such as might be supposed to occur at almost every 
 point of the atmosphere in a bright sunny day ; but 
 against this there seems to be an insuperable objection. 
 The polarization is most regular and complete, as we 
 have lately been able to satisfy ourselves under the most 
 favourable possible atmospheric conditions, after sunset, 
 in the bright twilight of a summer night, with the sun 
 some degrees below the horizon, and long after all the 
 tremors and turmoil of the air, due to irregular heating, 
 must have completely subsided. Even at midnight, 
 the moonlit sky* exhibits the same phenomenon, bear- 
 ing the same reference to the moon’s position as to that 
 of the sun by day, the black cross of a polariscope being 
 distinctly perceptible. The difficulty, therefore, of 
 conceiving the polarization as operated by a single 
 reflexion is very great. On the other hand, if effected 
 by several successive reflexions, what is to secure a 
 large majority of them being in one plane (in which 
 
 * It did so on the night of the evening referred to. This 
 was after a very hot day, and a series of very dry weather. Repeat- 
 ing the observation the next lunation after copious rains, no trace 
 of the cross or polarized rings could be anywhere discerned, and the 
 skylight, examined by a doubly refracting prism, shewed only 
 a feeble partial polarization in the most favourable position. 
 Perhaps there was unperceived cirrus. 
 
230 
 
 METEOROLOGY. 
 
 case only their polarizing effect would accumulate) ; and 
 of those which become ultimately effective, what is 
 there to determine an ultimate deviation of 90° as that 
 of the maximum h The more the subject is considered, 
 the more it will be found beset with difficulties ; and 
 its explanation, when arrived at, will probably be found 
 to carry with it that of the blue colour of the sky itself 
 and of the great quantity of light which, (whether 
 reflected, refracted, or fluorescent) it actually does send 
 down to us, and of which we confess our inability to 
 render any account less unsatisfactory than that of 
 Newton, who refers it to reflexion on thin transparent 
 particles. These cannot be air, because there can be 
 no reflexion upon air in contact with air of the same 
 density. And they cannot be water, it being impossible 
 to realize even in imagination the existence of globules 
 or bubbles of the requisite dimensions maintaining 
 themselves unevaporated for an instant, when dissemi- 
 nated through the atmosphere of a clear, dry, and sultry 
 day, when through its whole extent there is no doubt 
 of the dew-point being far below the actual temperature, 
 that is to say, under conditions where a sheet of wet 
 paper would become dry in a few minutes — over a 
 sandy desert, for instance, where rain never falls, and 
 cloud is a rarity. We may observe, too, that it is only 
 where the purity of the blue sky is most absolute that 
 the polarization is developed in its highest degree, and 
 that where there is the slightest perceptible tendency 
 to cirrus it is materially impaired. Neither is it in the 
 upper regions only that it is effected. The polarized 
 
POLARIZATION OF SKY LIGHT. 
 
 231 
 
 rings are formed, though much more feebly, and under 
 the same conditions of reference to the sun’s position 
 below the limit of the visible horizon as above it, 
 provided only the visual ray have a mile or two of air 
 to traverse in full sunshine. 
 
 (233, a.) M. Arago has shewn that there exists a 
 neutral point or point of no polarization situated in 
 the vertical passing through the sun, and at 150° or 
 155° distant from the sun. Sir D. Brewster finds this 
 angle to be variable with the sun’s altitude. When on 
 the horizon he assigns 161° for its value, and when 11 
 or 12° high 168° or 169°. M. Babinet also indicates 
 another neutral point less distinctly marked, at about 
 18^-° from above the sun when rising or setting. 
 Several other less distinctly marked “ neutral points” 
 are also stated by Sir D. Brewster to exist, and a regular 
 law indicated, according to which the polarization varies 
 for different altitudes of the sun, for which, as we see 
 no physical cause adequate to give rise to it, we must 
 refer the reader to his treatise on optics. Encyclopedia 
 Britannica , xvi., 692. 
 
 (234.) Y. Colours of Clouds . — Whether or no pure 
 air be an absorptive coloured medium, transmitting the 
 blue rays and absorbing the yellow, we may be very 
 sure that the terrestrial matter which, in the form of 
 smoke, dust, and general undefinable impurity, defiles 
 its lower regions, does exercise an absorptive action of 
 a contrary nature, absorbing the violet end of the 
 spectrum and letting pass the red. This is quite suffi- 
 cient to account for the red and golden hues of sunset, 
 
232 
 
 METEOROLOGY. 
 
 and of those clouds which are high enough to catch the 
 last rays of the declining sun after its disappearance 
 from the horizon of the spectator on the earth. The 
 red, and sometimes greenish, light thrown on the 
 moon by the earth’s atmosphere acting as a lens, and 
 concentrating on it light which has undergone its 
 absorptive effect, sufficiently indicates the nature of 
 that absorption on a general average of the whole 
 atmosphere, which, however, is sometimes singularly 
 suspended, and even changed into one of an opposite 
 character, as in the instance of the blue sun seen at 
 Bermuda from 6 a.m. to 5-L p.m. August 13, two days 
 after the great hurricane of August 10, 1831, a pheno- 
 menon which Arago has regarded as merely an effect 
 of contrast, but which, described as we happen to have 
 it very circumstantially in a letter from an eye-witness, 
 we must consider to have been an objective reality. 
 
 (235.) Professor Porbes, in a very curious paper 
 published in the Edinburgh Phil. Trans., vol. xiv., 
 has shewn that high pressure steam, in the act of 
 expansion and while still transparent, is highly ab- 
 sorptive of the violet, blue, and a portion of the green 
 rays of the spectrum; and in a second memoir in the 
 same volume, suggests that without supposing absorp- 
 tive coloration in the air itself, it may exist in a mixture 
 of air and vapour, the latter being in that peculiar 
 intermediate absorptive state which his experiments 
 have clearly shewn under certain circumstances (cer- 
 tainly very remote from atmospheric ones) to exist. 
 Whether the ruddy hues above alluded to in the lower 
 
REFRACTION, MIRAGE. 
 
 233 
 
 atmosphere be really owing to the presence of absorp- 
 tive steam, is doubtless a question which may be 
 entertained and more fully discussed; but if the sky 
 be blue by reason of absorption, that absorption must 
 be of a directly opposite character (£e., most energetic 
 on the red rays of the spectrum). [More recently it 
 has been observed by M. Carre that ammoniacal gas, 
 escaping from a pressure of two or more atmospheres 
 into the air, assumes a decided blue colour, “ similar to 
 that of the smoke of certain woods when burning.”] 
 (236.) YI. Refraction , Mirage , Lateral Refraction . — 
 [The air being a refractive medium of variable density, 
 diverts from its rectilinear course the lights of the stars 
 and other heavenly bodies, thus giving rise to the 
 phenomenon of “ Astronomical refraction.” Calculation 
 on the refractive power of air, agrees with experiment 
 in assigning 33' 0" for the mean amount of the “ hori- 
 zontal refraction,” and 5 7 //, 524 for that of a luminary 
 at 45° altitude. When the ray does not traverse the 
 whole thickness of the atmosphere, the amount of re- 
 fraction, of course, is less, but is very appretiable in 
 increasing the apparent angular elevation of any lofty 
 object seen from a lower level, and has to be allowed 
 for in all trigonometrical surveys and other operations 
 where precision is required.] When the surface of 
 the soil is greatly heated, the air in contact with 
 it is dilated, and while yet supporting the incum- 
 bent atmospheric pressure, its elasticity being in- 
 creased, does so with diminished density. In such 
 a case, rays of light coming from a distant object at 
 
234 
 
 METEOROLOGY. 
 
 great obliquities, before they can reach the ground, are 
 bent upwards by refraction, and pursue their further 
 course as if reflected from the surface of water. Thus, 
 to a spectator receiving both these reflected rays and 
 those which, diverging from the same object, reach his 
 eye directly, having never passed into the heated 
 stratum, both the object and. its reflected image will be 
 seen, the one direct, the other inverted, and joined by 
 their bases, as if rising out of a lake of still water, 
 which in arid deserts such a stratum of hot air exactly 
 resembles. Under certain circumstances, on sea coasts, 
 such a layer of hot air (drifted probably from a shore 
 of heated sand) occupies a higher level, and in it, as if 
 in a mirror suspended in the air, the inverted images 
 of ships, mast-head to mast-head with the direct, are 
 seen; and even in some rarer cases, again, another 
 repetition of the image upright above both. Singular 
 instances of this kind are described by Professor 
 Yince as seen at Eamsgate (PM. Trans, vol. lxxxix). 
 M. Biot has given an elaborate explanation of the 
 theory of such phenomena, in a paper in the Memoirs 
 of the French Academy . The accounts of arctic 
 voyages are full of extraordinary exemplifications of 
 the same general principle, where the powerful radia- 
 tion of an arctic summer sun acts on a surface loaded 
 with ice, and produces great contrasts of local tempera- 
 ture. 
 
 (237.) When a current of heated air passes through 
 a body of air generally colder, a lateral mirage is some- 
 times, though rarely, produced. Thus, on the Lake of 
 
 
LATERAL REFRACTION — AURORA BOREALIS. 235 
 
 Geneva, the image of a boat sailing on it has been seen 
 reflected on such a vertical plane of demarcation. A 
 similar effect is sometimes produced by the sun striking 
 on a wall. We remember when walking on a hot sunny 
 day under the south wall of Kensington Gardens, the 
 sun shining full upon it, to have observed the distinct 
 reflection of persons walking on the same footway. 
 A single soldier, for instance, appeared as two ; the 
 shape and colours of the uniform being visible in the 
 reflected image on the wall, which appeared invested 
 with a glassy, mirror-like coating. [Yon Humboldt has 
 recorded an instance of lateral refraction of a singular 
 nature witnessed on the Peak of Teneriffe. The image 
 of a bright star was observed to rise, move laterally, 
 descend, and resume its former position, the excursions 
 being very visible to the naked eye. A very similar 
 phenomenon is described by Proebel as having been 
 witnessed by him in one of his journeys near El Paso. — 
 (Seven Years’ Travel in Central America , p. 189.)] 
 
 Aurora Borealis. 
 
 (238.) As a meteorological agent, electro-magnetism, 
 to which department of physics this phenomenon refers 
 itself, has no claim to be regarded. So far as has 
 hitherto been proved, there is no meteorological effect 
 either as regards temperature, moisture, barometric 
 pressure, or wind, which is in the smallest perceptible 
 degree influenced by its most vivid displays. They 
 appear to be developed for the most part in a region of 
 
236 
 
 METEOROLOGY. 
 
 the atmosphere too high, and of too great rarity to affect 
 either our instruments or (except on these occasions) 
 our senses, and the only interest they offer to the 
 meteorologist otherwise than as brilliant spectacles, con- 
 sists in the evidence which they afford of the existence 
 of some matter of inconceivable tenuity no doubt, in 
 those elevated regions capable of being thrown into a 
 luminous state by the passage through it of the electric 
 discharge. Whether electricity passing through an 
 absolute vacuum be luminous, we have no means of 
 determining by experiment, since such a vacuum is 
 beyond our power to produce, though the experiments 
 of Davy would appear to indicate that beyond a 
 certain degree of tenuity (already very extreme) in 
 the gaseous or vaporous medium filling glass vessels 
 admitting of inspection of what passes, the electrical 
 discharge between the poles of a battery not only 
 begins to be less luminous, but the conduction itself is 
 impaired. But in certain phases of an auroral display, 
 indications of a very unequivocal character are afforded 
 of a distribution of material substance in forms which, 
 could they be seen under ordinary circumstances, would 
 be called clouds. We allude to those luminous bands 
 extending across the horizon, and patches of auroral 
 light which are either stationary or nearly so in the sky, 
 but which, when attentively watched, are usually per- 
 ceived to be slowly drifting southwards, and are gene- 
 rally the precursors of a more active phase of the aurora 
 when it bursts into streamers. These perhaps belong to 
 comparatively less elevated regions, and possibly in some 
 
AURORA BOREALIS. 
 
 237 
 
 cases to be identifiable with the very highest perceptible 
 cirrus cloud. But besides these, there are others pro- 
 bably at a much greater elevation, and which become 
 perceptible only when traversed by those undulating 
 pulsations of light, converging to the magnetic zenith, 
 which constitute a marked feature of certain auroras. 
 As a flash of what is called sheet-lightning (i. e. the reflec- 
 tion of an unseen flash on a distant back-ground of 
 cloud) will often disclose the outlines of intermediate 
 cloud otherwise unsuspected, so these pulsations when 
 carefully watched, will be seen to consist of waves of 
 light traversing regions of space, bounded by more or 
 less definite outlines, within which light is momentarily 
 developed by the passage of each pulse, and whose exist- 
 ence, as occupying place and having form, whatever else 
 their nature, is only revealed to us in those moments, 
 not as in the case just alluded to by their projection as 
 intercepting masses on a luminous ground, but as giving 
 off light out of their own substance. 
 
 (239.) The height of the auroral arch in that form 
 in which it stretches across the sky as a luminous band 
 at right angles to the magnetic meridian has been esti- 
 mated on several occasions from its apparent zenith 
 distance as seen from different stations, variously at 
 from 50 to 300 miles above the earth. The most 
 unexceptionable determination seems to have been that 
 of an arch observed simultaneously at Gosport, Keswick, 
 and Kewtown-Stewart in Scotland, on Oct. 17, 1819, 
 which, by the calculations of Dalton, Phil, Trans. 1828, 
 from the zenith distances observed, was 100 or 102, 
 
238 
 
 METEOROLOGY. 
 
 miles above the earth.* It has been suggested that 
 such measurements are inconclusive, on. the ground that 
 (as in the case of the rainbow) each observer sees his 
 own arch, and that no one spectator sees the same arch 
 as another. But it is obvious that this applies only to 
 an optical image reflected or refracted from some original 
 source of light elsewhere situated, whereas no one can 
 doubt that the light of the aurora originates nowhere 
 but in the place where it is seen. A planet or comet 
 might with equal justice be considered as the image 
 (formed on some unknown reflector) of some other 
 planet or comet not seen. But the want of absolute 
 fixity in the apparent place of the arc itself is a great 
 obstacle to exactness of determination, as such obser- 
 vations are rarely made at precisely noted and astro- 
 nomically corrected moments of time. There is very 
 positive evidence, however, that auroral light has been 
 seen below the clouds (as in the Polar Seas by Parry, 
 Sherer, and Ross, on Jan. 27th, 1825 ; near the chain 
 of the Rocky Mountains in North America on December 
 2, 1850, by Hardisty; and at Alford in Scotland on 
 Peb. 24, 1842, by Farquharson), nay, even habitually 
 
 * [Quite recently (March 9, 1861) a magnificent aurora 
 observed by Mr. Lowe at Nottingham, and by myself at Hawk- 
 hurst in Kent, afforded an excellent opportunity for determining 
 the height of the arch. It passed (as seen from Nottingham) over 
 Jupiter, on or near the meridian, and therefore south of the zenith, 
 at an altitude of about 52°. At or very nearly at the same time, 
 it attained at Hawkhurst (130 miles south of Nottingham) an 
 altitude of about 52° also, but to the north of the zenith. Its 
 height therefore above the ground was 83 miles.] 
 
AEROLITES, METEORS, SHOOTING STARS. 239 
 
 seen as if hovering over the Coreen Hills in the last 
 mentioned neighbourhood, at a height from 4000 to 
 6000 feet (Farquharson, Phil . Trans. 1839). 
 
 Meteors, Shooting Stars, &c. 
 
 (240.) The fall of a stone or a shower of stones from 
 the sky would seem at first sight to be quite as fairly 
 entitled to be regarded as a meteorological phenomenon 
 as that of a shower of hail; nay, hailstones are said to 
 have fallen, each containing a nucleus of iron pyrites. 
 At all events, falls of stony masses accompanied with 
 aerial detonations and luminous appearances are too 
 numerous and well authenticated to admit of doubt. 
 But there is not the smallest reason to believe that 
 such can be formed in, or anyhow collected from, dis- 
 seminated particles scattered through the air, and on 
 the contrary, so great a mass of facts go to connect 
 “shooting stars” with astronomical phenomena, that 
 we cannot hesitate in assigning them to that depart- 
 ment of physics. This, however, does not apply to a 
 class of meteors of which the great one of August 18, 
 1783, was an eminent example — great fiery globes, 
 of many hundreds, nay thousands of feet in diameter, 
 evidently not of solid materials, being of fluctuating 
 and continually varying form, and giving out most 
 intense light, many of them being compared not merely 
 to the moon in illuminating power, but to the full light 
 of day. The name Bolis or Bolide has been applied to 
 this class of phenomena. That above mentioned tra- 
 
240 
 
 METEOROLOGY. 
 
 versed the whole of Europe from the North Sea to 
 Rome, at an altitude tolerably well ascertained of about 
 50 miles, and with a velocity of from 20 to 40 miles 
 per second . Its diameter could not have been less than 
 4000 feet, having been seen under an angle equal to 
 one-third of the moon’s apparent diameter when verti- 
 cally over the eastern counties of England, from Edge- 
 worthstown in Ireland, at a distance of at least 300 
 miles. That it must have been a body of extremely 
 small density is evident from the fact of its having 
 made a sudden flexure in its course at a certain point 
 of its progress. There is so much that is enigmatical 
 about these bodies — the trains they leave behind them, 
 and which often remain long visible, and change their 
 aspect and form like luminous clouds; the immense 
 velocity of some, approaching to planetary (yet far 
 short of that of the electric spark), and the complete 
 apparent fixity of others ; and their tendency (alleged) 
 to affect the direction of the magnetic meridian (which 
 that of 1783 certainly did) — as to take them out of the 
 domain of exact science. In fact, no theory of their 
 origin, making the smallest approach to plausibility,* 
 has hitherto been advanced, though the records of the 
 observations of such meteors would fill volumes, and 
 may be found by consulting the indices of almost every 
 
 * [The most plausible is that which assimilates them (as well 
 as the slow-moving “globes of fire” mariners are in the habit of 
 talking about, as seen to approach and sometimes strike their 
 ships in violent thunderstorms), to the glow-discharge of a very 
 enormous electric reservoir of low tension, venting itself through 
 an imperfect conductor.] 
 
WHIRLWINDS, WATERSPOUTS, DUST-STORMS. 241 
 
 collection of scientific memoirs or notices, and every 
 philosophical magazine and journal. See especially the 
 reports of luminous meteors, from a.d. 338-1293, by 
 Chasles (Comptes Rendus, March 15, 1841); the great 
 collection of Chladni ; four reports by Prof. Powell to 
 the British Association, 1841-51; two by M. Quetelet 
 to the Royal Academy of Brussels, 1839 and 1842; 
 and Schmidt’s Resultate aus 10-jcihrigen Beobachtungen 
 uber Sternschuppen. 
 
 Whirlwinds, Waterspouts, Dust-storms. 
 
 « 
 
 (241.) Whenever two currents of air running in 
 opposite directions approach and graze one another, 
 eddies will arise, the air of which, forced into rotation, 
 compressed by its own impulse, and finding no escape 
 downwards or laterally, is driven upwards, and ascends 
 with a vorticose motion, which, as a necessary conse- 
 quence of the dynamical principle of the “ conservation 
 of areas,” becomes swifter the nearer the indraughted 
 air approaches the axis of the eddy. Whirlwinds so 
 generated differ widely from cyclones, inasmuch as the 
 ascensional movement is not the cause but the conse- 
 quence of the indraught of air; they are whirlwinds of 
 compression, whereas cyclones are whirlwinds of rare- 
 faction. The greater part of those violent and sudden 
 whirlwinds which are confined to limited and linear 
 tracts of land, which carry up into the air haystacks, 
 unroof houses and scatter the materials around, tear off 
 branches of trees, upset boats, and commit other local 
 
 R 
 
24 2 
 
 METEOROLOGY. 
 
 havoc, are probably of this kind. In such whirlwinds, 
 the law of the direction of rotation which the true 
 cyclone obeys (art. 72) is not necessarily observed, and 
 their rotation may be indifferently direct or retrograde, 
 according to the relative situation and direction of the 
 currents from which they originate. They are often 
 terminated by heavy falls of rain, a very obvious 
 consequence of the sudden transfer of a great mass 
 of air nearly saturated with vapour at the surface of 
 the earth to a much higher level (art. 110) ; for the same 
 reason, that is, that a fall of rain has been not unfre- 
 quently observed to follow great natural conflagrations, 
 as in the burning of forests or prairies in North America, 
 or in volcanic eruptions, nay, is even said to have been 
 brought on by fires kindled for that express purpose. 
 
 (242.) Whirlwinds of this kind taking place at sea 
 give rise to waterspouts ( trombes de mer), which are 
 very singular and sometimes dangerous phenomena. 
 Tall columns, apparently of cloud, and reaching from 
 the sea to the clouds, are seen moving majestically 
 along, often several at once, sometimes straight and 
 vertical, at others inclined and tortuous, but always 
 when approached perceived to be in rapid rotation. 
 At their bases the sea is violently agitated, and heaped 
 up with a leaping or boiling motion. Indeed water 
 would seem, at least in some cases, to be actually 
 carried up in considerable quantity, and scattered 
 round from a great height, as solid bodies are on 
 land. Hence they have been supposed by some to 
 draw water from the sea by suction , a thing obviously 
 
WHIRLWINDS, WATERSPOUTS, DUST-STORMS. 243 
 
 impossible. A notion is prevalent among seamen 
 that they may be cut asunder and dispersed by firing 
 a cannon-shot through them, an effect for which no 
 good reason can be rendered, and which certainly 
 savours of the marvellous. Appendages evidently in 
 the nature of imperfectly formed waterspouts are 
 often seen descending from the under surface of rainy 
 clouds on land (we have such a one before our eyes — 
 August 5, 1857), like long loose tapering tails floating 
 in the air, but not meeting the earth. Viewed through 
 a telescope, they are evidently seen to be hollow 
 vaporous cylinders or conoids — a light medial line or 
 axis being clearly traceable through their whole length, 
 and the rotation perceptible on attending to the 
 slight irregularities in their outline (which is very 
 definite). 
 
 (243.) During the hot season, in parched and sandy 
 tracts of flat country, whirlwinds of an opposite character 
 arise from the ascent of the violently heated air in 
 sheets or streams, determined by accidents of local 
 exposure or by any slight elevation of the soil, up 
 which gliding on all sides, the superficial air becomes 
 concentered for the moment, as we see flames arise 
 and divide themselves. When this takes place on a 
 large scale, a true cyclone may be thus generated ; 
 but if the ascensional movement be broken up into 
 numerous partial ascending columns, the wind-flaws 
 which sweep along the surface to feed them, when- 
 ever they encounter one another, will from that cir- 
 cumstance alone take on an eddying motion and 
 
244 
 
 METEOROLOGY. 
 
 generate whirlwinds, carrying up with them clouds of 
 dust. These in the African deserts, often appear as tall 
 columns of sand, revolving and advancing, suffocating 
 and actually overwhelming men and horses, and even 
 armies (as in the memorable expedition of Camhyses 
 into the Lybian desert). That the heat of a wind thus 
 loaded with sand may be insupportable, or even deadly, 
 will be easily conceived when it is remembered that a 
 sandy soil, down to several inches in depth, when 
 undisturbed, may under a tropical sun attain a tempera- 
 ture perhaps exceeding 200° F. (see art. 38), and when 
 suddenly swept up and mingled with air, itself already 
 greatly heated, will communicate its accumulated heat 
 to the general atmosphere, and impart to it, at the 
 same time, a drying power proportioned to its elevation 
 of temperature and absence of vapour. The destruc- 
 tive effects attributed to the Simoom are readily 
 explicable on this view of the causes of its heat, with- 
 out attributing to it any poisonous quality ; and the 
 Simoom itself is not improbably in the nature of a 
 cyclone so originating. 
 
 (244.) The “dust whirlwinds” of India, which are 
 very frequent in the district about Lahore and in the 
 Punjab, are sometimes stationary for a long time, some- 
 times advance with great rapidity. “ The sky is clear, 
 and not a breath moving ; presently a low bank of 
 clouds is seen in the horizon, which you are surprised 
 you did not observe before ; a few seconds have passed 
 and the cloud has half filled the hemisphere, and now 
 there is no time to lose — it is a dust storm, and helter- 
 
DUST WHIRLWINDS OF INDIA. 
 
 245 
 
 skelter every one rushes to get into the house in order 
 to escape being caught in it.” “ A broad wall of dust 
 is observed advancing rapidly, apparently composed of 
 a number of large vertical columns, each preserving its 
 respective position in the moving mass, and each 
 column having a whirling motion of its own.” “ Pre- 
 cisely the same phenomena in kind are observable in 
 all cases of dust storms, from one of a few feet in 
 diameter to those that extend for fifty miles and 
 upwards.” “ Their rotatory action seems to he con- 
 tinuous above as far as the eye can reach, and the cloud 
 of dust carried up by them, even at the height of some 
 thousand feet, to possess a gyratory motion.” “ Towards 
 the close of a storm of this kind a fall of rain suddenly 
 takes place .” — Baddeley on the Dust Storms and 
 Whirlwinds of India. As might be expected from the 
 powerful friction of the dust on the earth when dragged 
 along and in the act of leaving it, the air in these 
 columns is highly electrical. Mr. Baddeley states that 
 during the passage of dust storms, he obtained vivid 
 sparks, and in some cases streams of electricity, from a 
 wire suspended from an insulated bamboo, which would 
 instantly cease on the fall of the terminating shower. 
 
 (245.) A vast quantity of solid matter is thus carried 
 up into the higher regions of the air, and no doubt con- 
 veyed to great distances, where it sometimes falls, inter- 
 mingled with rain. Along the west coast of Africa the 
 air is frequently loaded with drifted dust, which covers 
 the decks of ships far out of sight of land. Nay, even 
 on the peak of Teneriffe, up to the height of 10,700 
 
246 
 
 METEOROLOGY. 
 
 feet, Mr. P. Smyth relates that the air during his 
 sojourn on the mountain was very frequently rendered 
 hazy by floating dust, of which there were often several 
 strata, separated by perfectly clear intervals which 
 could be distinctly traced as projected on the distant 
 mountain heights of Palma, far above the uniform 
 cloud-level (described in art. Ill) and of such density 
 as totally to obscure the sun previous to his descent 
 below the cloud level. Showers of fish, frogs, flannel 
 (matted confervoe), bread (edible fungus), infusoria, and 
 other unaccountable substances, are among the more 
 palpable evidences on record of the elevating and trans- 
 porting power of whirlwinds. 
 
 (246.) In conclusion, we subjoin a table of the mean 
 values and annual and diurnal average maxima and 
 minima, at a few select stations, of the chief meteor- 
 ological elements of temperature, pressure, vapour- 
 tension, humidity, and cloud, not as embodying any 
 general climatological results, but in illustration of 
 the main features of meteorological action laid down in 
 the foregoing pages. In the table, to save room, the 
 letters B, P, Y, T, H, C, R, are used to denote respec- 
 tively the total barometric pressure, that of dry air, and 
 that of aqueous vapour or the vapour-tension, the tem- 
 perature of the air, the degree of relative humidity, the 
 amount of cloud estimated in tenths of the hemisphere 
 covered, and the rain or other aqueous precipitation. 
 Capital letters are used to indicate the annual and 
 monthly means, corresponding to the months of annual 
 maxima and minima, whether simple or multiple, the 
 
TABLES OF METEOROLOGICAL ELEMENTS. 247 
 
 means for the whole year being entered in the column 
 marked «, and those for the maxima and minima in 
 their order of succession and their epochs, in the sub- 
 sequent columns ft 7, 5, & c . Similarly for the diurnal 
 march of the same quantities, these are represented by 
 small letters: their means (being identical with the 
 annual means) are not repeated in col. a, but their daily 
 maxima and minima, with their epochs, and hours of 
 their occurrence, reckoned from noon , occupy the sub- 
 sequent columns. In the monthly epochs, (3), (2), (3), 
 &c., represent January, February, &c. Where £ occurs, 
 whether in the indication of the month or the hour, 
 the average moment of the maximum or minimum falls 
 on or about the limit between two consecutive months 
 or hours. These epochs are, however, only approximate. 
 The barometric and vaporous pressures are in English 
 inches, the temperatures in degrees of Fahrenheit’s 
 scale, and degrees of humidity and cloud in hundredths 
 of their respective units, viz., complete saturation, and 
 a totally clouded sky. 
 
TABLE OF METEOROLOGICAL ELEMENTS. 
 
 248 
 
 METEOROLOGY. 
 
 - 
 
 O CO 
 
 T— I tH 
 
 s s 
 
 
 29-602 
 
 29-752 
 
 29-587 
 
 29-612 
 
 5S“ 
 
 CW 
 
 ® & 
 & 
 
 5X o 
 
 05 r-t 
 
 
 29-909 
 
 29-772 
 
 29-675 
 
 29-616 
 
 u> 
 
 
 CO ^ CO 
 
 
 29*627 
 
 0195 
 
 34-20 
 
 0-78 
 
 29-755 
 
 0-303 
 
 44-85 
 
 0-75 
 
 0-60 
 
 50 05 05 CO t-K 
 
 CO CO O CO H 05 1H CO CO 05 
 
 lOHHON 50 Cp CM C5 CO 
 
 05050050 05 05 0000 
 
 (N(M (M CM (M CO 
 
 iS 
 
 Cl. 
 
 ^ M HcWcWoHc* 
 
 2f <M rtrtfflo 
 
 O H 
 
 QnOCH (MOO b- 
 
 N H 04 (M H 
 
 QCL 
 
 CO CO CO uo 
 
 CM CO CO t>- ^N^CO 
 
 05 rj< CO 05 !>• Cp <M C5 l>. 
 
 05 O CO O 05 6^66 
 
 (M CO CM 50 
 
 r* 00 05 05 t>- 
 
 lOOOOMO tH 00 00 *-* CO 
 
 CO 50 Tf t>» 00 CO <p CM cp 00 
 
 05 05 0 50 0 0505000 
 
 <N <M CO (MM 50 
 
 3 
 
 CO 05 
 
 CO W (M M<5 00 O . . _ 
 
 t>» r* co cm cp co ^ :::::: 
 
 NOiOOOOtH 
 (N(N ^ CM 
 
 CO t>- O 
 
 7-1 50 CO CO 05 05 . . 
 
 co cp M <p» t>» cp : : : : : 
 
 05 05646 05 
 
 CM CM ^ CO 
 
 
 
 pqPHf>HWop3*o r. & *«5 cj 
 
 
 Royal Observatory , Greenwich. 
 Lat. 4- 51° 31' ; Long. 0° ; 
 
 Alt. 1 bb feet. 
 
 Mag. and Met. Observatory , 
 Toronto. 
 
 Lat. + 43° 40' ; Long. 79 21' W. ; 
 Alt. 108 feet above Lake Ontario. 
 
TABLES OF METEOROLOGICAL ELEMENTS. 249 
 
 CO to 
 rH r-i 
 
 x— s 50 
 
 tH tH 
 
 04 CO 
 t>. 00 
 
 l> 
 
 05 05 
 04 04 
 
 0-86 
 
 28-252 
 
 27-795 
 
 HnO 
 05 t-H 
 
 O' O O 
 
 S/ HH 
 
 29-800 
 
 29-502 
 
 0-89 
 
 28-302 
 
 27*835 
 
 
 
 05 O l> N- O !>• 
 
 CO ^ ^ iQ CO -rf 05 GO CO 
 
 CO CO 05 CO !>• tp 05 C5 CO 
 
 05 05 © © CO 05 05 0 00 0 
 
 05 CM 05 05 Tfl 
 
 to CO rH 00 O CO 
 
 (M CO H N CO r^NiOHO 
 
 C5 CO tH O 00 05 tN Hi 00 Op 
 
 wnono dob-©C5© 
 
 05 05 to 05 05 to 
 
 , He* He* 
 
 5, 05 rH 05 CO 
 
 SSESS oJ rH 05 CO 
 
 O » 05 rH © © 
 
 CO CO N CO H O O 05 >0) Tf) 
 
 ooiocooCtH qp ip co cp oo 
 
 05050005 0)05000 
 
 05 05 CO 05 05 CO 
 
 O 00 05 >0 00 CO 
 
 CO H* tO tH <35 r-H CO GO CO tH 
 
 CO 05 to 05 00 CO 00 tH 00 05 
 
 do tN o co © dor>OH*o 
 
 05 05 CO 05 05 CO 
 
 rH 00 05 
 
 CO NO CO 00 O 
 
 t>. cp t> ^ : : : : i 
 
 05 05 © © CO 00 
 
 05 05 to rH 
 
 00 00 o 
 
 h- O t>. O l» ..... 
 
 04 op h< hh qo 05 J : : : J 
 OONOHO tb 
 
 05 05 CO rtf 
 
 WPh^WHOh^ « 
 
 
 Mag . and Met. Observatory , 
 Hobart Town. 
 
 Lat. —42° 52' ; Long. 147° 25' i£. ,- 
 Alt. 105 feet. 
 
 Mag. and Met. Observatory , 
 Longwood, St. Helena. 
 Lat. - 15° 57' ; Long. 5° 41/ W. ; 
 Alt. 1765 feet . 
 
 J 
 
250 
 
 METEOROLOGY. 
 
 - 
 
 CO 
 
 r-1 
 
 17? 
 
 *c£s 
 
 29-846 
 
 29-800 
 
 29948 
 
 29 037? 
 
 S' 
 
 §3 5 
 
 10 ? 
 
 
 30-077 
 
 30*119 
 
 29*969 
 
 29-041? 
 
 U) 
 
 ^-v cv. 
 
 55 55 co 
 
 © §3© « 
 
 
 CO ^ rH 0(N»0 
 
 tH CSOi^O tD(N Ht>CO 
 
 go :^oi>l^ qvi ^ r> 
 
 <js * C 5 © cb o © 06*06 
 
 05 05 rH 05 05 CO 
 
 28- 827 
 
 0-057 
 
 2-00 
 
 0-62 
 
 29- 028 
 
 0-163 
 27*70 
 - 0-69 
 
 cS 
 
 S :SS§o §3 CO co S 
 
 8 883 S 
 
 so. 
 
 CO rH OOCOH 
 
 05 -H H* CO CO C5 00 
 
 tH j gs h< © 05 cjt>-oiq0Qp 
 O * 05 © CO © 05 05 0 05 0 
 
 CO 05 CO 05 05 
 
 29-226 
 
 0-425 
 
 63-73 
 
 0-96 
 
 29-041 
 
 0-191 
 
 39-46 
 
 0-89 
 
 
 © .McSn(MO 
 
 05 ; t> £3 ^ °° <*> . . . . ; 
 
 04^^05 CO rH 
 
 OH *0 
 
 CO *0 00 N O O 
 
 0 00 th co 00 co j : : : : 
 
 05 00 0 CO O K> 
 
 05 05 CO *H 
 
 
 CQ Ph y> E-< tCj Ph 0 s> ■** 
 
 pq p_, Eh W P3 
 
 
 Mag. and Met. Observatory , 
 Petersburg 
 
 Lat. + 59° 57' ; Long. 30° 28' E. 
 
 Mag. and Met. Observatory , 
 Catherineburg. 
 
 Lat. 4- 56° 50' ; Long. 60° 44' E. 
 
TABLES OF METEOROLOGICAL ELEMENTS. 251 
 
 ^ ^ CO 
 
 rH rH CO* 
 
 <M CM CO 
 CO 05 as rH 
 
 <M t>* ® t>* cp 
 
 6 oo 6 (no 
 
 ^ CO 
 
 00 O CO O 00 
 ip ^ 7- cp 
 05 050100 
 CM <M CM 
 
 s as >o i! c^i so as 
 
 D CM H CO hH *1“lco 00 CO CO CO 
 
 5 HOCOOCON 1 QHNO 
 
 13£S™ 
 
 QO!NO 
 
 WQO^iOO 
 
 as oo ^ co as 
 
 co o as 
 o^oco^ 
 o Tin cm »o oo 
 oc )666 
 
 CM CM tti 
 
 HCOH I 100 i—l tH 
 
 OOOiOiOCOTbcOoOON 
 
 ppfrooo^L^coHCiN 
 
 6 no^ 6 ^nn©n 6 
 
 CM CM CO CM CM CO 
 
 co r* as 
 
 OS OOOlO N 
 
 OOOINOO 
 CM CM CO rH 
 
 CO CM —I 
 
 OO (M CO CO rH O 
 1 >COH^N 9 
 NNO^OO 
 CM CM CM tH 
 
 03 P-, £> H K 2h rO ?^55>*HS 
 
 PQ Ph k* H ffl Ph »o t> -w> ^ 
 
 « s-T 
 < © 
 m ?• 
 
 * ^ 
 !> & 
 42 ^ 
 
 C3 
 
 S OS 
 
 I W H 
 
 4 § ® 
 
 rs K Ss 
 
 • wo 
 
 ^ H — 
 
 I I s 
 
 e . * u 
 §> ? 
 * i 
 
 e 
 
 ^3 
 
252 
 
 METEOROLOGY. 
 
 
 ® CO t> 
 
 tH ^ 
 
 16 
 
 
 0-61 
 
 29*936 
 
 0*293 
 
 29-957 
 
 ST 
 
 (8) 
 
 12 
 
 8i 
 
 Til 
 
 
 0.80 
 
 29-961 
 
 0-327 
 
 29-965 
 
 «• 
 
 ££§8:2:®**® £ « 
 
 O- . 
 
 3 3^£r If*© 2 jS3 ** 
 ^ Wvw/ '. t - 
 
 <50 
 
 CO t>» OHD 
 
 w»cooi>o«ooohoh 
 pt>OCD^®<ppCp03ip 
 ©OOOMOODDOibo 
 03 03 03 03 03 
 
 ffu 
 
 ia cd , |C5 rti 
 
 00 ^Hr)< +liO(NHiO 
 
 ip HipNijiawpN 
 05 O CD O P-t 05 O 05 O 
 
 03 03 03 CO 
 
 N 
 
 a. ^ 
 
 *^03 N h (NH 
 
 Cu ^ 
 
 3 333 < — ° o 
 
 CQ. 
 
 05 CD 05 c - O VO CD 
 
 '-'H t-IxOS^Ot^fMOSuO 
 (W<N^FHCpOOpcpcOCOI^ 
 
 OOO<f*0C50C5OOO 
 CO CO 00 CO 03 CD 
 
 rw 
 
 iH T* ^ , i |05 03 
 
 ° CO ir . 
 
 ® ojpoioosoiii^ 
 CO 10 H(N 
 
 8 
 
 CO OS 
 
 03 t— 1 CO Tf« O 
 
 9 «p cp <x> cp <» : : : : : 
 
 05 05 O 03 O CO 
 
 CM 03 *0 03 
 
 03 CO 
 
 00 CO rt< CO O . . . . 
 
 OO Cp (N Cl CO 05 : i I . 
 
 C5DOHON 
 03 03 Tfl 00 
 
 
 PQ Ph r*- H W Ph ^ S^ss 
 
 PP Ph >- H Ph s>-»^ 
 
 
 fci 
 
 £ $ 
 
 5 0 
 
 Q CO 
 
 Is ^ 
 
 J . £ 
 
 O B § 
 
 HO- t4 K? 
 
 5^4 
 
 e 
 
 « 05 
 
 i? + 
 
 * 3 1 
 
 tx 
 
 f i 
 
 e 
 
 & co 
 
 S* tH 
 
 £ 
 
 -3 £5 
 
 0 J § 
 
 hJ ^ ^ 
 
 ^ w b 
 
 1 r 
 .• 10 
 
 1 i 
 
 N 
 
TABLES OF METEOROLOGICAL ELEMENTS. 253 
 
 16? 
 
 S S 
 
 28549 
 
 29*681 
 
 29*736 
 
 13? 
 
 8 S 
 
 3 
 
 »c 
 
 GO 
 
 CM 
 
 29*768 
 
 29*753 
 
 P^f^^ToO ^ ^ CO 
 
 rH 
 
 VC CO Wi i.COOO^ 
 
 OOO^CON+!005C5C^ 
 
 «00H9*p^>prHCi00C 
 
 oo^o^ooooooocJoo 
 
 CM CM CO CM <M ^ 
 
 CM O t* CO 
 
 CO 05 O OS CM 00 CO O CM CM 
 
 CO tH O O ip 05 l>. CO t>- *0 
 
 05 O VO O O tH 05 O OO 
 
 CM CO CM 
 
 CM »— I GO CO <y\ 1> 
 
 r- 1 CM ” r-l 
 
 § 88888^3 
 
 i—i CO i t}( ^ 
 
 (M0005^(Mr!cocoHCoo 
 j>.vCt*^ 00»— i»O<NC0<MC0 
 QOODOCO^OOQOONO 
 CM CM t>. CM CM CO 
 
 tH O ^ 05 
 
 T* 05 GO rH VO »C CM CM t>- 
 
 GO t>- 05 J>* rH t> CO 05 0 
 
 05 OtPOOWOO OO 
 
 CM O CM 
 
 (M N lO 
 
 ^ CO O GO 05 O 
 
 vc <m co os : : : : : 
 
 GO do O O 05 
 
 CIN VO rH 
 
 »OH^ 
 
 CM CM rH rH CM CM 
 
 »>. ^ cp t* op o o : : : : : 
 
 0505000000 
 
 CM CM VO CM 
 
 ffl Cu H W as <5 s> <2 
 
 
 sS ^ 
 
 ^ VO 
 
 § * 
 
 { 2 
 
 <o ^ 
 
 S3 
 
 Q) 2 g 5 
 
 * S >3 
 
 ^ H -o 
 f g ^ 
 
 e ^ 
 
 th 
 
 « i 
 
 ^ « 
 
 Royal Observatory , Brussels. 
 Lat. + 50° 51'; Long. 4° 22' E. ; 
 Alt. 190 feet. 
 
254 
 
 METEOKOLOGY. 
 
 - 
 
 S' 
 
 2 (M «? 
 
 'w' 
 
 16 
 
 17 
 
 
 29*238 
 
 0-52 
 
 29-273 
 
 29*772 
 
 0-770 
 
 
 /—N 
 
 05 ^rH 
 
 N^ C' rH 
 
 10 
 
 4 
 
 bsj> 
 
 29-325 
 
 0-97 
 
 29-276 
 
 29*800 
 
 0*320 
 
 VM 
 
 
 c 2 Sh o’aT 
 
 *0 
 
 t-H tH tH O 
 
 H CO Tf 1C s «o >0 lO IQ 
 <^<PtHtHC0HIn 04?0 
 oiooocboboocb 
 
 04 04 04 <N 
 
 to JN- 1C >c N 
 
 CO HO^H lO CO O O GO 00 
 
 cp CO H In O N 05 co 9 OON 
 
 cs ©ho© C5«6»b66 
 
 04 N- 04 04 IN 
 
 
 ggesssSsfar 
 
 rH CO lO JO 00 rH 04 04 tH CO 
 
 N_^ws-^w 04 04 04 TH ^ 
 
 cq_ 
 
 co co ^ 
 
 CO — 1 (N C5 00 05 CO 
 
 OOONOOfNOcb 
 04 04 CO 04 O 
 
 C-. 
 
 04 CO i^CO *H 
 
 04 04iCtPH io HI — 1 O CO 04 
 
 05 05 04 GO IN 00 p 00 © C5 H 
 
 05 © 4h © o ooo^oo 
 
 04 00 04 04 GO 
 
 3 
 
 COHN 
 
 CO O CO N- U0 04 H 
 (N?NHt>cp 9 : : 
 
 omocoooo^ 
 
 04 04 H< rH 
 
 O 04 GO 
 
 © O 05 O 05 CO O . . 
 
 co 9 n f i> cp in : : : : : : 
 
 05 05 © 05 © © »0 
 
 04 04 IN IN 
 
 
 pq Ph H td o P3 ro ~ 
 
 MPh|>HEOP4'’0 « 
 
 
 £ ^ 
 
 0 So 
 
 1 ^ 
 1 ^ 
 
 § H §* 
 
 D ^ 
 
 *s 5 ^ 
 -5 PH f 
 
 § g 
 &■ + 
 
 * 3' 
 
 Mag. and Met. Observatory , 
 Bombay. 
 
 Lat. + 18° 58' ; Long. 72° 56' E. 
 
TABLES OF METEOROLOGICAL ELEMENTS. 255 
 
 S S3 
 
 -'“N 
 
 <M CM 
 
 rH rH 
 
 — ' 
 
 or 
 
 rH 
 
 V-/ 
 
 29*906 
 
 0.8 + 
 29*926 
 
 30060 
 2-9 + 
 
 27-624 
 
 S §3 
 
 E s 
 
 § 
 
 4-10* 
 
 05 
 
 05 05 05 
 
 05 "+ 05 
 
 CM CM 
 
 30-133 
 
 4-0+ 
 
 27*907 
 
 S S3 rH 
 
 
 S" ao 
 
 s ~' 
 
 29-842 
 
 0- 149 
 
 28- 77 
 
 0*45 
 
 1- 0 + 
 
 29- 897 
 
 0-334 
 
 46-00 
 
 29-953 
 
 0-224 
 
 31-23 
 
 2-6 ± 
 
 rH CO 
 
 O i^co CO 
 
 W O »0 t* 
 
 w oo 6 
 
 CM ^ 
 
 3 33 1000 ^ 
 
 c c 
 
 co" psoP 
 ✓ 
 
 30*024 
 
 0-645 
 
 73-27 
 
 0*77 
 7-8 + 
 29-960 
 
 0*381 
 
 58-33 
 
 T* I-H O ‘ 
 
 r-H rH »0 
 
 o o »b 
 
 CO l>- 
 
 28-003 
 
 0-236 
 
 82-72 
 
 083 
 
 29-929 
 
 29-573 
 
 0-356 
 
 51*53 
 
 0-61 
 
 37-25 
 
 30 051 
 29-582 
 0-469 
 53-75 
 
 41-21 
 
 27*815 
 
 27-686 
 
 0-129 
 
 60-66 
 
 0-62 
 
 
 
 
 Girard College, Philadelphia. 
 Lat. + 31° 56'; Long. 75" 12' W. 
 
 Observatory , U. S. Washington. 
 Lat. + 38° 54' ; Long. 77° 31' W. 
 
 G<l 
 
 Xh 
 
 O 
 
 CO 
 
 . 
 
 G g 
 l-t o 
 a k} 
 Q 
 
 ^ cq 
 o 
 o 
 
 + 
 
 *53 
 
 * These results, deduced from the observations made at the Imperial Observatory, Prague, differ very materially from 
 those given by Herr Karl Firtsch as resulting from the discussion of observations taken in the University Observatory. 
 — (Grundzuge einen Meteorologie fur den Horizont von Prog.) 
 
256 
 
 METEOROLOGY. 
 
 - 
 
 
 3 
 
 o 
 
 
 
 29-687 
 
 29680 
 
 K* 
 
 
 O* 
 
 t— 1 
 
 3 
 
 5sJ> 
 
 
 29-763 
 
 29-868 
 
 OJ 
 
 Jh, 3333 
 
 ^ 33 
 
 o' 
 
 
 29-601 
 
 0*229 
 
 40-5 
 
 0-81 
 
 1 - 5 + 
 
 29-627 
 
 0-218 
 
 37*0 
 
 29-764 
 
 0-211 
 
 38-4 
 
 0.76 
 
 K 
 
 © 333,3 
 
 'wX' — 
 
 3 
 
 ca 
 
 29-793 
 
 0 413 
 58-2 
 0-89 
 3 - 1 + 
 
 29-743 
 
 0-441 
 
 61-30 
 
 29-846 
 
 0-438 
 60-5 
 0 88 
 
 8 
 
 i—l O CD 00 
 
 N-^Cprhooo 
 05 05 © 00 © 05 
 Dl (M ^ <M 
 
 29-710 
 
 29*404 
 
 0-306 
 
 48-60 
 
 26-50 
 
 CO r— 1 
 
 O <M O 
 W ^ CO 05 GO ^ 
 OiOONoi 
 CN <N ^ CO 
 
 
 PQCL,>HEP$ 
 
 
 pqf^t>HWP$ 
 
 
 Office of Ordnance Survey , 
 Dublin. 
 
 Lat. 53 ° 22 ' ; Long. 6 C 5' W. ; 
 Alt. 154 feet. 
 
 A K * 
 § 
 
 £ *3 
 ° 
 
 6 g, 
 
 0 8 
 
 1 ^ 
 
 o 
 
 US 
 
 i } 
 
 * *3 
 
 £ 
 
 O 
 
 H CO 
 
 00 o 
 
 W . U 
 w g . ^ 
 
 *r « £«. 
 £ 8 * S 
 
 * 1 ? 3 
 4 125 S ^ 
 s + 
 
 * 3 
 
TABLES OF METEOROLOGICAL ELEMENTS. 257 
 
 
 
 CO 
 
 
 H 
 
 
 rH 
 
 
 *o 
 
 
 iO 
 
 
 CO 
 
 
 o 
 
 
 *0 CM 
 
 
 CO 
 
 
 05 05 
 CM CM 
 
 
 05 
 
 CM 
 
 
 
 
 
 
 JT'CM 
 
 
 05 
 
 
 I> 00 
 
 
 CM 
 
 
 CO CO 
 
 
 Si 
 
 
 I> 
 
 
 CO 
 
 
 05 05 
 
 
 05 
 
 
 CM CM 
 
 
 CM 
 
 
 
 Hl«CO CO 
 CM rH rH ^ 
 
 -^HOO 
 
 
 00 tH t>» 
 
 CO ■'f 05 uO 05 — *COOHON«i 
 9 (NhONOCOOCO(NON 
 
 05 05 O CO O O tH 05 05 O CM O 
 
 CM CM 
 
 co 
 
 CM CM 
 
 SSSScTS§cm 
 
 Hi©* >r . 
 
 rH rH CM ^ 
 rH 
 
 00 CO CO 
 
 
 CO tH rH 
 
 HWCiOONiOfN^OOCI 
 N^WOClNCiO WMHC5 
 
 ocsonooc^ocioho 
 
 CM CM 
 
 uo 
 
 CM CM »C 
 
 1QO>0 
 
 HC0 00C0»0O^) 
 
 CO Cp CM O 00 CO : 
 
 
 C5 05 O CO O O CO 
 
 • • • « 
 
 CM CM 
 
 CM 
 
 
 B 
 
 P 
 
 V 
 
 T 
 
 H 
 
 C 
 
 R 
 
 b 
 
 &. S> 
 
 
 
 .rs 
 
 
 
 
 
 
 
 o 
 
 *3 
 
 
 
 
 s> 
 
 
 
 
 
 o 
 
 
 
 «o 
 
 rH 
 
 
 
 * t 
 
 © 
 
 st 
 
 
 P o 
 
 <o H 
 g co 
 
 i 
 
 S 
 
 co 
 
 
 e os 
 H 
 
 •3 
 
 rH 
 
 CM 
 
 
 •g s 
 
 b 
 
 CO 
 
 
 
 
 
 
 
 
 iO 
 
 
 
 
 
 
 
 
 C3 
 
 
 
 S3 
 
 
 
258 
 
 METEOROLOGY. 
 
 (247.) The student who wishes to obtain a deeper 
 insight into the subject of Meteorology than can be 
 conveyed in the limited space we can devote to it, 
 will find ample information in the following works, 
 which however form only a small portion of the im- 
 mense literature of the subject — 
 
 ^Epinus de distributions Caloris. 
 
 Albany Institute. Annual reports of its Regents to the Senate — 
 Do., Report of the Committee for Term Observations, 
 trans. ii. 
 
 Anderson . Description of an Atmometer, Ed. Phil. Jour., ii. 64. 
 Annales de l’Observatoire Physique Centrale de Russie, publics 
 par l’ordre de sa Majesty Nicholas I. 
 
 Annuaire Magnetique et Meteorol. du Corps des Ingenieurs des 
 Mines de Russie. 
 
 Apjohn. Theory of the Moist Bulb Hygrometer, Edin. Phil. 
 Trans, xvii. 
 
 Arago. Notices Scientifiques, Annuaire du Bureau des Long. 
 Paris — 1824 (various Meteorol. Notices) — 1826, Do. — 1828, 
 Rayonnement Nocturne — 1833, Influence de la Lune — 1834, 
 Etat Thermom. du Globe Terrestre — 1835, Puits Artesiens 
 — 1838, Sur le Tonnerre. 
 
 Atkinson. Refraction and Decrement of Temperature, Mem. 
 Ast. Soc. ii. 
 
 Bacon. F. de Ventis, 1664. 
 
 Baddeley. On Dust Whirlwinds and Cyclones in India. 
 Beccaria. Dell’s Elettricita Atmosferica. 
 
 Beechey, (Capt.) Narrative of the Voyage of the Blossom to the 
 Pacific and Behring’s Straits, 1825-6-7-8, vol. ii., Meteoro- 
 logical Journal. 
 
 Benzenberg. Die Sternschuppen. 
 
 Biot. On Mirage and unusual Refraction, Mem. de TAcad., 1809. 
 Birt. Tabulae Anemometricae, and Anemologicae, reports to the 
 British Assoc, on Atmospheric Waves. 
 
 Blodget. Climatology of the United States, London, 1857, 
 (Trubner and Co.) 
 
CATALOGUE OF METEOROLOGICAL AUTHORITIES. 259 
 
 Bouvard. Influence de la Lune sur l’Atmosph. Tem. ; Corr. 
 Math, et Phys. de 1’Obs. de Bruxelles, viii. 
 
 Bravais and Martin. Comparaisons Barom. faites dans le Nord 
 de l’Europe, Mem. Acad. Brux., xiv. 
 
 Brewster (Sir D.) On the Mean Temperature of the Globe, 
 Edin. Phil. Trans, ix. — On the Distribution of Heat in the 
 Arctic Regions, Do. — Results of Therm. Observations at 
 Leith Fort, Do. x. 
 
 Buist. Catalogue of Indian Hailstones and Meteors — Provisional 
 Report on the Met. Obs. at Colaba, Bombay, 1844. 
 
 Cacciatore. De Redigendis ad Unicam Seriem Comparabilem 
 Observationibus Met., Palermo, 1832 — Lettera sulle Osser- 
 vazione Meteor., Palermo, 1825. 
 
 Carrel. Obs. Met. faites a Aoste. Bibl. U. de Geneve, 1842. 
 
 Castellani. Richerche sull’ Aumento delle Pioggie, Turin, 1848. 
 
 Cavallo. Atmosph. Electricity, Ph. Tr., 1776, 1777. 
 
 Chladni. Ueber Feuermeteore — Nouveau Catalogue des Chutes 
 de Pierres, ou de Fer, des Poussieres, &c. &c. — Annuaire du 
 B. des Long. Par., 1825. 
 
 Colebroolc. Abstracts of Capt. Webb’s Obs. on the Himalayas, 
 Jour. R. I., vi. 
 
 Cordier. On Temperature of Interior of the Earth, Mem. Acad 
 Sci., 1827. — (Transl. Ed. P. J., Nos. 10, 11.) 
 
 Correspondence Met. de l’Obs. Centrale Physique de Russie. 
 
 Cotte. Meteorologie, Paris, 1774 — General Results and Axioms, 
 Jour, de Phys. xliv. xlv. 
 
 Qrosse. Account of an Apparatus for Ascertaining and Collecting 
 the Electricity of the Atmosphere. 
 
 D'Alembert. Sur la Cause Generate des Yentes, Berl. 1747. 
 
 Dalton. On Rain and Dew, Manchester Mem. v. — On the 
 Constitution of Mixed Gases, Do. — Met. Obs. and Essays, 
 Lond. 1793 — On Constitution of the Atm., Phil. Tr., 1826 — 
 — On height of Aurora Borealis, Ph. Tr., 1828. 
 
 Daniell. Meteorological Essays — On the Constitution of the 
 Atmosphere. 
 
 Darwin. Ph. Tr., 1788 — (First suggests the Self-cooling of Air 
 by Ascending to a Higher Level.) 
 
 D' Aubuisson. (Variation of Temperature with the Latitude), 
 Jour, de Phys. lxii. 
 
260 METEOROLOGY. 
 
 De Luc. Recherches sur les Modifications de l’Atmosph., 
 Geneva, 1772— Id6es sur la Meteorologie, Lond. 1786— On 
 Hygrometry, Ph. Tr., 1791— On Evaporation, do., 1792. 
 
 Dobson . On the Harmatian, P. T., 1781. 
 
 Dove. Tables of Mean Temperature, Rep. of B. Assoc., 1847— 
 Meteorologische Untersuch ungen — Introduction to vol. iii. 
 of the Mag. and Met. Obs. at Hobart Town, V.D.L.— Mem. 
 Acad., Berl., 1846 — PoggendorfF, Annalen, 1829. — Ueber 
 die nicht-periodischan Aenderungen der Temperatur-verthei- 
 lungen auf der Oberflache der Erde. Ueber die periodischen 
 Aenderungen des Druckes der Atmosphare, 1860. 
 
 Deles. On Vesicles and Atmospheres of Electricity, Phil. Trans., 
 1775. 
 
 Ermann. Ueber Boden-und-Quellen-Temperatur — Reise um die 
 Erde — Ueber Einige Barom. Beob., PoggendorfF, lxxxviii — 
 Meteorol. Beob. bei Einen-See-Reise, Schumacher’s Astron. 
 Jahrb., 1840. 
 
 Espy. Philosophy of Storms, Lond., 1841 — Report on Meteorol. 
 of U. S. 
 
 Fitzroy (Rear Admiral H.) Meteorological papers compiled by, 
 and published by the authority of the Board of Trade, 1857, 
 et seq. 
 
 Foggo. Ed. Ph. Tr., No. 27. 
 
 Forbes. On Horary Oscill. of Barom., Ed. P. T. xii. — Report to 
 Brit. Assoc, on Meteorol., 1832 — Supplementary do. do., 
 1840— On Decrease of Temp, with Height, Ed. P. T. xiv.— 
 On Transparency of the Atmosphere, Phil. Tr. 1842 — -On 
 Temp, of Soil at Different Depths, Ed. P. T. xvi.— On the 
 climate of Edinburgh for 56 years (1795-1850), deduced 
 principally from Dr. Adie’s observations, &c., Trans. R. S. 
 Edin., xxii. part 2. 
 
 Franklin . Phil, and Met. Obs. Ph. Tr., 1755. 
 
 Fritsch. Periodische Erscheinungen im Wolkenhimmel, R. 
 Bohem. Acad. V. Folge. Bd. iv.— Grundzuge einer Met. fur 
 den Horizont von Prag. 
 
 Galbraith. Barom. Tables, Ed. 1833. 
 
 Glaisher. Hygrom. Tables, Lond., 1847.— On Correction of 
 Monthly Means of Met. Obs., Phil. Tr., 1848— On Nocturnal 
 
CATALOGUE OF METEOROLOGICAL AUTHORITIES. 261 
 
 Radiation, P. Tr., 1847 — “Meteorology” (Hughes’s reading 
 books, a useful brief compendium). 
 
 Hadley . On the Cause of the Trade Winds, P. Tr., 1738. 
 
 Halley. On Heat of Different Latitudes, P. Tr., 1693 — On Eva- 
 poration, do., 1686, 1694. 
 
 Harris (Sir Snow). Climate of Plymouth, Report B. A. 1839— 
 On the Preservation of Ships from Lightning. 
 
 Hartnup. Results of Met. Ohs. at Liverpool, 1851-2, &c. 
 
 Harvey. Art. Meteorology, Encyc. Metrop. 
 
 Heis. (Aix la Chapelle) fiber Stemschiippen, Koln, 1849. 
 
 Herschel, W. Observations of the Sun, and on its Variable 
 Emission of Light and Heat, Phil. Tr., 1801— Supplementary 
 Paper on Do.— Do. do., p. 354. 
 
 Herschel, J. F. W. Reports to B. Association on Atmospheric 
 Waves, 1843— On Effect of the Full Moon in Clearing the 
 Sky, vide infra , Lovelace ( Earl of). 
 
 Howard (Luke). On Clouds, Askesian Mem., 1802-3 — Climate 
 of London — On a Met. Cycle of 18 years, Ph. Tr., 1841 — 
 Barometrographia — Appendix to do., Lond., 1854. 
 
 Hudson. Hourly Obs. and Experimental Investigations of the 
 Barometer, P. T., 1832. 
 
 Humboldt. Personal Narrative — Asie Centrale— Kosmos— On 
 
 Isotherms, Mem. d’Arceueil, iii On Temp, of the Torrid 
 
 Zone, Ann. de Chim., 1826— On Inferior Limit of Perpetual 
 Snow, do., xiv. (Transl. Ed. Ph. T., iii. iv. v.)— Voyage aux 
 Regions Equinoxiales. 
 
 Hunter. On Temperature of Springs, Ph. Tr., 1788. 
 
 Hutton. On Rain, Ed. Ph. Tr., i. 
 
 Instructions for Making and Recording Met. Obs. Manual of 
 Scientific Enquiry, publ. by the Board of Admiralty — By R. 
 Irish Acad., 1850 — By the R. Soc. Report of Committee of 
 Physics including Met. 7, 1840. 
 
 Ivory. On Astronom. Refractions, Ph. Trans., 1823. 
 
 James (Lieut. Col. H.) Abstracts from the Met. Obs. taken at 
 the Stations of the R. Engineers in the year 1853-4, with a 
 brief discussion of some of the Results and Notes on Meteor. 
 Subjects. 
 
 Johnson. Met. Obs. at Ratcliffe Observatory, Oxford. 
 
 Johnston , Keith. Physical Atlas of Natural Phenomena. 
 
262 METEOROLOGY. 
 
 Kamtz. Meteorologie — On Isobarometric Lines — Jahrb. der 
 Phys. und der Chim., 1827— Bulletin des Sci. Math. x. 
 
 King (Capt. R.N.) Met. Jour, on board H.M.S. Adventure in 
 Survey of S. Coast of South America, 1826-30. 
 
 Kirwan. Estimation of Temperature in different Latitudes, 
 Lond. 1787— Mem. i., Acad. viii. 
 
 Roller. Gang der Warme in Oesterreich (Kremsmunster, 1841) 
 — Discussion of 10 years Observations at Kremsmunster, 
 Linz, 1833. 
 
 Kupffer. Temp, du Sol en l’Air, Bull. Phys. Math, de l’Acad. 
 Imp. Petersburg, iv. — On Springs and Earth Temp., Pog- 
 gendorff, xx. 
 
 Lambert. Meteorologie — Pyrometria — Mem. Acad. Berl., 1769, 
 1771, 1772 (Hygrometry, &c.) 
 
 Lamont. Darstellung der Temperatur — Verhaltnisse aut der 
 Oberflache der Erde — Abhandl. der Wiener, Akad. ii. 
 Abth. i. 
 
 Lawson (Brig. Gen. T.) Army Meteor. Register for 12 years 
 1843-54, compiled from observations made by the Officers of 
 the Medical Dep. of the Army at the Military Posts of the 
 Army of the U. States, Washington, 1855. 
 
 Leslie. On the Relations of Air to Heat and Moisture — On 
 Climate (Suppl. Encyc. Brit.) 
 
 Lind. On a Portable Wind-gauge, Ph. T. 1775. 
 
 Lowe. Climate of Nottingham, 1853 — Barom. Tables and In- 
 structions, 1857. 
 
 Lovelace (Earl of) On Climate as connected with Husbandry, 
 Lond. 1848. — (N.B. has a note, p. 31, on the Tendency of 
 the Full Moon to clear the Sky, from the Obs. of 80 Full 
 Moons, by Sir J. Herschel.) 
 
 Malnlmann. Beob. der. Temp, der Mittellandischen Meeres Pogg., 
 lviii. Mittlere Werhaltniss der Temp. Auf der Oberflache 
 der Erde (Dove’s Repertorium, Bd. iv.) 
 
 Mairan. P. Acad. 1719-1761. 
 
 Maury. Nautical Monographs of the Observatory, Washington, 
 U. S., 1859, et. seq. — Storm and Rain Charts of the North 
 and South Atlantic. 
 
 Mayer. De Variationibus Thermometricis Accuratius Defini- 
 endis, Op. ined. i. 
 
CATALOGUE OF METEOROLOGICAL AUTHORITIES. 263 
 
 Meech. On the Relative Intensity of the Heat and Light of the 
 Sun upon Different Latitudes of the Earth. — Smithsonian 
 Contributions to Knowledge, 1855. 
 
 Meteorological Society (of London), Transactions and Council 
 Reports. 
 
 Ofverbom. Discussion of the Stockholm Obs. of Daily Tempe- 
 rature, Ann. of Phil. 1813, i. 
 
 Olmsted. On the Recent Secular Period of the Aurora Borealis, 
 —Smithsonian Contributions to Knowledge, 1855. 
 
 Parrot on Meteorology Gilb., x. 
 
 ' Parry (Adml. Sir E.) Journal of a voyage of the Hecla and 
 Griper in search of a NW. Passage in 1819, 1820. 
 
 Pictet. Essais de Physique. 
 
 Piddington. Nineteen Memoirs on Cyclones in the Indian and 
 China Seas — Sailor’s Hornbook. 
 
 Plantamour. Resume des Obs. Therm, et Bar. a Geneve, Mem. 
 Soc. de Ph. et Hist. Nat. Gen. xiii. — Do. des Obs. a Gen. 
 et Mont St. Bernard — Archives des Sci. Phys. et Nat. a 
 Geneve, xv. 
 
 Pouillet. Elemens de Phys. et de Meteorol. — Mem. sur la 
 Chaleur Solaire, Comptes Rendus, 1838. 
 
 Prevost. De la Chaleur Rayonnant. 
 
 Proceedings of the Mag. and Met. Conference at Cambridge, 
 Brit. Assoc., 1845. 
 
 Quetelet. Mem. on Annual and Diurnal Yar. of Temperature at 
 Different Depths, Brux., 1837 — Catal. 1 and 2 des Principales 
 Apparitions des Etoiles Eilantes, Acad. Br., 1839 — Sur le 
 Climate de la Belgique — Obs. des Phenomenon Periodiques 
 — Obs. des Variations Periodiques et Non-Periodiques de la 
 Temperature, Ac. Br. xxviii. 
 
 Ramond. Obs. faites dans les Pyrenees. 
 
 Read . Summary view of Electricity of Earth and Atmosphere, 
 1795 — Meteorological Journal of Atmospheric Electricity. 
 Phil. Trans., 1794. 
 
 Reaumur. On Thermometers, Mem. Acad. Par., 1750, 1751. 
 
 Reid. Law of Storms — On Storms and Variable Winds. 
 
 Redfield. On Tides and Currents of the Ocean and Atmosphere, 
 American Journal of Arts and Sciences, xiv. — Report of 
 Meteorology of New York to Regents of University, State of 
 
264 
 
 METEOROLOGY. 
 
 New York — On Atlantic Hurricanes, United States Naval 
 Magazine. — On the Courses of Whirlwinds, American Jour- 
 nal of Arts and Sciences, xxxv.— On Violent Columnar 
 Whirlwinds which appear to have resulted from Large 
 Fires, Connecticut United States Academy of Arts and 
 Sciences, 183 9. —Remarks on Espy’s Theory of Centripetal 
 Hurricanes, Newhaven, United States, 1846— On Whirl- 
 wind Storms, New York, 1842. 
 
 j Eeslhuber. Constanten fur Kremsmiinster. Linz, 1853. 
 
 Robinson. Description of Improved Anemometer, Royal Irish 
 Academy, xxii. 
 
 Rowning. On a New Construction of a Barometer, Phil. Trans., 
 1773. 
 
 Roebuck . On Heat of London and Edinburgh, Phil. Trans., 1775. 
 
 Ross, Sir J. C. Arctic Voyage of the Erebus and Terror. 
 
 Roy (Gen. ) On the Barometric Measurement of Heights, Phil. 
 Trans., 1777. 
 
 Sabine. Pendulum Experiments, Lond., 1825 (Atmospherical 
 Notices, p. 506, etc.) — Report on Meteorology of Toronto, 
 Brit. Assoc., 1844— On Lunar Tide at St. Helena, Ph. 
 Trans., 1847 — On Meteorology of Bombay, Ph. Trans., 1853 
 — On Periodic and Non-Periodic Variations of Temperature 
 at Toronto, Ph. Trans., 1853. 
 
 Saussure . Voyages dans les Alpes — Essais de l’Hygrometrie. 
 
 Schouw. Specimen Geographiae Physicse Comparatae Beitrage 
 zur Vergleichenden Klimatologie — Bibl. U. xxxiv. — (Baro- 
 metric Changes.) 
 
 Schubler . Atmospheric Electricity— Bibl. Univ., xlii., Jahrbuch 
 der Chem. und Phys., 1829 — Ed. Jour. Sci., New Series, iii. 
 — Gilbert’s Ann., xxxix., xlix., li. 
 
 Scoresby. Account of the Arctic Regions — Meteorological Essays. 
 
 Schuckburgh . Observ. for Heights of Mountains, Phil. Trans., 
 1777. 
 
 Secchi. Results of Met. Obs. in the Collegio Romano (1850-56), 
 Bibl. U., 1857. 
 
 Sinobas (Don J. M. Rico y). Resumen de los trabajos Meteoro- 
 logicos verificados en el Real Observatorio de Madrid. 
 
 Six. On Meteorology, 1794— On Local Heat, Phil. Trans., 1784, 
 1788. 
 
CATALOGUE OF METEOROLOGICAL AUTHORITIES. 265 
 
 Stark. Reports on Meteorology of Scotland, Edinburgh (Murray 
 and Gibb). 
 
 Sykes. On Atmospheric Tides and the Meteorology of Dekhan 
 (Deccan), Phil. Trans., 1835— Observations in India, Phil. 
 Trans., 1850. 
 
 Thomson . Introduction to Meteorology. 
 
 Toaldo. Saggio Meteorologico — Della Yera Influenza Degli 
 Astri, 1770 — On Climates, Acad. Pad., iii. 
 
 Ubersicht , der bei der Met. Inst. zu. Berlin gesammelten Erge- 
 bnisse dei Wetterbeobachtungen auf den Stationen des. 
 Preussischen Staats, 1855, et seq. 
 
 Uebersicht, der Witterung im Nordlichen Deutschland. 
 
 Walker (Sear). On Periodic Meteors of August and November. 
 
 Welsh. Phil. Tr., 1853 — Account of four Balloon Ascents. — 
 Phil. Tr., 1856 — Account of the construction of a standard 
 Barometer, and description of the Apparatus and processes 
 employed in the verification of Barometers at the Kew 
 Observatory. 
 
 Wells. On Dew. 
 
 Whewell. On a New Anemometer, Tr. C.U.P.S. vi. 
 
 Wilson . On a Remarkable Cold in Glasgow, Ph. Tr., 1780. 
 
 Wollaston. On the Finite Extent of the Atmosphere, Ph. Tr. 
 
 Young. Course of Lectures on Natural Philosophy, and the 
 Mechanical Arts (< especially the Catalogue of Meteorological 
 Memoirs , etc., in vol. ii.) 
 

 
INDEX. 
 
 The references are to the numbers of the sections or articles into which 
 the work is divided. 
 
 Absorption of tlie sun’s rays by tbe atmosphere, 10; of 
 terrestrial radiant beat by do., 37. 
 
 Abyssinia , lightning flashes of extraordinary length in, 139. 
 
 Acid , carbonic, a constituent of the atmosphere, 17, 21. 
 
 Actine , the unit of solar heat-radiation, 14. 
 
 Actinometer , Herschel’s, its construction and use, 14. 
 
 Actinometry , 13, et seq. 
 
 Africa , effect of on the limits of the trade winds, 66; its 
 rainless deserts, 110. 
 
 Air , general consequences of its mobility, 3; its nature, 
 density, electricity, rate of expansion, etc., 15; its 
 chemical constituents, 17; not an atomic compound, 
 ibid; specific gravity, and weight of cubic foot, 18, 89; 
 its dilatation produces winds, 55; barometric pressure 
 of dry air , distinct from that of vapour ; its laws of 
 fluctuation, 165, et seq. (See Atmosphere). 
 
 Altitude above sea; its influence on meteorological pheno- 
 mena, 161; its special influence in producing diurnal 
 barometric oscillations, 177. 
 
 Altitudes , barometric determination of in balloon ascents, 
 27; formulae for barometric estimation of, 19, 26; 
 Laplace’s, 30; Sir J. Herschel’s, 34. 
 
268 
 
 METEOKOLOGY. 
 
 Ammonia , its blue colour on escaping from pressure, 235. 
 
 Anemometers , various constructions of, 81. 
 
 Anemometry , 81, et seq. 
 
 Antitrade Winds , 62, 63; transport rain from the equator 
 to the poles, 113. 
 
 Anvil shaped clouds, 106. 
 
 Apjohn (Dr.), bis formulae for reduction of hygrometric 
 observations, 89. 
 
 Arago , bis observations on atmospheric electricity, 131; 
 on temperature of equatorial seas, 190; on a point of 
 no-polarization in tbe sky, 233 a. 
 
 Arch , auroral , its beigbt above tbe earth’s surface, 239. 
 
 Arve, River , fogs formed over, 96. 
 
 Asia, its influence on tbe trade winds of tbe Indian ocean, 
 67. 
 
 Astrachan, climate of, 195. 
 
 Atkinson, bis hypothesis respecting tbe decrement of At- 
 mospheric temperature, 27, 32. 
 
 Atlantic Ocean, limits of tbe trade winds in, and of their 
 annual oscillations, 66. 
 
 Atmosphere, absorption of solar beat by, 10; of terrestrial 
 beat, 37; its pressure, 16; total weight of in pounds, 
 17; homogeneous, what, and its height, 18; decrement 
 of density, 19; question of its finite limits, 20; 
 habitual dryness of its upper regions, 88; not in a 
 state of statical equilibrium, 77 a, 161. (See Air). 
 
 Atmospheric Electricity, 126, et seq. (See Electricity). Tides, 
 their nature, 76, et seq.; diurnal, 77 a; annual, 78. 
 
 Aurora Borealis, 238; height of, 239; of a recent one, 
 239, note. 
 
 A verages, Meteorological, mode of determining, 150, 153; 
 annual rainfalls (see Bain) ; of temperature of day and 
 year from short series of observations, 182. 
 
 Azote , see Nitrogen. 
 
 Bahinet, observation of a point of no polarization in sky 
 light, 233 a. 
 
INDEX. 
 
 269 
 
 Bacon (Lord), 69. 
 
 Baddeley on dnst whirlwinds in India, 244. 
 
 Balloon Ascents , their advantages in barometric researches, 
 27; their application to such researches, 29; baro- 
 metric formulae founded on, 34; remarkable pheno- 
 mena observed in, 116, 201. {See Gay Lussac, Green, 
 Kush, Welsh). 
 
 Bands of light passing through the sun, 231. 
 
 Barnaoul, summer and winter temperature at, 195; table 
 of meteorological elements at, 246. 
 
 Barometer, its mean height at the sea level, 16; great 
 habitual depression if in certain regions, 162. 
 
 Barometric pressure, law of decrement in an atmosphere of 
 uniform temperature, 19; do. for temperature decreas- 
 ing uniform by, 26; do. for true law of decrement of 
 temperature, 34; affected by the introduction of vapour 
 into the air, 54; diminution of in proceeding from 
 tropics to equator, 54; distribution of, 161, 163; 
 annual and diurnal fluctuations of, 165; resolved into 
 dry and vapour pressures, 165, 166, et seq.; exhibits a 
 double maximum and the rationale thereof, 169, et 
 seq.; table of gross pressures at various places, 175; do. 
 at normal stations, 246. 
 
 Barometric fogs, 97. 
 
 Baxendell (Mr.), his views of the state of aqueous vapour in 
 the air, 109, note. 
 
 Beale (Dr.), first notices the diurnal oscillations of the 
 barometer, 174. 
 
 Beechey (Capt.), his observations of deep sea temperatures, 
 
 37. 
 
 Bermuda, a focus of hurricane paths, 72. 
 
 Bernouilli, his computation of efflux of air under pressure, 
 57. 
 
 Bessel, his formulae for computation of most probable 
 meteorological co-efficients, 153, et seq . 
 
 Binney (Mr.), his observations of falling waterdrops in deep 
 pits, 109. 
 
270 METEOROLOGY. 
 
 Biot , Ms hypothesis respecting the decrement of tempera- 
 ture, 27. 
 
 Birt, Ms “ great November wave,” 80. 
 
 Boblaye , 22. 
 
 Bolides , 240. 
 
 Bombay , great rainfall at, 115; average do., 115; table of 
 meteorological elements for, 246. 
 
 Borlase , remarkable effect of lightmng described by, 140. 
 
 Borrowdale , remarkable rainfall in, 114. 
 
 Boussingault , Ms observations on the temperature of the 
 soil, 188. 
 
 Brandes, his calculations of penthemeral temperatures, 196. 
 
 Bravais , his imitation of halos, 121; Ms barometric obser- 
 vations, 173. 
 
 Brewster (Sir D.), Ms observations on polarization of sky 
 light, 233 a; Ms treatise on optics, ibid. 
 
 Brick , its radiating power, 47. 
 
 Brisbane (Sir Thos.), results of observations at Makerstoun, 
 246. 
 
 Brooke , his self-registering photograpMc apparatus, 159. 
 
 Brussels , table of meteorological elements for, 246. 
 
 Buisi (Dr.), his account of Indian hailstorms, 118. 
 
 Callao , formula for the diurnal march of the barometer at, 
 176. 
 
 Calm latitudes , 61. 
 
 Caloric , radiant; its properties, 37; latent of steam, 51; 
 of water, 53. 
 
 Candeish , great hailstorm at, 119. 
 
 Cape of Good Hope , temperature of the soil observed at, 
 38; phenomenon of the table cloth, 99; thunderstorms 
 at, 141. 
 
 Carbonic acid as a constituent of the atmosphere, 17, 21. 
 
 Catalogue of meteorological works, 247. 
 
 Catherineburg , table of meteorological elements for, 246. 
 
 Causes , general, of meteorological phenomena, 3; direct 
 and indirect, and derivative, 4. 
 
INDEX. 
 
 271 
 
 Cavallo , his researches on atmospheric electricity, 128. 
 
 Cayenne , extraordinary rainfall at, 115. 
 
 Centrifugal force, correction for in barometric formulae, 31. 
 
 Ceylon, diurnal fluctuations of temperature at, 179. 
 
 Charcoal, its radiating power, 47. 
 
 Cher r a Ponji, enormous rainfall at, 115. 
 
 Chili, snow level in, 125. 
 
 Cirro cumulus, 104. 
 
 Cirro stratus, 105. 
 
 Cirrus, 103. 
 
 Climate, its dependence on geographical situation, 9 ; 
 continental and insular, 40; solar and real, 56. 
 
 Climatology , general principles of, 143, et seq . 
 
 Clouds, 98, et seq.; Howard’s nomenclature of, 98, 100, et 
 seq.; anvil shaped, 106; ascent in sunshine, 107; 
 descent by gravity, 107; constitution of, 107; of the 
 trade winds, 111; on Teneriffe, ibid.; frozen at great 
 altitudes, 121 ; their relation to ascending vapour, 
 197, 205; extreme humidity in, 204; formation of 
 by up-diverted currents of air, 99; on table mountain, 
 99; several distinct levels of co-existing, 205; colours 
 of, 234; coloured fringes seen on, 230. 
 
 Coasts, east and west, their different meteorological habi- 
 tudes, 114, 195. 
 
 Cochin, remarkable optical phenomenon observed by, 226, 
 note. 
 
 Coefficients of meteorological formulae, 153; how best 
 determined, 150, et seq. 
 
 Cold produced by evaporation, 51 ; by expansion of air, 24. 
 
 Colladon, his researches on atmospheric electricity, 128. 
 
 Condensation of vapour, a source of heat, 51. 
 
 Conduction of heat 39, 45; of electricity, 134. 
 
 Congo, mean temperature of soil at, 189. 
 
 Continental, climate, 40, 195. 
 
 Copper, radiating power of, 47. 
 
 Cordier, 22. 
 
 Cordilleras, snow level in, 125. 
 
272 
 
 METEOROLOGY. 
 
 Coreen hills , aurora frequent over, 239. 
 
 Corona , 229. 
 
 Cornea of the eye , phenomena analogous to coronae, caused 
 by Rims on, 229. 
 
 Cotton , radiating power of, 47. 
 
 Coulomb , bis researches on atmospheric electricity, 128. 
 
 Cumberland , its rainy districts, 114. 
 
 Cumulo stratus , 106. 
 
 Cumulus , 98, 101; its appearance an indication of the 
 ascent of vapour, 200. 
 
 Currents of the ocean, their influence in distributing heat 
 and moisture, 84, et seq.; in a globe uniformly covered 
 by sea, 84. 
 
 Curves expressing connection of temperature and pressure 
 in balloon ascents, 29, 30; expressing values of mete- 
 orological averages, 148; isometeoric, 149. 
 
 Cyclones , 72; their explanation by Prof. Taylor, 73; 
 African, 243. 
 
 Dalton , his law of mutual inelasticity of gases, 21, 87; 
 his experiments on evaporation, 50; his law of vapour- 
 tension, 52. 
 
 Daniell on terrestrial radiation, 46; on striking distance 
 of voltaic electricity, 139, note. 
 
 Decrement of temperature in ascending into the atmosphere, 
 22, 26, 27, et seq.; its rate near the surface of the 
 earth, 22; causes of do., 23, 24. 
 
 Deductive method of inquiry inapplicable in Meteorology 
 in general, 4. 
 
 De Glos , an early observer of the diurnal oscillations of 
 the barometer, 174. 
 
 Delcrosse (Capt.), his account of large hailstones, 118. 
 
 Deluc , his views respecting vapour in the atmosphere, 
 87. 
 
 Density of air, 1 8 ; diminution of, 19; law of in an atmo- 
 sphere of uniform temperature, 19; at various altitudes 
 its decrement, 19, 21. 
 
INDEX. 273 
 
 Des Hayes , his observations of diurnal oscillation of the 
 barometer, 174. 
 
 Dew, 91, et seq.; circumstances favouring or opposing its 
 formation, 91; electricity of, 130; cause of do., 135. 
 
 Dewpoint , 90; for the most part coincident with lowest 
 night temperature, 178; very low observed on Tene- 
 rifFe, 203; nil observed by Messrs. Green and Rush, 
 203. 
 
 Diffusion of gases, Law of, 21. 
 
 Diffusion at Fogs, 97 a. 
 
 Direct and indirect action of meteorological causes, 4. 
 
 Dove, 67; his law of rotation of winds, 69; calculation of 
 winds at various places, 83 ; explanation of double 
 maximum of barometric pressure, 170, 174; conclusions 
 respecting the average temperatures of the two hemi- 
 spheres, 191; views of dependence of temperature, 
 moisture, etc., on direction of winds, 207, et seq. 
 
 Dryness, habitual, of upper regions of atmosphere, 88, 197, 
 203; relative, 199; absolute observed, 203; on Tene- 
 riffe, 203. 
 
 Dublin, table of meteorological elements for, 246. 
 
 Dulong, 41. 
 
 Dust, transported to great distances by winds, 245. 
 
 Dust whirlwinds in India, 244. 
 
 Dynamical measurement of solar radiation, 14. 
 
 Earth, its mean diameter, 1 7 ; mean temperature of surface 
 of its hemispheres in summer and winter, 191. 
 
 Edinburgh (Fort Leith). Formulae for diurnal fluctuation 
 of temperature at, 181. 
 
 Eeles, his theory of lightning, 135. 
 
 Eisenlohr , his meteorological results for Karlsbad, 216. 
 
 Electricity, Atmospheric, 126, et. seq.; its diurnal variation, 
 127,128,131; method of exploring, 127; its general 
 character vitreous, 128; increases in ascending to the 
 higher regions of the atmosphere, 129; annual vari- 
 ation of, 131; at sea, 131; its origin, 132; epochs 
 
 T 
 
274 
 
 METEOROLOGY. 
 
 of diurnal and annual maximum and mimum, 131; in 
 what state existing, 134; its diurnal fluctuation ex- 
 plained, 135; inefficient as a cause of great atmospheric 
 movements, 137; its quantity discharged during storms, 
 142; its agency in the production of aurora, 238; 
 development of in dust whirlwinds, 244 ; and in 
 volcanic eruptions, 133. 
 
 Elements , Meteorological , tables of for different selected 
 stations, 246. 
 
 England , its west coasts rainy, and why, 114. 
 
 Epochs of maxima and minima of barometric pressure, 174; 
 of atmospheric electricity, 131; of temperature, 184; 
 201; of humidity, 201, 202; of vapour-tension, 201; 
 of cold on the earth, 192. 
 
 Equator , Temperature of the sea under the, 37, 38, 55. 
 
 Equatorial calm region, 61; rains, 110, 112; seas, their 
 uniformity of temperature, 190 
 
 Equilibrium of temperature, 41. 
 
 Eschmann , 22 . 
 
 Evaporation , of water, its rate at various temperatures, 50; 
 of ice and snow, 125; accelerated by wind and other 
 causes, 50, 125; abstraction of heat by, 51; electricity 
 developed by, 132. 
 
 Eccentricity of the earth’s orbit, its effect on temperature, 
 8, 184, 191. 
 
 Farquharson (Dr.), his observation of aurora borealis at low 
 altitudes, 239. 
 
 Faulhorn , 10 . 
 
 Ferilli (volcanic lightning), 133. 
 
 Flakes of snow (see Snow) ; their melting a possible cause 
 of vesicles, 121. 
 
 Flannel , its radiating power, 47. 
 
 Flax , its radiating power, 47. 
 
 Fluctuations , diurnal and annual (see periods, etc., for the 
 several phenomena) ; laws of how determined, 1 52, et seq. 
 
 Fogs , radiation, 93 ; river, ibid ; in low grounds, reason of, 
 
INDEX. 
 
 275 
 
 ibid; over shoals at sea, 96; barometric, 97; diffusional, 
 97 a; yellow, 102; electricity of, 130; do. accounted 
 for, 135. 
 
 Forbes (Prof.), his observations on extinction of solar heat 
 in the air, 10; researches on temperature of soil at 
 various depths, 39; on the colour of high pressure 
 steam, 235. 
 
 Formulae , Bessel’s for probable means of meteorological 
 observations, 152; for diurnal fluctuation of barometer 
 at several places, 176; for do. of temperature, 191; of 
 Kamtz for mean temperature of a place, 182; for 
 obtaining the mean temperature by three observations, 
 182; for annual temperature of places in the extra- 
 tropical northern hemisphere, 184; for dependence of 
 heat, moisture, and pressure on the wind’s direction, 
 208, 209, 210, 212. 
 
 Franklin , his demonstration of the electric nature of 
 lightning, 126. 
 
 Fringes interior of the rainbow, their theory, 221; of 
 interference on clouds, 230; surrounding shadow of 
 spectator, 232 a. 
 
 Froebel , his observation of a case of lateral refraction, 235. 
 
 Frosts , severer on low grounds than on moderate eleva- 
 tions, 94. 
 
 Fulgurites , 140. 
 
 Gas, ammoniacal blue colour assumed by, when expanding, 
 235. 
 
 Gases, mutual inelasticity of and law of their diffusion, 21. 
 
 Gag Lussac , his balloon ascent, 21, 22, 31; computation 
 of its height from different formulae, 26; his observa- 
 tions on atmospheric electricity, 129. 
 
 Glaisher, on terrestrial radiation 46, et seq.; his hygro- 
 metrical tables, 89; his figures of snow spangles, 120; 
 his researches on mean annual temperature, 186. 
 
 Glass , radiating power of, 47. 
 
 Glow discharge of electricity, a probable cause of certain 
 phenomena, 240, note. 
 
276 
 
 METEOROLOGY. 
 
 Gobi , desert of, 110. 
 
 Godin , his observations of the diurnal oscillations of the 
 barometer, 174. 
 
 Graphical process for determining altitudes in a balloon 
 ascent, 28. 
 
 Grass , its radiating power, 47. 
 
 Gravel , its radiating power, 47. 
 
 Green , his ballon ascents, 22, 31. 
 
 Greenwich , phenomenon observed at, 102; march of tem- 
 perature, humidity, and vapour tension at, 201, 202; 
 table of meteorological elements for, 246. 
 
 Gulf-stream , 86, its influence on climates of Ireland and 
 the west coast of England, 114. 
 
 Hadley , his explanation of the trade winds, 59, et seq , 
 
 Hail , 116, et seq, its cause, 117; great storm of, 1 1 7. 
 
 Hail-stones , structure of, 118; instances of very large, 116 • 
 aggregated by regelation, 119. 
 
 Halos , 227, et seq,; explained by ice crystals, 227, 228; 
 imitated artificially, 121. 
 
 Hamilton (Sir Win.), his observations during an eruption of 
 Vesuvias, 133. 
 
 Hardisty , his observation of an aurora below the clouds, 
 239. 
 
 Heberden (Dr.), his observations on rain at different levels, 
 109. 
 
 Heat , solar and terrestrial, their distinction; abstracted by 
 evaporation, 51; its climatological distribution, 178, et 
 seq.; solar , its annual fluctuation, 8; sensible and latent, 
 24, 25; mode of its propagation through water, 37; 
 through the soil, 38. 
 
 Herschel (Sir W.), his views of the dependence of solar heat 
 on the spot in the sun’s disc, 7 ; (Sir J.), his measure of 
 solar radiation, 1 1 ; actinometric experiments, 1 4. 
 
 Heyne , his account of a great hailstone, 119. 
 
 Himalayas , level of perpetual snow on, by what causes 
 affected, 125. 
 
INDEX. 
 
 277 
 
 Hoar-frost , 91. 
 
 Hobart Town , table of meteorological elements for, 246. 
 
 Homogeneous atmosphere , 18. 
 
 Horary oscillations of barometer, etc. ( See Barometer and 
 Fluctuation). 
 
 Horsburgh , bis directory, 67. 
 
 Hours most proper for meteorological observations, 158, 
 182. 
 
 Howard , bis nomenclature of clouds, 98, et seq. 
 
 Humboldt (A. Von), 22, 54, 56 ; bis observations of re 
 markable rain-falls, 115; on level of perpetual snow, 
 123, 124; of diurnal oscillation of barometer, 173; of 
 lateral refraction, 237. 
 
 Humidity of tbe air, wbat; its scale; relative, wbat, 199; 
 its march contrary to that of vapour tension, 200; 
 epochs of diurnal maxima and minima, 201; annual 
 do., 202; singularities in its law of ascensional decre- 
 ment, 204, 205. 
 
 Hurricanes , velocity of wind in, 57; nature of, 72; of 
 Indian Ocean, 72. 
 
 Hutchinson (Graham, Esq.), his account of thunderstorms in 
 Jamaica, 141. 
 
 Hygrometer , Hygrometry , 89, et seq, ; 197, et seq.; Hygro- 
 metric fluctuations, 197. 
 
 Ice , melted per minute by solar radiation, 11; its artificial 
 formation by nocturnal radiation, 49 ; primitive form 
 of its crystals, 120, 121. 
 
 Ice-bergs , produce fogs, 96. 
 
 Ice-caves , 125. 
 
 India , diurnal fluctuation of temperature in, 179; dust 
 whirlwinds of, 244; hail in, 118; manufacture of ice 
 in, 49. 
 
 Inelasticity , mutual , of gases, 21. 
 
 Insular climates , 40. 
 
 Interference of light , rainbow fringes produced by, 221; 
 coronas, 229; colours and fringes on clouds, 230. 
 
278 METEOROLOGY. 
 
 Interplanetary spaces , their temperature, 22, 36; density 
 of air in, 20. 
 
 Ireland , its west coasts rainy, and why, 114. 
 
 Irkutsk, its summer and winter temperatures, 195. 
 
 Isobar ometric curves, 149; Isocheimonal, do.; Isogeothermal, 
 do; Isotheral, do; Isothermal, do., 149; the latter 
 agree generally with sphserolemniscates, 192, 193. 
 
 Isometeoric curves , see Isobarometric, etc. 
 
 Jamaica , daily thunderstorms in, 141. 
 
 Johnson (Prof.), meteorological formulae and results for 
 Oxford, 215. 
 
 Joyeuse , great rainfall at, 115. 
 
 Kamtz , his actinometric observations on the Faulhorn, 10; 
 his work on meteorology, 67; calculation of averages 
 of winds, 83; explanation of certain phenomena of rain, 
 109; his isobarometric curves, 149; calculations of 
 diurnal march of temperature, 181 ; of barometric 
 pressure, 176; of annual temperature, 183, 184; law 
 of decrement of do. on receding from the equator, 194. 
 
 Karlsbad , climate of, 216. 
 
 Kasan, average direction of wind at, exceptional, 217. 
 
 Kent , Weald of, radiation fogs frequent in, 93. 
 
 Khasyah Hills, immense annual rainfalls in, 115. 
 
 Kirwan , his researches on decrement of temperature on 
 globe, 193. 
 
 Kislar, low winter temperature of, 195. 
 
 Kite , electrical, 126. 
 
 Kotzebue , 37. 
 
 Kratzenstein , his argument in favour of vesicles, 92; case 
 where it is inapplicable, 93. 
 
 Kupffer , his isogeothermal lines, 149, 189; his calculation 
 of annual march of temperature at Petersburg, 183. 
 
 Lake districts of Cumberland and Westmoreland, their 
 rainy character, 114. 
 
INDEX. 
 
 279 
 
 Lambert , his law of the decrement of temperature, 27. 
 
 Lampblack , radiating power of, 47. 
 
 Land , its habitudes in relation to solar heat; its radiation 
 and conduction; in what respects different from water; 
 superficial temperature of, 38. 
 
 Lenz, his calculation of Kotzebue’s observations of ocean 
 temperature, 37. 
 
 Leslie , his explanation of the decrement of atmospheric 
 temperature, 24, 25. 
 
 Lightning , 126, et seq.; its electrical nature proved, 126; 
 immediate cause of, in a storm, 135, 136, 137; length 
 of flashes, 139; extraordinary do. in Abyssinia, ration- 
 ale of, ibid; singular effects of, 140. 
 
 Lond , his observations of the snow level on the Himalayas, 
 
 125. 
 
 London , phenomenon presented by the smoke of, 102; 
 average rainfall in, 114; climate of (see Greenwich). 
 
 Lowe, his observations of the forms of snow spangles, 
 120; of an auroral arch, 239, note; table of meteoro- 
 logical elements from his observations for Nottingham, 
 246. 
 
 Mackerel sky , 164. 
 
 Madrid, table of meteorological elements for, 246. 
 
 Maker stoun, table of meteorological elements for, 246. 
 
 Malet, his account of a hailstorm in Candeish, 119. 
 
 Mariotte , 69. 
 
 Maxima and minima (see Epochs), double, 131, 169. 
 
 Mayer, his law of decrement of mean temperature on the 
 globe, 194. 
 
 Mazeas (Abbe), his experiments on atmospheric electricity, 
 
 126. 
 
 Mercury, its specific gravity, 1 6 ; dilatation, 1 6. 
 
 Meteor, great, of 1783, 240; Meteors, supposed annual 
 partial obscuration of the sun by, 196. 
 
 Meteorolites, 240. 
 
 Meteorology, its general scope; etymology, etc., 1 , et seq . 
 
280 
 
 METEOROLOGY. 
 
 Miller , his observations on rainfall in Cumberland and 
 Westmoreland, 114. 
 
 Mirage , 236; lateral, 237. 
 
 Misty 92. (See Fog). 
 
 Moisture, its distribution through the atmosphere, 203. 
 (See Humidity). 
 
 Monsoons , 67. 
 
 Mould (garden), its radiating power, 47. 
 
 Mountain, Table, 99. 
 
 Mountains, barometric measurement of (See Altitude); their 
 effect in determining the formation of cloud, 99; do. 
 the fall of rain, 113; Khasyah, 115. 
 
 Nertschinsh, table of meteorological elements for, 246. 
 
 Newfoundland, fogs of, 96. 
 
 Niebuhr, his observation of a white rainbow, 226. 
 
 Niedermening, ice preserved in quarries of, 125. 
 
 Nimbus, 106. 
 
 Nitrogen, its proportion in the atmosphere, 1 7. 
 
 Norway, its climate affected by the gulf stream, 86. 
 
 Nottingham, table of meteorological elements for, 246. 
 
 Obliquity of incidence of sunshine, its influence on tempe- 
 rature, 9, 10; on absorption of heat in the air, 12. 
 
 Ocean, its division into three basins or regions of tempera- 
 ture and density, 37 ; Atlantic, Pacific (see those 
 heads), Indian, monsoons of, 67. 
 
 OchotzJc, Sea of, habitual depression of barometer in and 
 near, 162. 
 
 Ofverbom, his calculation of penthemeral temperatures for 
 Stockholm, 196. 
 
 Optical phenomena of meteorology, 219, et seq a remark- 
 able one seen by the author, 229 ; Schemer’s great 
 phenomena, 232. 
 
 Ord (Ross-shire), extraordinary hailstone at, 119. 
 
 Oscillations of barometer, annual, 165; diurnal, 171, 173, 
 et seq.; double maximum of, 174. 
 
INDEX. 
 
 281 
 
 Osier , his anemometer, 81. 
 
 Oxford , formulae for dependence of meteorological elements 
 on the wind, 215; table of meteorological elements for, 
 246. 
 
 Oxygen , its proportion in the atmosphere, 17. 
 
 Ozone , produced by lightning, 137. 
 
 Pacific Ocean, limits and oscillations of the trade winds in, 
 65. 
 
 Padua, barometric pressure expressed in a formula for, 
 176; temperature (diurnal), do., 181. 
 
 Parhelia , 231; great displays of, at Eome and Moscow, 
 232. 
 
 Paris, rain at different levels at observatory, 109. 
 
 Parry (Capt.), aurora seen by below clouds, 239. 
 
 Payta, barometric formulae for, 176. 
 
 Penthemera of temperature, 196. 
 
 Periods, annual and diurnal of meteorological phenomena, 
 (see Pressure, Temperature, etc.); decennial, 186; of 
 11T1 years, 7; of 14 years, 186. 
 
 Periodicity of meteorological phenomena, general view of, 
 143, et seq.; a general principle of, 144. 
 
 Persia , rainless districts of, 110. 
 
 Petersburg , formulae for annual fluctuation of temperature, 
 183; table of meteorological elements for, 246. 
 
 Petit, 41. 
 
 Philadelphia, table of meteorological elements for, 246. 
 
 Phillips (Prof.), his observations of rain on York Minster, 
 109. 
 
 Photography applied to self-registry of meteorological phe- 
 nomena, 159. 
 
 Piddington, his researches on the law of storms, 72. 
 
 Polarization of rainbows and halos, 228; of skylight, 233. 
 
 Portugal, its wet and dry seasons, 113. 
 
 Pouillet, his measurement of heat absorbed by atmosphere, 
 10; of the solar radiation, 11; his pyroheliometer, 14; 
 his researches on atmospheric electricity, 132. 
 
282 
 
 METEOROLOGY. 
 
 Prague , table of meteorological elements for, 246. 
 
 Pressure, Barometric (see Barometric Pressure), of wind 
 per square foot, 57. 
 
 Prevost, bis views on radiant beat, 41. 
 
 Pyroheliometer, 14. 
 
 Radiation , terrestrial, 40, 41; from and into space, 43; its 
 amount, measurement, and average, 44, 48; process 
 of after sunset, 45; from various substances, 47; to 
 clouds, 48; mutual among all bodies, 41; its applica- 
 tion to making ice, 49 ; into space tbe cause of dew, 
 91. 
 
 Radiation fogs, 93. 
 
 Rain , 108, et seq.; amount per incb per acre, 109, note; 
 amount at different levels above soil, 109; circum- 
 stances determining its greater or less amount, 110; 
 rainless districts, 110; regions of unfrequent occur- 
 rence, 111; its dependence on latitude, 113; negative 
 electricity accompanying, 138. 
 
 Raingauge , 109. 
 
 Rainfalls , tables of in various places, 115; sudden, accom- 
 panying lightning, 137, and note; extraordinary, 115. 
 
 Rainbow, not formed in cloud, 92, 226; wby not, 92, note; 
 226, note; lunar formed in fogs, 93; superb instance 
 of, 93; explanation of tbe supernumerary bows, 219, 
 220, 221, et seq.; primary, secondary, etc., 220, et seq.; 
 seen on grass and gossamer, 224; in cloud, 226; in 
 fogs, 92, 226; white, 226. 
 
 Rarefaction of air at great altitudes, 19, 31. 
 
 Raymond, 22. 
 
 Read, bis researches on atmospheric electricity, 128, 130. 
 
 Redfield , bis researches on tbe law of storms, 72. 
 
 Reduction of meteorological observations, general formulae 
 for, 153, et seq.; recommended to meteorologists as part 
 of their regular work, 158. 
 
 Reflector for nocturnal radiation, 48. 
 
 Reflexion of objects on a heated wall, 237. 
 
INDEX. 283 
 
 Refraction , astronomical, 236; terrestrial, 236; cases of 
 remarkable atmospheric, 236; lateral, 236. 
 
 Reid , bis researches on the law of storms, 72. 
 
 Resistance of air to falling drops, 107, 108. 
 
 Richmann , his death by lightning, 126. 
 
 Ripples, aerial, 99, 163. 
 
 Rio Negro, great rainfall at, 115. 
 
 Robinson (Dr.), his anemometer, 81. 
 
 Romas, his experiments with electric kite, 126. 
 
 Ronalds , his system of photographic self-registry, 159. 
 
 Ross (Sir J. C.), his observation of anrora seen below clouds, 
 239. 
 
 Roussin (Admiral), his account of a great rain fall at 
 Cayenne, 115. 
 
 Rush, his balloon ascents, 22, 31. 
 
 Sabine, his opinion on the solar period, 7 ; his observations 
 on terrestrial radiation, 46. 
 
 Sahara, 110. 
 
 Saint John , his observations of a white rainbow in morning 
 mist, 226. 
 
 St. Helena (Longwood), table of meteorological elements, 246. 
 
 Sand, its radiating power, 47. 
 
 Saussure (De), 22; his account of vesicles, 92; his researches 
 on atmospheric electricity, 128, 131. 
 
 Scheiner, great meteorological phenomenon observed by, 
 232. 
 
 Schouw, his observations of the domination of barometric 
 pressure between the tropics, 54. 
 
 Schubler on atmospheric electricity, 128, 131. 
 
 Schwabe, his period of the sun’s spots, 7. 
 
 Scoresby , his observations of the forms of snow spangles, 
 
 120 . 
 
 Seathwaite, extraordinary annual rainfall, 114, 115. 
 
 Seasons, dry and wet between tropics, 112. 
 
 Serein, 108. 
 
 Sherer , his observation of aurora below clouds, 239. 
 
284 
 
 METEOROLOGY. 
 
 Showers of fish, frogs, flannel, bread, stones, ashes, 245. 
 
 Silk, radiating power of, 47. 
 
 Simoom, 243. 
 
 Sitka , Table of meteorological elements for, 246. 
 
 Skin, hare, rabbit, their radiating powers, 47. 
 
 Slate, its radiating power, 47. 
 
 Smith, his observations on temperature of soil at Congo, 
 189. 
 
 Smoke of London, 102. 
 
 Smyth (Piarri, Esq.), his observations on Teneriffe, 111, 
 245, 246. 
 
 Snow, its radiating power, 47 ; sudden fall of, observed in 
 a balloon ascent, 116; its nature and mode of forma- 
 tion, 120, et seq.; spangles of, 120; its effect in miti- 
 gating frost, 122; perpetual level of, 123, et seq.; cir- 
 cumstances which determine it, 125. 
 
 Soil, temperature of, 39, 188, 189; uninfluenced by rain 
 and snow, 189. 
 
 Spangles, snow. See Snow spangles. 
 
 Spencer, his balloon ascent, 116. 
 
 Stars, radiation from, 43; shooting, 240. 
 
 Statical and dynamical measures of solar radiation, 1 3. 
 
 Steam, latent heat of, 51; specific gravity of, 52; high 
 pressure, its ruddy colour when expanding, 235. 
 
 Stone, its radiating power, 47; Stones, showers of, 240. 
 
 Storm, great Crimean, of 1854, 80 ; storms, law of, 
 See Cyclone. 
 
 Strata of the atmosphere, 76, 161. 
 
 Stratus, cloud, 102; rapid propagation of, 102; low level 
 of, at night, 198. 
 
 Sturm, 69. 
 
 Stye, the, extraordinary rainfall at, 115. 
 
 Summer, heat received from sun during, in east hemi- 
 sphere, 8. 
 
 Sun, as a source of heat, 7, et seq.; periodicity of its spots, 
 7; amount of heat received from at different seasons, 8; 
 its heating power on a horizontal surface, 9 ; measure 
 
INDEX. 
 
 285 
 
 of its direct radiation, 10 , 11 , et seq.; of its oblique do., 
 12; effect of its movement in declination on winds, 
 63, 64. 
 
 Supernumerary rainbows, 221, et seq. 
 
 Sykes (Colonel), bis barometrical observations, 173; bis 
 account of a rainbow seen in fog, 226; of a white one, 
 226. 
 
 Table mountain, 99. 
 
 Tables of meteorological elements for selected stations, 246; 
 for meteorological' reduction, references to, 31, 89; of 
 rainfalls, 115. 
 
 Temperature , internal, of tbe globe, 2 ; law of decrement on 
 ascending into atmosphere, 22, et seq.; average rate of 
 decrease near tbe surface, 22; of interplanetary spaces, 
 23, 36; of tbe sea at great depths, 37; at tbe surface, 
 37 ; superficial, of soil in hot climates, 38 ; annual 
 and diurnal fluctuations of, in depths below surface, 39; 
 depth, where sensibly constant, 39; of air, its diurnal 
 and annual fluctuations, 178, et seq.; diurnal fluctua- 
 tion of, in India, 179; in Ceylon, ibid.; more uniform 
 on sea than on land, 40, 180; expressions for its 
 diurnal march in Padua and Edinburgh, 181; mean, 
 how easiest obtainable, 182, 187; annual fluctuation 
 of, how deduced, 183; mean coefficients of, formulae for, 
 in different places, 183; general formula of annual 
 temperature over the globe, 184; intertropical varia- 
 tion of, 185; extent of, deviation from mean, in parti- 
 cular years, 186; of the soil, 39, 189; uniform, of 
 equatorial seas, 190; importance of observing do., ibid . ; 
 average of the whole globe in June and January, 191. 
 
 Tenerife , Peak of, cloud level on, 1 1 1 ; atmospheric pheno- 
 mena observed on, 237. 
 
 Tension of vapour, 92; diurnal and annual march of, 201, 
 202; its march, contrary to that of relative humidity, 
 200. 
 
 Terrestrial radiation, 41. 
 
286 
 
 METEOROLOGY. 
 
 Thermometer , blackened, as a measure of solar radiation, 
 13; exposed in a reflector as a measure of terrestrial 
 do., 48. 
 
 Thibet , rainless plateau of, 110. 
 
 Thomson (Dr.), bis treatise on meteorology, 11 8, bis account 
 of a great thunderstorm, 142. 
 
 Thunder , its nature, 139. 
 
 Thunderstorms , 141; of extraordinary extent and duration, 
 142. 
 
 Tides of tbe sea and air, their analogies and differences; 
 - — heat in dry air, direct and indirect effect, 77 a. 
 
 Tijlis, table of meteorological elements for, 246. 
 
 Tin, its radiating power, 47. 
 
 Toaldo , 69. 
 
 Tobolsk , summer and winter temperature of, 195. 
 
 Toronto , table of meteorological elements for, 246. 
 
 Trade winds, 59, et seq.; their habitual dryness, 111. 
 
 Tyndall (Prof.), his experiments on regelation, 119. 
 
 Vapour, aqueous, agency of, in maintaining the decrement 
 of temperature on high levels, 25; its condensation a 
 source of heat, 45, 53; laws of its diffusion, 50, an 
 agent in the transfer of heat, 51 ; action of, as a moving 
 power in meteorology, 52; its low specific gravity, 52; 
 its influence on the barometric pressure, 54; precipita- 
 tion of, in rain, snow, etc., 87, et seq.; formula express- 
 ing the tension of, 92; distribution of, 197, 203, et 
 seq . 
 
 Vapour plane, 108; its level variable, 200. 
 
 Vapour planes, several distinct ones co-existing, 205. 
 
 Vapour tension, its diurnal and annual march, 201, 202. 
 
 Vegetation, a source of electricity, 132. 
 
 Velocities of winds, 57. 
 
 Vesicles of water in clouds, etc., 92, 205, 226 note. 
 
 Vesuvius, electrical phenomena during its eruptions, 133. 
 
 Vince, his accounts of a remarkable atmospheric refraction, 
 236. 
 
INDEX. 
 
 287 
 
 Volcanoes , their effect in heating the air, 2. 
 
 Von Buck , his remarks on the difference of interior and 
 coast climates, 195. 
 
 Von Humboldt , See Humboldt. 
 
 Wall , his discovery of the electric spark, 126. 
 
 Wall, heated, its action as a mirror, 237. 
 
 Washington , U. S., table of meteorological elements, 246. 
 
 Wastdale, extraordinary rainfall at, 115. 
 
 Water, its habitudes in relation to solar heat, 37; its radia- 
 tion of heat, 37; its evaporation and condensation (see 
 Vapour, Eain, Snow, Hail, Dew, Fog, Cloud). 
 
 Water-spouts , 242. 
 
 Wave, great November, 80. 
 
 Waves of heat and cold, 39, 45; atmospheric, 75, et seq 
 instances of, traced over extensive tracts, 79. 
 
 Welsh, his balloon ascents, 22, 31; calculation of his 
 highest, 35. 
 
 Wells (Dr.), his account of dew, 46, 91. 
 
 West coasts habitually rainy, 114. 
 
 Westmoreland, rainy districts of, 114. 
 
 Whewell (Dr.), his anemometer, 81. 
 
 Whirlwinds, 241; dust, 244; African, 243. 
 
 Whiting, its radiating power, 47. 
 
 Williams, his account of ice-making in India, 49. 
 
 Wind, how produced by heating action of the sun, 58; how 
 modified by the earth’s rotation, 59; law of rotation of, 
 69, et seq.; contrary in north and south latitudes, 70; 
 mean annual velocity and direction of, how calculated, 
 82, et seq.; results of such calculations for various 
 places, 80; causes electricity by friction, 80; depen- 
 dence of the various meteorological elements on its 
 direction, 206, et seq.; Dove’s and Kamtz’s results of 
 do., embodied in formulae, 212; its average direction 
 in Europe, 217. 
 
 Winds, their general agency as distributors of heat and 
 moisture, 56; in causing oceanic currents, 56; atmo- 
 
288 
 
 METEOROLOGY. 
 
 spheric pressure requisite to produce, of different forces, 
 57; velocities of corresponding to different pressures, 
 also in breezes, gales, hurricanes, etc., 57; pressures on 
 the square foot in pounds, 57; trade, explained, 59. 
 anti-trades, 62; periodical, 64, et seq.; sea and land, 
 68; S.W. and N.E., their contrary influence, 207; belie 
 their birth-places, 209. 
 
 Winter, amount of heat received from the sun in the two 
 hemispheres, 8. . 
 
 Wolf , his period of the solar-spots, 7 ; sub-periods dependent 
 on planetary action, ibid, note. 
 
 Wollaston, on the finite extent of the atmosphere, 20. 
 
 Wool, radiating power of, 47. 
 
 Young (Dr.), his explanation of the supernumerary rainbows 
 221, et seq.; of coronas round the moon, 229. 
 
 Zach (Baron), his law of decrement of atmospheric tempera- 
 ture, 27, 32. 
 
 Zero, absolute, of temperature, 30. 
 
 Zinc, radiating power of, 47. 
 
 PRINTED BY R. AND R. CLARK, EDINBURGH. 
 
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