ELEMENTS OF ". 
 
 AGR ICULT URE 
 
 SOUTHERN S "WESTERN 
 
 ^^Tx 
 
Class __X^ 
 
 Book kjL 
 
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 CopyrightK^. 
 
 COPYRIGHT DEPOSm 
 
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 *S&^ 
 
 THE MACMILLAN COMPANV 
 
 NEW YORK • BOSTON • CHICAGO 
 ATLANTA • SAN FRANCISCO 
 
 MACMIT.LAN & CO., Limited 
 
 LONDON • BOMBAY • CALCUTTA 
 MELBOURNE 
 
 THE MACMILLAN CO. OF CANADA, Ltd. 
 
 TORONTO 
 
ELEMENTS OF AGRICULTURE 
 
 SOUTHERN AND WESTERN 
 
 BY 
 
 W. C. WELBORN, B.S., M.S., M.P.A. 
 
 VICE-DIRECTOR AND AGRICULTURIST OF 
 THE TEXAS EXPERIMENT STATION 
 
 Ncfa) gork 
 THE MACMILLAN COMPANY 
 
 1908 
 
 All rights reserved 
 
LIBRARY of CONG^IESS 
 I wo Copies KecciYt^:; 
 
 MAY 22 1908 
 
 XXC. Mu 
 
 aA! 
 
 ussA 
 
 Coi'VUIGUT, 190S, 
 
 Bv THE MACMILLAN COMPANY 
 
 Set up and electrotyped. Published April, 1908. 
 
 MANUFACTURED BY 
 
 BROCK & RANKIN. 
 
 CHICAGO. 
 
PREFACE AND SUGGESTIONS 
 
 The author feels no hesitation in taking the ground 
 that agriculture has an educational, or mind-training 
 value, fully equal to geography or history. The facts 
 presented in agriculture are quite like those of physical 
 geography in particular; the description of the develop- 
 ment of crops, live stock, and agricultural industries gener- 
 ally is the very best of history. In addition, the study 
 of agriculture has a manifest advantage in training the 
 habits of observation, as it treats of things that are about 
 us — that may be seen, heard, and felt — and therefore 
 truly educates through the environment of the pupil. 
 
 If a geography class could be taken to Mount Vesuvius 
 and could see the great volumes of ashes, cinders, and 
 lava that are belched forth, covering hundreds of square 
 miles with rich soil, what a lesson it would be in world- 
 building and what an inspiration to the whole school and 
 the whole community ! In agriculture we teach facts 
 tliat may be verified on the farm, in the garden, by the 
 roadside, and in the forest, and facts, too, of greater im- 
 portance by far to that community than the operations of 
 tlie far-away volcano. Beyond all this, agriculture will 
 impart a mass of useful information about the greatest 
 business in this country, which farmers cannot any more 
 
vi PREFACE AND SUCtGESTIONS 
 
 afford to do without than doctors could afford not to know 
 that the blood circulates. This information, put into the 
 minds of pupils generally, will be imparted in a great 
 measure to the present generation of farmers, and will be 
 reflected in better methods and better results on the farms 
 of the country. 
 
 Agriculture can without any doubt be taught as easily 
 as any other subject, if the truth is told, if it is put into 
 simple language, and is arranged in fairly logical order. 
 This book has aimed to meet these conditions, and on ac- 
 count of the want of preparation on the part of many teach- 
 ers, has a faithful list of questions at the end of each 
 chapter. No one can answ^er the questions without under- 
 standing the subjects. It is believed the questions will 
 be a great help to teachers and pupils, and will enable any 
 teacher to teach the subject quite as easily as geography 
 or history can be taught. Indeed, it is believed that most 
 teachers in country districts actually know much about 
 agriculture, although they may never have read any book 
 treating it. 
 
 The author does not believe that most country teachers 
 will have time and means to provide a large amount of 
 illustrative material in the way of a farm, live stock, 
 garden, orchard, and laboratory. Teachers of history 
 and of geography are not expected to follow any such 
 method, and their only illustrative material consists of 
 pictures, or maps and globes, of things generally removed 
 a thousand miles of distance or a hundred years in time. 
 The principles of agriculture could be taught as well by 
 the same means. Whenever a teacher is fortunate enough 
 
PREFACE AND SLTGGESTIONS vii 
 
 to have a pupil who has seen the battleliekl of Gettysburg, 
 it is never difficult to teach the history and geography of 
 that whole region to that pupil and to the whole class. In 
 teaching agriculture you teach something that all the pupils 
 and their parents know something about, and their interest 
 will be keen. An appeal to what the pupil has seen or can 
 see for himself will in a great measure compensate for any 
 lack of direct illustration. You are teaching something 
 about the pupiFs old friends and acquaintances, and you 
 are less dependent on experimental work on this account. 
 
 It is not believed that any considerable percentage of 
 the schools are in position to make agriculture more 
 of an outdoor than a class-room subject. Neither is it 
 advised in teaching this book to try to vary the order 
 of chapters taught to better fit the seasons for experi- 
 mental work. Agriculture is certainly a valuable class- 
 room study; it should be so used, and calling to mind 
 what the pupils have experienced and stimulating them 
 to find more will constitute the best experiments. Then 
 make all the suggested experiments and observations that 
 time and means will permit. Try to get still others made 
 by the patrons, who should always be consulted on account 
 of their invaluable practical experience. Remember, these 
 farmers know more than the author of your text-book 
 about many agricultural matters. 
 
 In preparing this book the author supposes that its 
 readers are acquainted to some extent with agricultural 
 matters from practice and observation. The smaller 
 details of information have been left to be got in some 
 other way, if not already known. Only the general truths 
 
viii PREFACE ANJ) srcUJESTIONS 
 
 and useful principles about the main features of agri- 
 culture have been attempted. 
 
 No attempt has been made to agree with other authors ; 
 in fact, in many very important matters, views directly 
 o[)posite to those of most agricultural writers have been 
 taken. Agriculture as a science is new . Mucli tliat we 
 believed true ten 3^ears ago has been disproved. Tlie dis- 
 credit attaching to so-called ''book farming*' no doubt 
 came about from the widespread })ublication of so much 
 matter that was untrue and hurtful to those attempting 
 its practice. The Agricultural Experiment Stations of 
 the country have given us tlie nu)st reliable agricultural 
 literature we have in the record they liave made of their 
 own research and of the practical work of farmers witli 
 Avhom they have cooperated. In ditfering with other 
 authors, most of whom wrote a number of years ago, this 
 work is in substantial agreement wdth the combined re- 
 sults of all the experiment stations, so far as these 
 results have been published. It is fully believed that in 
 this little volume enough of truth applicable to the sec- 
 tions intended to be served will be found, and enough 
 of error has been pointed out to make the book one of 
 general usefulness. 
 
 While written for the schools, this work should be no 
 less valuable for the farmer and general reader. The fact 
 that it gives useful information about agricultural affairs 
 in language easily understood, being otherwise suitably 
 arranged for school work, should make it onl}^ more 
 valuable to the farmer, wlio is a student no less than the 
 public school pupil. 
 
PREFACE AND SUGGESTIONS ix 
 
 The author has received valuable help and advice from 
 Dr. H. H. Harrington, President of the Texas Agricul- 
 tural and Mechanical College, and Dr. C. P. Fountani, 
 Professor of English, who patiently criticised the entire 
 work. He is under obligation also to almost the entire 
 faculty of the above-named institution for kind assistance. 
 
 January 13, 1908. 
 
CONTENTS 
 
 I. The Resources of the Farmer 
 
 II. The Building of a Plant 
 
 III. The Makixg of the Soil . 
 
 IV. Kinds of Soil .... 
 V. Rainfall and Productions of Texas 
 
 VI. Chemistry of Soil and of Plants 
 
 VII. The Physics of the Soil : Storage of 
 
 VIII. Bacteria or Ger:\i Life . 
 
 IX. The Botany of our Crops 
 
 X. Grafting and Budding 
 
 Xr. Seed Selection .... 
 
 XII. Improving the Land . 
 
 XIII. Rotation of Crops 
 
 XIV. Manures and Fertilizers 
 XV. Commercial Fertilizers . 
 
 XVI. Plowing 
 
 XVII. Preparation for Planting 
 
 XVIIL Irrigation 
 
 XIX. Insect Friends and Enemies . 
 
 XX. Cotton . 
 
 XXL Corn . 
 
 XXII. Wheat and Oats 
 
 XXriL Rice 
 
 XXIV. Sugar Cane. 
 
 XXV. The Sweet Potato 
 
 Water 
 
 PAGE 
 1 
 
 15 
 
 28 
 
 :n 
 
 46 
 
 52 
 
 62 
 
 «;.s 
 
 78 
 
 86 
 
 !)2 
 
 US 
 
 106 
 
 112 
 
 119 
 
 125 
 
 1:^5 
 
 149 
 
 154 
 
 162 
 
 169 
 
 17(! 
 
xu 
 
 CONTENTS 
 
 iMlAPTER 
 
 
 PAGK 
 
 XXVI. 
 
 The Cowpka and Peanut .... 
 
 181 
 
 XXVIL 
 
 1'OBACCO 
 
 18H 
 
 XXVIIL 
 
 SoKGHUM, Kafir, and Milo-Maize . 
 
 KM) 
 
 XXIX. 
 
 The Velvet and Soy Beans, Alfalfa. IIaih\ 
 
 
 
 Vetch 
 
 DM) 
 
 XXX. 
 
 The Clovers and MiNoii Croi-s 
 
 •JOl 
 
 xxxr. 
 
 Other Hay and Pastuke (trassks . 
 
 •JU8 
 
 XXXTI. 
 
 Orchard Crops 
 
 2\ry 
 
 XXX 1 1 1. 
 
 Truck Crops 
 
 227 
 
 XXXTY. 
 
 The Feeding of Animals .... 
 
 234 
 
 XXXV. 
 
 The Making of a Ration .... 
 
 2M 
 
 XXXVL 
 
 Animal Diseases 
 
 250 
 
 XXXVIL 
 
 Animal Husbandry 
 
 255 
 
 xxxviir. 
 
 Raising Horses and Mules 
 
 258 
 
 XXXIX. 
 
 Cattle 
 
 263 
 
 XL. 
 
 Hogs, Sheep, Goats, Poultry, and Bees 
 
 275 
 
 XLI. 
 
 Dairying 
 
 286 
 
 AlM'ENDIX 
 
 
 295 
 
 (Jl.OSSAUY 
 
 
 
 :J23 
 
 ]N^)^:x . 
 
 
 329 
 
LIST OF ILLUSTRATIONS 
 
 Texas Agricultural and Mechanical College 
 
 Sprouting Pea .... 
 
 Weathering of Kock, forming Soil 
 Glacier in the Alps 
 Where a Glacier Melts . 
 Trees assist in breaking Rock 
 Soil Divisions of Texas . 
 Alkali Land .... 
 
 8. Former Inhabitants of the Plaini- 
 
 9. Present-day Scene on the Plains 
 
 10. Soil Areas of the Cotton Belt 
 
 11. Rainfall Map of Texas . 
 
 12. Showing Capillary Action of Soils 
 
 13. Stirring Soil when Wet and when in Rij 
 
 14. Different Bacteria greatly Magnified 
 
 15. Tubercles on Roots of Legumes 
 
 16. Fibrous Roots of Corn . 
 
 17. Osmosis 
 
 18. Flower of the Apple 
 
 19. Lily of the Valley . 
 
 20. Steps in Budding . 
 
 21. Ring Budding for Oranges and Pecans 
 
 22. Grafting 
 
 23. The Proper Depth to plant Fig Cutting 
 
 24. Old Pecan Tree growing Paper-shell Buds 
 2o. Testing Seed 
 
 26. Pure and Impure Alfalfa Seed 
 
 27. New INIexico Date Palm .... 
 
 alit Condition 
 
 Frontispiece 
 
 PAGE 
 
XIV 
 
 LIST OF ILLUSTRATIONS 
 
 FIG. 
 
 '28. Terraced Land ....... 
 
 "29. Corn Grown on Washed and on Terraced Land 
 
 ;{(). Terraced Land and Hows ..... 
 
 ol. Best Shape for an Open Ditch .... 
 
 82. Tile Draining 
 
 33. Cowpeas and Sweet Sorghum .... 
 
 34. Hogs grazing Cowpeas 
 
 35. Fertilized and Unfertilized Cotton 
 
 36. Sandy-land Plow^ 
 
 :)7. Black-land Plow 
 
 ■'58. Steam Plow on the Plains 
 
 39. Sub-surface Packer 
 
 40. Irrigating between Rows 
 
 41. Spraying Fruit Trees 
 
 42. Boll Weevil and Larva ... 
 
 43. Different Life Sizes of Adult Boll Weevils . 
 
 44. Punctured Square containing Young Weevils 
 4."). Karly and Late Cotton in Boll Weevil District 
 4(). (lood Type of Cotton Plant 
 
 47. Poor Type of Cotton Plant 
 
 48. Rolling Fresh Cotton Bed to firm the Soil for Planting 
 
 49. Mississippi Cotton Field 
 
 50. Round Cotton Bales 
 
 51. Long and Short Staple Cotton .... 
 
 52. American Bale of Cotton as it gets to Europe 
 
 53. Corn and Cowpeas 
 
 54. Wheat planted in Loose Soil and in Soil Compacted 
 
 55. AVheat Field on the Plains 
 
 5fj. Oats and Vetch 
 
 57. Hice Field in Louisiana 
 
 58. Filipinoes plowing in Mud, prej^aring Land for Rice 
 
 59. Seeded Sugar Cane 
 
 60. Way to use a Saccharimeter 
 
 61. Cutting Sugar Cane in Louisiana .... 
 
LIST OF ILLUSTRATIONS XV 
 
 FKi. PAGE 
 
 62. Hill of Sweet Potatoes 177 
 
 63. Digging Sweet Potatoes 179 
 
 6L Spanish Peanuts 183 
 
 65. Saving Peanuts 184 
 
 66. Tobacco growing under Cheese-cloth Shade .... 187 
 
 67. Harvesting Sorghum " . . . 191 
 
 68. Field of Kafir Corn 193 
 
 69. Soy Bean 197 
 
 70. Stacking Alfalfa Hay 198 
 
 71. Red Clover 201 
 
 72. Crimson Clover 203 
 
 73. Florida Beggar Weed 204 
 
 74. Rape Field .205 
 
 75. Jerusalem Artichoke 206 
 
 76. Johnson Grass 211 
 
 77. Guinea Grass, Biloxi, Mississippi 212 
 
 78. Intensive Farming — Chinese in Hawaii grow Four Crops 
 
 at Once 215 
 
 79. Irrigating an Orchard 216 
 
 80. Well-trimmed Texas Peach Tree 217 
 
 81. San Jose Scale on Peach Trees 218 
 
 82. Cocoanut Plantation as seen in Florida, Porto Rico, Hawaii, 
 
 and the Philippines 219 
 
 83. An Apple Branch 220 
 
 84. Figs at the Texas Experiment Station 221 
 
 85. Smyrna Fig Trees, California 222 
 
 86. Grape Fruit at Beeville, Texas, Branch Experiment Station 224 
 
 87. Texas Orange Tree 225 
 
 88. Harvesting Irish Potatoes 227 
 
 89. Small Hotbed 229 
 
 90. Gathering Tomatoes . . 230 
 
 91. Cabbage Field 231 
 
 92. Southwest Texas Steers being fattened on Cactus and Cot- 
 
 ton-seed Meal . . .' 237 
 
XVI 
 
 LIST OF ILLUSTRATrONS 
 
 FIG. 
 
 
 
 I'AGE 
 
 93. Coach Type 25f> 
 
 94. Draft Type : Percheron 
 
 
 
 260 
 
 95. Zebu, or Sacred Bull of India 
 
 
 
 263 
 
 96. Dual Purpose Cattle : Devon and Red Poll . 
 
 
 
 265 
 
 97. Beef Cattle : Short Horn and Hereford 
 
 
 
 267 
 
 98. Showing Beef Cattle at the Texas Agricultural 
 
 aiul 
 
 M.- 
 
 
 chanical College 
 
 
 
 270 
 
 99 Breeds of Swine : Tarnworth and Duroc Jersey 
 
 
 
 276 
 
 100. Breeds of Swine : Poland China and Berkshire 
 
 
 
 277 
 
 101. Razor Backs for Want of Feed . 
 
 
 
 278 
 
 102. Movable Fence 
 
 
 
 279 
 
 103. Sheep and Goats 
 
 
 
 280 
 
 104. Flock of Angoras 
 
 
 
 281 
 
 105. Sheep Ranching in the West 
 
 
 
 . 282 
 
 106. Plymouth Rock Hen 
 
 
 
 . 283 
 
 107. Brown Leghorn Hen 
 
 
 
 . 28:5 
 
 108. Bronze Gobbler 
 
 
 
 . 284 
 
 109. Round Silo 
 
 
 
 . 287 
 
 110. Dairy Cows: Jersey and Holstein Dehorned 
 
 
 
 . 288 
 
 111. Cream Separator 
 
 
 
 . 290 
 
 112. Pure and Impure Milk 
 
 
 
 . 292 
 
 113. Box Churn 
 
 
 
 . 293 
 
ELEMENTS OF AGRICULTURE 
 
 SOUTHERN AND WESTERN 
 CHAPTER I 
 
 THE RESOURCES OF THE FARMER 
 
 Usually the first object of tlie farmer is to grow plants. 
 These may be used or sold, or they may be fed to animals, 
 and the animals or animal products used or sold. For 
 example, cotton may be grown and sold, and the seed may 
 be fed to cows, and milk and butter produced for home 
 use and for sale. 
 
 Plants Necessary for Man and Animal Life. — The earth 
 and the air are rich in the things needed to produce bone 
 and muscle and blood. Yet animals would starve if they 
 tried to live on rock, or earth, which is only ground-up 
 rock. Man and his servants, the other animals, cannot 
 digest rock or earth. Neither can they use to build up 
 their bodies any of the gases of the air they breathe. 
 
 Plants, however, our other servants, send their little 
 threadlike roots all through the soil. These roots twine 
 themselves about the little rocks, or soil grains, and suck 
 from them the substances they need for growth. Their 
 green leaves, too, through little openings or breatliing 
 pores, known as stomata, take in tlie gases of the air, and 
 find in these one of the most important things needed to 
 
 B 1 
 
2 ELEMENTS OF AGRICLLTURE 
 
 iiiiike them large and strong. This same element is also 
 •nbeded for the growth of our bodies, and since we can get 
 none of it from the air, we must get our supply by eating 
 plants or substances obtained from plants. So, by eating 
 and digesting the plants, we can use the materials the 
 plant roots get from the soil. 
 
 Earth, Air, and Water. — All the animal kingdom, in- 
 cluding man, is made up of the elements of the earth, the 
 air, and the water. Water is the only one we can use 
 for growth without the help of plants, but we cannot live 
 on water. If it were possible that all the plant world 
 could go on a strike, animal life perhaps could not endure 
 on the earth more than a month. 
 
 Plants purify the Air. — Our faithful servants of the 
 plant kingdom not only stand between us and starvation, 
 but also purify the air that we breathe. When we breathe 
 the air, part of the oxygen gas we take in is used in the 
 lungs to purify our blood. In its place we exhale, or 
 breathe out, a gas called carbonic acid gas. The air of a 
 closed room which contains very much of this gas is unfit 
 for breathing. 
 
 Plants use Carbonic Acid Gas. — When green leaves 
 take in air, they use the carbon of the carbonic acid gas 
 which the air contains, and give out pure oxygen. If it 
 were not for this work of plants, the whole atmosphere 
 would become so filled with carbonic acid gas as to be 
 like a small, close room. Animal life would probably 
 soon cease for want of pure air. You may ask wh}^ we 
 do not die in winter when there are few green leaves. 
 Your geography teaches that the trees are green in winter 
 
THE RESOURCES OF THE FARMER :] 
 
 throughout the Southern hemisphere, and are green in tlie 
 torrid zone all the time. Winds bring pure air to us in 
 winter, and carry away the air of our zone to be purified. 
 
 Animal Life of Use to Plants. — Animals in turn give 
 oH' from their lungs carbonic acid gas for plants. But 
 the burning of wood and coal and the rotting of leaves, 
 wood, and other vegetable matter also make this gas. 
 So the plants could live without the animals, but prob- 
 ably they would not thrive quite so well. As animals, 
 including all worms, insects, etc., die, their bodies rot and 
 add richness to the land. Earthworms and many other 
 lower forms of animal life make holes in the soil, let in 
 air, assist water to drain away, and by eating parts of 
 the soil and grinding it make it finer and richer. 
 
 Animal Manures. — The larger farm animals, such as 
 cows, horses, sheep, and hogs, eat grasses, weeds, corn, 
 and otlier foods. The horses and mules give us work ; 
 the cows, milk and butter and beef ; and the hogs, pork 
 and lard. At the same time, if the fai-myard manure is 
 saved and used on the land, the fertility of the soil will 
 be kept up and the crops will be large. 
 
 Value of Manure. — It is often true that the manure 
 produced by live stock is worth more than the cost of the 
 food eaten by them. This is true in feeding cotton seed 
 when it sells for a low price. Then certain hay crops, 
 such as peas, peanuts, alfalfa, and others, get their most 
 costly fertilizing ingredient from the air. Even when 
 these crops are cut for hay, their roots enrich the land. 
 If the hay is fed to stock, very rich manure is produced. 
 With plenty of live stock and crops like these to feed 
 
4 ELEMENTS OF AGRICULTURE 
 
 them, we would have very fertile land. These things 
 will be discussed at length later on. 
 
 QUESTIONS 
 
 What products do farmers grow ? Give examples. Why could not 
 animals hve without plants? Where do the materials that our bodies 
 are made of come from? From what different sources do plants get 
 the materials to grow with? What effect do plants have on the air 
 we breathe? Why do animals make the air better suited to nourish 
 plants? What is the name of the gas that plant leaves take in from 
 the air? How does the air become purified in winter? What effect 
 does animal life have on the fertility of the land? May animal 
 manures ever have more value than the cost of the foods the animals 
 eat? Why? Why do certain crops enrich the land rapidly? 
 
 Observation. — Did you ever notice where old horse lots or cattle 
 pens have been put into cultivation how rich the land is, and how 
 long it remains rich ? 
 
CHAl^TER IT 
 
 THE BUILDING OF A PLANT 
 
 In order to grow plants we need seed, soil, moisture, 
 air, warmth, and light. Some plants, such as weeds, and 
 even some useful plants, need no 
 sowing or cultivation. 
 
 The Seed. — A seed is generally 
 a little package of rich foodstuff 
 for young plants, containing a 
 germ, or young plant itself. The 
 germ and the food are usually dry 
 so as to keep well, and are covered 
 with a nearly waterproof coat to 
 preserve them till a suitable season 
 for growing comes. 
 
 The Seed and Root. — When the 
 weather becomes warm enough, 
 the seed is sown in moist soil, the 
 germ sprouts or swells and begins 
 to grow. The little plant uses the 
 food stored up in the mother seed 
 at first, till it can send out little roots through the soil to 
 gather food and water for itself. 
 
 The Root, Stem, and Leaf. — In the meantime the plant 
 has made a stem, and on top of this have grown some 
 
 • 5 
 
 Fig. 1. — Sprouting Pea 
 
6 ELEMENTS OF AGRICLLTL'RE 
 
 green leaves. These leaves have little opening's, and the 
 stems of the plant have little cliannels for the food and 
 water to pass up and down. As already learned, the 
 stomata of the leaves take in carbonic acid gas with the 
 air. By the aid of sunliglit the green leaf takes the car- 
 bon, combines it with water, and makes sugar, starch, 
 wood, and other materials. The leaf gives off the oxygen 
 pure for us to breathe. 
 
 What Plants are made of. — About half the weight of 
 dry plants is carbon, most of which is gotten from the 
 air. So we see the leaves are quite as useful in feeding 
 plants as are the roots. 
 
 Air, Water, and Soil as Food for Plants. — Nine tenths 
 or more of the weight of dry plants is made up of ele- 
 ments which plants get from water and air together. One 
 tenth, or generally less, is made up of materials drawii 
 from the solid earth. Burn a plant, and the part it got 
 from the air and water will go off in smoke and other 
 gases. The part that came from the solid earth will 
 remain as ashes. 
 
 When plants, or parts of plants, rot the same thing 
 happens : the part that comes from the air goes back to 
 the air, and the part that comes from the earth goes back 
 to the earth. 
 
 Plants build Animals. — The ash of plants is the part 
 that makes the bones of animals, while the sugar, starch, 
 and oils of plants produce the fat of the animal body, and 
 also supply heat to keep the body warm and force to pro- 
 duce motion and work. Most plants produce some sugar, 
 as sugar cane ; some starch, as corn ; and some oil, as cot- 
 
THE BUILDING OF A PLANT 7 
 
 ton seed. Other constituents in plants produce in ani- 
 mals muscle, fat, blood, hair, skin, etc. We will discuss 
 these things more at leugtli later. 
 
 The Main Purposes of Plants. — The main purpose of 
 every plant appears to be to produce seed, or in some 
 other way to make other plants of the same kind. Peo- 
 ple and animals sometimes consume the seed, roots, or 
 stems that would produce new plants, and sometimes parts 
 tliat would not reproduce. The new seeds are generally 
 the most valuable for food, as in the case of rice, wheat, 
 and corn. 
 
 QUESTIONS 
 
 What is a seed, and what does it contain? What provision is 
 made in every seed for the young plant to grow from it? Of what 
 use are leaves of plants? How do plants get their solid food from 
 the soil? Does a plant use all the water tlie roots take in from the 
 soil? Do plants get more of their food from the air or from the 
 earth? What common substances does the plant make out of the 
 carbon it gets from the air and the water it takes from the soil? 
 About what part of the dry weight of a plant is derived from the 
 soil? What part came from the air? Where did the other part 
 come from, and how mnch does that make of the whole? If you 
 burn a plant, where do these materials go? How nearly is rotting of 
 plants like burning them ? What part of plants makes the bones of 
 animals? What do the sugar, starch, and oils of plants produce in 
 the body of the animal? Do all plants produce some sugar, starch, 
 and oil? What parts of plants do people and animals use? 
 
 Experiment. — Weigh a bundle of dry grass; burn it and weigh 
 what is left. You can do this at school during recess. 
 
CHAPTER III 
 
 THE MAKING OF THE SOIL 
 
 The Soil and how it is Formed. — Although plants get 
 fully half of their food from the air, we cannot change 
 the air to make it better fitted for growing them. Plants 
 get almost all the other half of their food from water, 
 and all their soil food by the help of water. We can 
 supply water sometimes, and can always so work the land 
 as to make tlie rain water in the soil last a long time 
 during drought. 
 
 The soil itself affords no more than ten per cent of tlie 
 weiglit of plants, and sometimes not over one or two per 
 cent. Yet we can often so work the land and fertilize 
 it as to double our crops. 
 
 Soil made of Rock. — The earth was once covered with 
 solid rock. Now it is generally covered with decom- 
 posed rock to a depth of a few feet to a hundred or more 
 feet. This powdered material is called soil. The top 
 layer of this for a few inches is generally darker in color 
 than the deeper layers, and is called top soil, or soil, 
 while the layer under this for some distance is called 
 subsoil. The upper layer is generally dark in color be- 
 cause there is mixed with it rotting leaves, stems, and 
 roots of plants. This material is often called humus. 
 Plows generally run about deep enough to turn over this 
 top soil, leaving the subsoil unbroken. 
 
 8 
 
THE MAKIN(; OF THE SOIL 9 
 
 How the Rock was ground up. — (ieology, the science 
 Avliich teaches the past history of the earth, tells us some 
 interesting stories about how the soil was made. The 
 surface of the earth was at first covered with melted rock, 
 surrounded by air containing water vapor, as we find the 
 
 i^^i^ 
 
 
 ?4^f.''^'"'t--% 
 
 ^:^^'- 
 
 Fig. 2. — Weathering of Rock, forming Soil 
 
 air to-day. As the vapor high in the air became cold, it 
 formed rain, which fell on the hot rock. Of course the 
 rain cooled the rock and cracked it. As the rain water 
 was heated, it rose in steam, and reaching the higher 
 air, grew cold, and was again condensed into rain. 
 Aofain it fell and cooled and cracked the rocks still more. 
 Finally the rocks became cool enough for the rain to form 
 little streams, and to wash and grind the little pieces of 
 broken rock, and separate the coarser from the finer pieces. 
 As the whole surface of the earth cooled, mountains and 
 valleys, hills and hollows, were formed. Many large 
 cracks, or seams, Avere also made in the earth's crust. 
 
10 elemp:nt8 of a(;riculture 
 
 Cold weather came ; rain tilled all the crevices and 
 cracks of the rocks, and froze. You know how ice will 
 break pitchers, vases, or bottles. When water freezes, it 
 expands with resistless force. Of (jourse the rocky sur- 
 face was split by the ice. When the ice melted, the water 
 formed into swift streams, carried the broken rock along : 
 deposited bowlders here, gravel yonder, sand at another 
 place, and tine soil at still another. 
 
 Streams are steadily doing the same things to-day. 
 Rocks are still being broken throughout the mountain 
 regions by rain and ice, variation of temperature, winds, 
 and other agencies. 
 
 Early Plant Life. — Wdiile soil was thus being made, 
 lower forms of plants, like lichens and mosses^ came and 
 fastened themselves to the rocks. The roots of plants 
 seem to give out an acid that eats away, or dissolves, 
 the rock. These low forms of plants may be seen to-day 
 slowly eating away old gravestones and stone walls and 
 buildings. Plant roots will cut furrows in the surfaces of 
 flower pots. When these first plants died, they added 
 some humus to the soil and made it better. This fitted 
 the soil for higher plants. Finally, animals of the lower 
 kinds appeared, and when they died their bodies became 
 a part of the soil. 
 
 Glaciers. — At one period in the earth's history there 
 was intense cold everywhere. Much of the Avater vapor 
 of the whole air fell as snow or sleet. Whole valleys were 
 rilled with moving ice, and formed what are known as 
 i/laciers. One of these, which extended over part of the 
 northern portion of the United States, is said to have 
 
THE MAKING OF THE SOIL 
 
 11 
 
 been a thousand feet deep and a thousand miles wide. It 
 moved toward the south, tearing away rocks, and cutting 
 away parts of hills and mountains. 
 
 Fig. 
 
 Glacikk in thk Ar.rs 
 
 Most of the rocks thus collected sank to the bottom of 
 the ice mass, and scoured the solid rock of the earth until 
 they ground themselves into powder. Thus enough fine 
 rock dust was made to cover a good part of the continent 
 witli soil. This deposit, left after the melting of the ice, 
 is known as drift soil. 
 
 Stream Action. — The work of moving and sorting tlie 
 materials by the streams has never ceased. Every creek 
 or river moves rock, gravel, sand, or fine sediment. When 
 a swift stream overflows its banks, the current of the water 
 
12 
 
 ELEMENTS OF AGRICULTURE 
 
 is checked, and its gravel and sand are allowed to settle. 
 When the water gets farther aw^ay from the channel and 
 begins to run more slowly, it allows fine mud to settle. In 
 this way stiff, muddy soils are made. 
 
 
 Fig. 4.— Where a Glacier Melts 
 
 Wind-blown Soils. — Not only do ice and running water 
 move soils, but in dry countries the wind blows enough 
 dust and sand* to build up the land several feet deep. 
 Streams have been filled, railroad tracks covered, and 
 even cities have been buried by wind-blown soil. Just 
 north of the Canadian River in Hemphill County, Texas, 
 is a beautiful example of wind-formed soil. The south- 
 west wind has blown away the fine particles of soil and 
 left great mounds of coarse sand for many miles. Farther 
 north finer particles settled and formed a loam soil. Still 
 
THE MAKING OF THE SOIL IS 
 
 farther north the finest soil settled and made a silt or clay 
 soil. 
 
 Sedentary Soils. — While much soil has been trans- 
 ported from where it was first made from rock, much of 
 the earth's surface is covered by soil made from the rock 
 
 Fig. 5. — Trees assist in breaking Rock 
 
 lying just under the surface. The soil of much of the 
 black prairie land of Texas and other Southern States 
 was formed in this way. The lime rock is only a few 
 feet under the surface. White, grayish, or blue lime rock 
 powdered up and mixed with humus, or rotting vegetable 
 matter, always turns black. These soils, lying where they 
 were formed, are sometimes called sedentary soils. Those 
 moved by ice and water and wind are called transported 
 soils. 
 
14 ELEMENTS OF AGRICCLi UKE 
 
 QUESTIONS 
 
 Wiiy is it impossible to change the air so as to make it feed 
 2»lauts better? What can be done to the soil to make plants 
 grow better? Is it often profitable to furnish plants extra water? 
 Js it possible to work the land in a way to make the rainfall 
 last longer? What is soil? What is soil made of? What do you 
 call the upper part of the soil, and what the lower part? What 
 makes the soil darker in color than the subsoil? What do you call 
 rotting vegetable matter in the soil ? How deep do plows generally 
 run? What is the name of the science that teaches us the past his- 
 tory of the earth ? What was the first condition of the surface of the 
 earth? How did it become cooled? What effect did ice have in 
 bi-eaking up the rock of the earth's surface? Where is soil being 
 made at this time? What sort of plants first grew on the rocks, 
 and what effect did they have? Describe how glaciers help make 
 rock into soil. The soil made by glaciers is called by what name? 
 Explain how streams sort out different kinds of soil. Besides water 
 and ice, name any other means by which soil is moved and sorted 
 out. "\^''as the soil of the black prairies of Texas, Mississippi, and 
 Alabama transported, or is it lying where it was formed? 
 
 Experiment. — Heat different kinds of rock ; pour water on them 
 while hot. Note how many crack and break and how many can be 
 easily powdered up. Do this at recess or after school. 
 
 In winter notice how banks of ditches, streams, etc., crumble down 
 after a freeze. Make a little lime by burning chalk ; mix it well in a 
 ball of mud made of stiff clay. Let it dry, keep it, and observe it 
 from day to day. 
 
 Stir a quart of clay loam soil violently in a bucket of water ; let the 
 water rest a second or two and pour the water off into another bucket 
 and let it settle for an hour. Dry the settlings in both buckets and 
 see what kind of soil you have in each. 
 
CHAPTER lY 
 
 KINDS OF SOIL 
 
 Sand, Clay, and Loam. — We generally know a sandy 
 or clay soil when we see it. Sandy soils are made up of 
 coarse particles of rock, and clay soils of very fine mate- 
 rial, having scarcely any grain at all. Clay soils may be 
 of any color, and are generally sticky, when wet. They 
 are usually richer than sandy soils, but harder to work. 
 
 A mixture of sand and clay, especially when containing 
 a good quantity of humus, is what is called a loam. Be- 
 sides, we have clay loams and sandy loams. The loam 
 soils nearly always drain well and are easy to work; they 
 are usually richer than sandy soils and stand drought 
 l)etter. 
 
 Then we have limy soils, sometimes called calcareous 
 soils. They are made of rotten lime rock. All the great 
 ])lack prairie belts in Texas, Mississippi, and Alabama 
 are covered with calcareous soil. It is stiff and sticky 
 when wet, but crumbles into little sliotlike particles when 
 dry. If you mix a little lime with a small ball of sticky 
 clay and put it out to dry, it will crumble to powder when 
 it dries. Limy soils are generally of great fertility. They 
 often contain ten times as much plant food as sandy soils. 
 
 Arid and Semiarid Soils. — In much of West Texas and 
 north to the Canadian line and west to the Rocky Moun- 
 
 1.5 
 
16 
 
 ELEMENTS OF AGRICULTURE 
 
 tains there is so little rainfall that the soils are called arid 
 or semiarid. That means that they are not watered, or 
 only half watered. 
 
 These soils are generally loose and sandy in nature, but 
 are very productive when watered. There is no sucli 
 tiling as a poor arid soil. Soils that have plenty of rain 
 
 '•^'Galveston 
 
 Fio. G. — vSoiL Divisions of Tkxas 
 
 No, 1. Coast Prairie 
 " 2. Sandy and Clay Land mainly 
 
 of the Timber Belt 
 " 3. Lime Land 
 
 No. 4. East Cross Timbers 
 
 " 5. West Cross Tinil)ers 
 
 '• (i. Red Lands 
 
 '■ 7. Great Plains 
 
 are called humid. The reason that arid soils are so much 
 richer than humid soils is that the latter have had plant 
 food washed, or leached, out of them all through the past 
 ages. Chemical analysis shows that certain dry West 
 
KINDS OF SOIL 17 
 
 Texas soils contain twenty times as much of some of 
 the important elements of plant food as the pine-woods 
 lands of East Texas contain. Wherever these dry 
 lands are well irrigated, they become sources of great 
 wealth. 
 
 Alkali Land. — Sometimes dry lands are so full of 
 salts hurtful to crops that they are called alkali lands. 
 Alkali lands never occur in humid climates, because the 
 rain washes out the harmful compounds along with some 
 of the useful elements of plant food. 
 
 Fkj. 7. — Alkali Land 
 
 By heavily irrigating alkali land after tile draining it, 
 the excess of salts hurtful to crops is washed out of it, and 
 it becomes very productive. Carbonate of soda in excess 
 causes what is known as black alkali. Still otlier harmful 
 compounds cause what is known as wMU alkali. ■ 
 c 
 
18 ELEMENTS OF AGRICULTURE 
 
 Geological Formations. — Looking at the map, Figure 6, 
 we find tliat the state of Texas is divided into several 
 belts, according to the general types of soil in each belt. 
 
 Coast Prairies. — The coast prairies, occupying a strip 
 of level land from thirty to sixty miles wide, are generally 
 a clay or clay-loam soil, with a clay subsoil. Where the 
 larger rivers such as the Brazos, Colorado, and Nueces 
 enter the coastal plains, the soils are largely made up of 
 the rich deposits from the streams. These soils are often 
 very rich in lime, and richer also in the other elements of 
 plant food than the rest of the coast prairies. As the 
 coastal prairies reach farther west and get more and more 
 into the dry belt, the soil becomes naturally richer ; that 
 is, it contains larger amounts of plant food. So is the soil 
 deposited by the Brazos, Colorado, and Nueces rivers 
 richer than that deposited by the Trinity and Sabine, 
 because the former three rivers rise and flow through 
 drier and naturally more fertile sections than the latter 
 two. The Trinity flows through rich black land, and its 
 deposits are richer tlian those of the Sabine. 
 
 Timber Belt. — North of the coast prairies lies an im- 
 mense timber belt. This includes the long-leaf and short- 
 leaf pine areas of East Texas and the other Southern 
 States, and a broad strip of post-oak land extending far 
 southwest toward tlie Rio Grande. These areas are roll- 
 ing lauds, generally made up of sand and clay. Here, as 
 in almost all humid sections, the subsoil generally contains 
 a larger proportion of clay than the top soil. 
 
 In the eastern part of this belt, where pine timber is 
 abundant, the land is often very sandy and seldom 
 
KINDS OF SOIL 19 
 
 stitfer than clay loam. These pine lands are naturally 
 poor in plant food ; but they drain well, are warm, hold 
 moisture well, and respond remarkably to fertilizers. By 
 the help of fertilizers these thin lands produce fine crops 
 of fruits, vegetables,, tobacco, corn, and cotton. 
 
 The large area of post-oak land mentioned above also 
 seems to need commercial fertilizers in order to give the 
 best results. 
 
 There are many small patches of lime land cropping out 
 in the timber belts described, but the country has not been 
 mapped carefully enough for us to know their extent. 
 There is a considerable area of lime prairies comprising 
 parts of Wasliington, Lee, and other counties, just west of 
 the Brazos River. 
 
 Calcareous Soils. — Occupying an immense area in the 
 central part of Texas are the cretaceous, or lime, lands 
 of the state. This belt was, even before it was cultivated, 
 generally without timber, and hence it is called prairie. 
 Lime lands are usually so rich in plant food that com- 
 mercial fertilizers cannot be profitably used on them. If 
 such lands become less productive, a crop or two of clover, 
 grass, peas, or some other crop that will add humus to it 
 and loosen it uj), will make it generally productive 
 again. 
 
 It never injures strong lime land to plow it wet, be- 
 cause the lime causes it to crumble into powder, as has 
 already been explained. 
 
 Buckshot Land. — Much of the stiff land in the river 
 bottoms is of this character ; when wet it is stiff and 
 sticky, but when dry it crumbles. This kind of land in 
 
20 
 
 ELEMENTS OF AGRICULTURE 
 
 the bottoms is often called "buckshot" land, because the 
 crund:)S it breaks into are somewhat like shot. 
 
 Grand Prairie. — Tlie western part of the lime prairies, 
 known as the Fort Worth Prairie, or Grand Prairie, has 
 not so deep or so black a soil as the eastern part, or Black 
 Prairie. The lime rock of the Grand Prairie is sounder 
 and harder, and decays more slowly. Hence, the decayed 
 rock, or soil, is thinner, and often has less hum Us, and is 
 
 
 Fig. 8. — Fokmek Inhabitants of the Plains 
 
 not so dark in color. The Grand Prairie is more ele- 
 vated, more rolling, and consequently more subject to 
 wash. Much of its soil, formed through the ages past 
 from the weathering and crumbling of the rock, has been 
 washed off into the streams, and much of it into the sea. 
 
 Red Lands. — North and west of the great Black and 
 Grand Prairie belts, and between these lime prairies and 
 the Great Plains, lies a large area of soils generally red or 
 brown in color, so far as the writer has seen, and composed 
 
KINDS OF SOIL 
 
 21 
 
 mostly of sands, clays, and loams. This region was also 
 mostly treeless. This area also includes light, thin soils 
 with occasional sections rich in lime, such as the gypsum 
 deposits. This section scarcely contains such great stores 
 of plant food as the black prairies do, but it is generally 
 more fertile than the East Texas or South Texas timbered 
 lands. Ikying west and north, these lands are naturally 
 
 more fertile than the lands farther east and south formed 
 of a similar kind of rock. The influence of rainfall has 
 already been explained. It has been also well proved that 
 the lands farther north do not wear and lose their fertility 
 as the more southern soils do. As tlie soils of northern 
 climates are frozen more of the time, their plant food is 
 locked up so that it cannot waste away. It rains little 
 as far west as West Texas in winter, when crops are not 
 
22 ELEMENTS OF AGRICULTURE 
 
 oTowinor. In East Texas and the other Southern States it 
 rains much in winter, when crops are not growing, and 
 hence the hind is leached and inipoverisiied. 
 
 Chemical analysis has frequently shown that a clay 
 loam soil in Wisconsin, for instance, contains several times 
 as much lime, phosphoric acid, potash, and nitrogen in a 
 form to be used by crops, as a clay loam in Mississippi. 
 That is, the soluble plant food in the Mississippi soil is 
 dissolving and washing away throughout the warm, wet 
 winter, while in Wisconsin the soil is locked up in ice for 
 perhaps six months. The Mississippi land should grow 
 a restorative crop in winter to keep it from becoming- 
 poor. 
 
 Red Fruit, Truck, and Tobacco Soils. — Much of the East 
 Texas timber belt has sandy loam soil varying from light 
 gray to a bright red in color. The red color denotes iron 
 compounds and good natural drainage. Tliis area pro- 
 duces the line wrapper and filler tobacco of Nacogdoches 
 and Palestine, the tomatoes, potatoes, and other truck 
 crops of Jacksonville, Troupe, Henderson, Athens, Tyler, 
 and other points. This same area is becoming one of the 
 great peach-growing sections of the South. 
 
 The Great Plains. — Lying still farther west, northwest, 
 and southwest of the last area described are the Great 
 Plains. The Plains comprise a large area of level land, 
 ranfrinof from about 4000 feet hio^h in the northwest to 
 about 2500 feet in the southeast. The Plains of Texas 
 include most of the Panhandle and extend southwest to the 
 Pecos River. The soils of these plains are said by geolo- 
 gists to have been deposited in an ancient fresh-water 
 
KINDS OF SOIL 23 
 
 lake. The soils vary from light sands to dense, stiff clays. 
 In color they vary from black to red. The Plains are so 
 bare of timber, except in sheltered canyons, that one 
 might ride all day and never find a riding switch. This 
 treeless condition is probably due to annual fires that 
 swept over the country. The Plains extend north to 
 Canada and west to the foothills of the Rocky Mountains. 
 
 The soils are rich, and as the people have gradually 
 learned to cultivate them so as to conserve the twenty or 
 more inches of annual rainfall of the eastern part of the 
 Plains, farming has made splendid progress. Fine crops 
 of kafir, milo, sorghum, corn, wheat, oats, melons, etc., 
 are readily grown. The land is still mostly used for 
 grazing, but it is being rapidly cut up into small tracts 
 for farms. 
 
 West of the Pecos River. — This section is generally 
 rather mountainous and rough, but it contains many fer- 
 tile valleys. With irrigation these are, of course, very 
 productive. So far there has been no large development 
 of farming in this region, except in the Pecos and Rio 
 Grande and other river valleys. In the more elevated 
 mountain valleys of this region apples and grapes thrive 
 wonderfully under irrigation. Some day this region will 
 rival any other part of the world in the production of 
 these and other fruits. 
 
 Cross Timbers. — It will be noticed from the map that the 
 timber area of Texas extends up Red River far west of Fort 
 Worth, and one narrow belt comes southward between 
 Dallas and Fort Worth to Waco, and the other extends 
 from considerably west of Fort Worth, and reaches nearly 
 
24 ELEMENTS OF AGRICULTURE 
 
 to Austin. These are called the East and West Cross 
 Thnbers. The land in these belts is sandy, and resembles, 
 in every essential particular, the large post-oak belt, in 
 South Texas, except that it is generally more sandy. Like 
 the latter, the land in the cross-timbers sections will no 
 doubt respond profitably to the use of commercial ferti- 
 lizers. These lands produce fine fruits, vegetables, and 
 potatoes, as well as general crops. The cross-timbers 
 lands were at one time considered almost worthless, but 
 they are now held in high esteem. 
 
 Soils of the Cotton States. — Figure 10 shows the different 
 soils of the whole cotton belt as mapped by the Depart- 
 ment of Agriculture. It will be seen that the pine flats 
 and pine hills appear in all states touching the sea. The 
 lands marked "oak" also appear in most of them. These 
 lands are often spoken of as oak, hickory, and short-leaf 
 pine lands, as all these growths generally appear except 
 in the western part of this area in Texas, where the 
 short-leaf pine disappears. Black prairies occur only 
 in Texas, Mississippi, Alabama, and a little corner in 
 Arkansas. There are also considerable areas of lime- 
 prairie in Oklahoma not shown on this map. The deep 
 Red Lands appear only in Arkansas, Oklahoma, and 
 Tennessee, and the Piedmont includes the more elevated 
 regions of Alabama, Georgia, and the Carolinas. Alluvial 
 lands are usually situated along the larger rivers, espe- 
 cially the Mississippi. The two classes of Pine lands, 
 the Oak, the Piedmont, and Sand Hills, are largely ferti- 
 lized with commercial fertilizers, especially in the older 
 states. These lands are not of high natural fertility, but 
 
KINDS OF SOIL 
 
 25 
 
 g^ il ^S I oS o2 th tl 
 
 <- -•< -q; i uiz Zj ",.:; "-^ 
 
 rfl S5 ^2 2 -=2 5x sp 3| 
 
26 ELEMENTS OF AGRICULTURE 
 
 are very susceptible to high improvement. Tliese and 
 the Red Lands are hirgely of the same nature. In fact, 
 most of the agricultural land of the earth is made up of 
 sands, clays, and loams not very rich in lime. Where the 
 sands and clays are mixed, making loams, the soil drains 
 well, warms up early, works easily, holds moisture well, 
 pays for fertilizing, and, although not naturally ricli, 
 makes profitable farming and gardening land the world 
 over. 
 
 Light and Heavy Soils. — Sandy land is often called 
 light land, although it may weigh, when dry, one hundred 
 pounds to a cubic foot, while clay land Aveighing, say, 
 seventy-five pounds to a cubic foot, is called heavy land. 
 Sandy land is called light because it is easy to work. 
 Clay land is sticky and tough, and is called heavy because 
 it is hard to work. 
 
 Light sandy lands are warm and good for earl}^ truck 
 crops, watermelons, etc., while heavy clay lands are good 
 for grasses, wheat, rice, and other crops. Corn, cotton, 
 oats, sorghum, and many other crops do equally well on 
 various kinds of soil, if the soils be equally rich and in 
 suitable condition. 
 
 QUESTIONS 
 
 AVhat is the difference between sandy and clay soils? Which is 
 generally richer, sandy soil or clay soil ? What do we call a mixture 
 of sand and clay? What do you understand by calcareous soils? 
 Where do yon find these? What makes such soil crumble when it 
 dries? Are these soils generally fertile? Define arid, semiarid, and 
 humid soils. Why are arid and semiarid soils generally richer than 
 humid soils? What are alkali lands? What can be done to get rid 
 
KINDS OF SOIL 27 
 
 of alkali ? Draw a map of Texas and mark the diiferent geological 
 divisions. Describe the coast prairies. Will the soils be richer along 
 the Brazos River where it flows through the coast prairies than the 
 other coast prairie land? Explain why. AVhat varieties of lands 
 are there in the main timber belts of Texas? What chai'acter of 
 land is found in the [)ine timber belt of the Southern States? Under 
 wiiat circumstances are pine lands good farming lands ? What do 
 you understand by buckshot land? What is the difference between 
 the eastern part of the Texas lime lands and the western part? De- 
 scribe the red land areas of Texas. Why is land North and West 
 naturally richer than the land South and East ? Describe the Great 
 Plains. What kind of soils are found on the Great Plains? What 
 kind of land is found in Cross-timbers areas of Texas? Why is 
 sandy land called liuht land? 
 
CHAPTER V 
 
 RAINFALL AND PRODUCTIONS OF TEXAS 
 
 Figure 11 is a map of the State of Texas, showing 
 tlie anioimt of annual rainfall in tlie different belts. In 
 extreme East Texas fifty or more inches 'fall on the aver- 
 age during the }'ear ; in another broad belt, forty inches 
 or more ; in another rather narrow strip west, thii'ty 
 inches ; then in a very broad belt extending west of the 
 101st Meridian, twenty or more inches ; west of this ten 
 to twent}^ inches fall. These lines of rainfall curve east- 
 ward as we go north to the Canadian line. But northern 
 latitudes demand less rain than southern latitudes, be- 
 cause of shorter summers, cooler temperatures, and less 
 evaporation. Western Nebraska should make as good 
 crops on fifteen inches of rain as Texas can on twenty 
 inches. 
 
 Fortunately, in West Texas and the semiarid belt 
 generally, where rainfall is light, a large proportion of 
 the total falls in the spring and summer, when it is most 
 likely to be needed. In East Texas and farther east, 
 much of the rain falls in winter. 
 
 These rain belts go far toward determining the kinds 
 of crops that can be grown, and will be referred to 
 frequently. 
 
 Elevation and Production. — Texas varies in elevation 
 from sea level to about five thousand feet, not considering 
 
 28 
 
RAINFALL AND PRODUCTIONS OF TEXAS 
 
 29 
 
 the mountain peaks. Elevation influences climate quite 
 as much as latitude does. A small portion of Texas about 
 the mouth of the Rio Grande is truly tropical. All 
 the coast country is subtropical. Here we find the 
 
 
 a'' ( 1 U. lUl.'.ijl lUTo I 
 
 i--' \ \ L>^Galveston 
 
 Fig. 11.— Rainfall Map of Texas 
 
 No. 1. 50 inches and over 
 " 2. 40 to 50 inches 
 " 3. 30 to 40 inches 
 
 No. 4. 20 to 30 inches 
 " 5. 10 to 20 inches 
 
 sugar cane, rice, bananas, and oranges, while the western 
 part of the Panhandle has exactly such a climate as grows 
 sugar beets to perfection in Colorado and Michigan. It 
 is mainly the elevation of the Panhandle that gives it the 
 temperature suitable for the sugar beet. 
 
30 ELEMENTS OF AGRICULTURE 
 
 lietween the extremes, Texas has fine climates for wheat, 
 oats, corn, cotton, and a great variety of other crops. 
 
 Wheat will thrive farther west than corn, because it 
 re(|uires less rain. Still farther west sorghum, kafir 
 corn, milo-maize, etc., are grown, largely because the 
 land is so dry that Indian corn is not a certain crop. 
 Cotton flourishes in both wet and dry sections if there 
 is warmth enough. Far to the west, alfalfa, Avhen irri- 
 gated, revels in the abundance of plant food and the fine 
 mellow, porous soil. Of course, the dry, rich soils of the 
 Pecos, the Rio Grande, the Arkansas, and many other 
 valleys, when irrigated, grow a great variety of crops to 
 perfection. 
 
 QUESTIONS 
 
 Draw a map of Texas and show the different rain belts. About 
 liow much rain falls in each belt? How many different kinds of 
 climate are found in Texas? What effect does elevation above sea 
 level have on climate? What effect does climate have on corn pro- 
 duction ? AVhat crops do well where it is too dry for Indian corn? 
 
CHAPTER YI 
 
 CHEMISTRY OF SOIL AND OF PLANTS 
 
 The Elements of Matter. — We have several times referred 
 to elements. An element is the simplest form of matter. 
 Iron and gold are elements. Oxygen is an element. 
 Elements may be called the A B C of matter. Just as 
 twenty-six letters may be combined so as to form many 
 thousands of words, so less than one hundred elements 
 unite in various ways to form every substance in exist- 
 ence. Some of these elements are solids, one is a liquid, 
 and some are gases. Iron rust is not an element. It is 
 a substance formed by the union of iron and oxygen. 
 The chemist can separate the iron rust into its elements 
 and thus obtain pure oxygen and metallic iron again. 
 Water is a substance formed by the union of oxygen 
 and hydrogen in the proportion of two parts, by volume, 
 of hydrogen to one of oxygen. The water thus formed 
 may be separated into these gases again. Such a 
 union of two or more elements is called a chemical 
 Gomfound. 
 
 Chemical and Physical Changes. — When water evapo- 
 rates, or when it forms steam, it is not then separated 
 into oxygen and hydrogen, but merely divided into fine 
 particles of water, and each particle floats in the air. This 
 is a physical change in the water. The formation of ice 
 
 31 
 
32 ELEMENTS OF AGRICULTURE 
 
 is also a physical change. Filing iron into dust produces 
 only a physical change, just as breaking a piece of iron in 
 two. Powder some chalk into dust, and you effect only a 
 phydcal or mechanical change. Each particle of dust is 
 as pure chalk as that you had before. If you pour some 
 strong vinegar on the chalk, it will boil, get hot, and con- 
 sume the chalk, forming new compounds in no way like 
 chalk or vinegar. If we cut wood, a physical or mechani- 
 cal change is produced. If wood burns, a chemical change 
 is produced. When wood burns, another chemical ele- 
 ment, the oxygen of the air, comes in and unites with 
 the elements of the wood, and additional compounds are 
 formed, all of which are entirely different from the origi- 
 nal wood. 
 
 Chemical changes completely alter the substances. A 
 union of oxygen and hydrogen gases forms water, a 
 liquid. Two gases may form a solid when united, or 
 they may form a liquid, or another gas. Two substances, 
 poisonous in themselves, may unite «i.nd form a harmless 
 compound ; or two substances, harmless in themselves, 
 may form a deadly poison. Common salt is made of a 
 metal called sodium and a gas called chlorine ; both of 
 these elements are poisonous before uniting. 
 
 Plants as Chemists. — Plants are skillful chemists. Out 
 of water and carbon plants manufacture sugar, oil, woody 
 fiber, etc. From carbon and water, with a little nitro- 
 gen, phosphorus, and sulphur from the soil, plants pro- 
 duce the most complicated compounds found in plant and 
 animal bodies. 
 
 Elements found in Plants. — When plants are analyzed 
 
CHEMISTRY OF SOIL AND OF PLANTS 33 
 
 (that is, separated into their elements), about fifteen 
 elements are found in them, as follows : — 
 
 carbon sulphur potassium aluminum 
 
 hydrogen phosphorus sodium silicon 
 
 oxygen magnesium iron chlorine 
 
 nitrogen calcium manganese 
 
 The sodium, manganese, aluminum, silicon, and chlorine 
 are perhaps not necessary for plant growth, but plants 
 will not grow in the absence of any one of the other ten 
 elements. All plants use the same elements : but they 
 do not use them in the same proportions. 
 
 Where Elements of Plants come From. — Of these ten 
 elements necessary for plants, the air supplies the carbon ; 
 the water the hydrogen and oxygen, and the soil all the 
 others. Some plants, however, can get nitrogen from the 
 air circulating in the soil. 
 
 Sunshine. — The sunshine adds nothing to build up the 
 plants. Like a lire in the furnace of a boiler, it furnishes 
 heat that causes the work to be done. The warmth of 
 the sun causes many chemical changes to take place in 
 the soil and in the plant. Without the warmth and light 
 of the sun nothing could grow, nothing could live. When 
 coal burns, it gives out heat. The energy that produces 
 the heat in the coal was supplied to the trees perhaps 
 millions of years ago by the heat and light of the sun, and 
 these trees afterward formed the o;reat coal beds. A sfi^eat 
 waterfall like Niagara produces energy to run railroad 
 trains and factories, and to light cities, but the heat- 
 energy of the sun raised the water from the sea and put 
 
34 ELEMENTS OE AGRICULTURE 
 
 in motion the wind that carried it to the watershed of the 
 river ; so that, after all, tlie work of the water was made 
 possible by the work of the sun, the great source of all 
 work. 
 
 Abundance of Most Elements. — Only two or three of 
 the elements of plant food furnished by the soil are ever so 
 scarce as to prevent the normal growth of plants. Phos- 
 phorus and nitrogen are most often scarce. In much of 
 the sandy and loamy lands of the South neither of these 
 elements exists in sulhcient quantities to raise good crops. 
 Hence fertilizers are used. Potassium also may be scarce 
 in very sandy or very poor lands. Lime may occasionally 
 be needed in fertilizers, but not often. 
 
 Most of the value of commercial fertilizers or barnyard 
 manure is due to the nitrogen, phospliorus, and potassium 
 which they contain. A wagon load of barnyard manure 
 may contain no more than thirty pounds of these valuable 
 elements, but even this amount gives it high value. 
 
 Fertilizing Elements found Combined. — These elements 
 ai-e always united with other elements in soils and fer- 
 tilizers. About four-fifths of the air is pure nitrogen, but 
 in the gaseous form it is of no use to most plants. But 
 combined with oxygen and sodium, it forms sodium 
 nitrate, a solid substance soluble in water. In this com- 
 ptmnd it is a s[)lendid fertilizer. 
 
 Phosphoi'us burns in air, and hence cannot be used in 
 the pure state. Combined with oxygen, calcium, and 
 water to form calcium phosphate, an important constitu- 
 ent of bones, it is easily handled and is an excellent 
 fertilizer. Bones, which contain about twenty-five per 
 
CHEMISTRY OF SOIL AND OF PLANTS 35 
 
 cent phosphoric acid in this fonn, are fine fertilizers. 
 Potassium will burn in water or air, and is consequently 
 not found i)ure in nature. Combined with ox3'gen and 
 sulphur into potassium sulphate, or with chlorine into 
 potassium chloride, it is easily handled as a fertilizer. 
 Wood ashes are rich in potash (one of the substances 
 that make soap when mixed with grease), and mainly 
 for this reason ashes may be good fertilizers ; they also 
 contain some phosphoric acid and lime. Fertilizers will 
 be discussed in a later chapter. 
 
 QUESTIONS 
 
 A\'liat is a chemical element? (iive an example of an element. 
 About how many elements are there? What substances do the differ- 
 ent elements nuike up? What is water made of? AVhat are the 
 elements of iron rust? Are iron rust and water elements or com- 
 ])ounds? Can water be separated into its elements? If water is 
 frozen into ice, is that a chemical or physical change? If you powder 
 clialk, is that a chemical or physical change? If you pour vinegar 
 on i>owdered chalk, what sort of a change takes place ? If wood burns, 
 what sort of a change is produced? Which makes the most complete 
 change in substances, chemical or physical changes? What do i3lants 
 use for making sugar, starch, and oil? Can chemists produce sugar 
 from these substances ? Can j)lants j)roduce still other substances 
 tluit chemists cannot make? How many elements are found in 
 ]>lants when they are analyzed? Name some of the more impor- 
 tant ones. Do all plants need the same elements for growth ? Do all 
 ])lants use the same elements in the same proportion? What effect 
 does the sun have on the growth of plants? AVhere did the heat of 
 burning coal first come from? Explain what the sun had to do with 
 making a waterfall. How many elements sometimes get scarce in 
 the land so that crops cannot grow well ? What do we do to supply 
 these scarce elements? Name the two elements that are most often 
 scarce. What other two occasionally are not present in sufficient 
 
36 ELEMENTS OF AGRICULTURE 
 
 quantity? Why do we not find phosphorus pureV What tVrtili/er 
 ingredient is found in bones? 
 
 Experiment. — Heat chalk and see if you can make lime. Stir a 
 good quantity of this lime in water and let it stand awhile. Tour 
 the clear liquid off and blow your breath through it, using a tubt^ or 
 hollow straw. Note the milky appearance of the liquid. See if 
 you can settle some of this chalk and collect it. 
 
 Put some zinc in a little bottle of strong hydrochloric, or muriatic, 
 acid, which you can get at the drug store. See if gas given off at the 
 mouth of the bottle will burn. If there is enough of it and the neck of 
 the bottle is small enough, it will burn. Being hydrogen gas, it will 
 form water when it burns by uniting with the oxygen of the air. ' Be 
 careful in this experiment, as a small explosion may occur. 
 
 Heat a little ammonia; hold a rod wet with hydrochloric acid in 
 the uases rising and note result. 
 
CHAPTER VII 
 
 THE PHYSICS OF THE SOIL: STORAGE OF WATER 
 
 Soil a Storehouse for Plant Food. — The soil made up, 
 as we liave seen, of ground-up rock mixed with humus, 
 or decaying vegetable and animal matter, is a storehouse 
 of plant food. Even moderately g(^od land will have in 
 a foot of depth enough nitrogen, phosphoric acid, and pot- 
 ash to supply crops for two or three hundred years or 
 more, but the roots of most plants feed to a depth of four 
 or five feet. Since plants can use only soluble matter, 
 and shice plant food becomes soluble ver}^ slowly, lands 
 having a large quantity of plant food may sometimes 
 become unproductive and need fertilizing. 
 
 Soil a Storehouse for Water. — Tlie soil stores rain-water 
 and gradually gives it up to the plants. Sometimes soils 
 are known to hold water enough to nourish plants during 
 a six months' drought. Ordinarily crops begin to suffer 
 when they go without rain for three weeks or a montli. 
 Crops need an immense amount of water. A mature 
 corn stalk of large size may be said to have used during 
 its lifetime about two barrels of water. The production 
 of one pound of dry hay, or otlier dry plant body, requires 
 the use of about 400 pounds of water. Most of this water 
 is evaporated from the leaves. 
 
 Water-holding Power of Soils. — Clay soil may often 
 hold forty per cent or fift}^ per cent of its own dry weight 
 
38 ELEMENTS OF AGRICULTURE 
 
 of water and not be wet enough to allow any water to 
 drip from it. We call this water soil-moisture. If a 
 cubic foot of dry clay soil weighs 75 pounds, it will hold 
 30 to 37.5 pounds of water, and will weigh 105 to 112.5 
 pounds when thoroughly moist. A sandy soil will barely 
 hold twenty per cent of its weight of water. A cubic 
 foot of dry, sandy soil weighing 100 pounds will hold 
 20 pounds of water, and will, therefore, weigh 120 
 pounds when thoroughly wet. Dry humus will some- 
 times hold twice its weight of water. Hence, if soil 
 has plenty of humus in it, it will hold more water and 
 stand drought better. Such is the case with new 
 lands, or old land after peas or other restorative crops 
 have been grown on it,- or land that has been in pasture 
 a few years. 
 
 A clay soil may hold in a depth of four feet ten indies 
 more water than does sandy soil. Ten inches of water 
 would be equal to ten big rains. It would be supposed 
 that clay soils would always stand drought well, and sandy 
 soils would always suffer worst from drought. This is 
 not always so. Sandy soils generally suffer more than 
 clay soils, but sometimes the clay soils suffer more. 
 Sandy land will come nearer giving up all the water 
 in it than clay land will. Crops can use the water from 
 the sand until the supply gets as low as five per cent. 
 In clay, plants can hardly live after the supply of water 
 gets below twelve or fifteen per cent. 
 
 Clay is often so wet in early spring that roots cannot 
 go deep, and when a drought comes, the crops burn up. 
 Clay land is quite sticky when wet, and if plowed wet 
 
THE rilYSICS OF THE feOU. 
 
 89 
 
 and dried suddenly by the sun, will be cloddy and very 
 hard to get into good condition. Wlien very dry, it 
 shrinks and cracks, thus breaking plant roots and c;i us- 
 ing tlie plants to suffer severely from drought. 
 
 A loamy soil with a good percentage of liunius will 
 generally stand drought better than clay or sand. Loams 
 also drain nearly as well as sand and can be worked almost 
 as easilv. A good loam 
 contains nearly all the 
 advantages and but few 
 of the disadvantages of 
 sandy and clay soils. 
 
 Kinds of Water in the 
 Soil. — In a moist soil a 
 thin film, or sheet, of 
 water surrounds each 
 grain, but there are small 
 spaces between the grains, 
 and will admit air 
 
 Fig. 12. — Showing Capillary 
 Action of Soils 
 
 That is, the soil is porous 
 Tlie water held as moisture is called 
 capillary ivater. It moves about in the soil by capillary 
 action. In a dry time water rises in this way from below 
 to supply plants. A lamp wick raises oil by the same 
 means. If you will insert some little glass tubes in a 
 vessel of water, you will see the water rise in the tubes. 
 The smaller the tubes, the higher the water will rise. 
 This is capillary action. Capillary water, or moisture, 
 is the kind of water most beneficial to crops. As smaller 
 glass tubes will cause water to rise higher than larger 
 ones, so a soil witli small grains, like clay or clay loam, 
 having smaller spaces between the grains, will cause 
 
40 ELEMENTS OF AGKICl'LTURE 
 
 water to rise higher in time of drought than coai'se sandy 
 soil will. But since the sandy soil has large grains and 
 large tubes, or poi-es, between the grains, capillary water 
 will move faster in sandy soil than in clay soil. We have 
 all noticed that rain water sinks into sandy soil faster 
 tlian it does into a clay soil. 
 
 Ground Water. — If we dig deep down into the soil, say 
 thirty or forty feet, we find standing water, as in wells. 
 This is called ground water, or the water table. Some- 
 times we find ground water within a foot of the surface. 
 When the })ore spaces of the soil are thus filled with 
 water, air cannot enter, and roots of most plants cannot 
 grow. Hence the necessity of draining the land. Ground 
 water may remain near the surface for a short time with- 
 out doing much luirm. In most soils, crops would never 
 suffer from drought if ground water remained about four 
 feet from the surface. Enough of the ground water 
 would be drawn up by capillary action to moisten the 
 soil and supply the crops. But when the ground water 
 is thirty or forty feet deep, it probably does not greatly 
 benefit the creeps. 
 
 Hygroscopic Water. — Dust, apparently dry, contains 
 •some water, as may be proved by heating a weighed 
 (j^uantity of it to the boiling temperature of water, and 
 then weighing it again and noting the difference in 
 weight. This is called hygroscopic water. Hygroscopic 
 water is of little or no value to crops, as it can hardly 
 be used by most plants. Hay, corn, flour, cotton-seed 
 meal, and most other dry substances contain about ten per 
 cent of moisture that may be driven off by heat, but they 
 
THE PHYSICS OF THE SOH. 41 
 
 will regain the same amount of moisture from the air 
 ^\hen they get cold. 
 
 Importance of Water. — For each pound of soil food 
 used by crops from 4000 to 10,000 pounds of water are 
 needed, most of it being evaporated from the plant 
 leaves. Some of this water is evaporated from the sur- 
 face of the ground, and a little is used to help build up 
 the plant. It can be seen from this Jiow^ very important 
 it is to supply plenty of water either by irrigation or by 
 so Avorking the land as to make it hold and furnish the 
 crops the greatest amount of rain water. Water is not 
 only an important food for crops, but it is the life blood 
 of plants, as it carries all food into and tli rough the 
 plants. 
 
 Green or Succulent Plants. — Every green plant, or vege- 
 table, is largely composed of Avater. Green grass, corn, 
 sorghum, etc., contain seventy-five to eighty-live per cent 
 of water. Melons, strawberries, cucumbers, and many 
 other fruits and vegetables contain ninet}^ per cent or 
 UKH'c of water; Irish potatoes, eighty per cent, and sweet 
 potatoes, seventy per cent. Hay, even when dry enough 
 to stack or house, contains thirty to thirty- five per cent 
 <»f water. Yoti have noticed corn and sorghum wilt and 
 droop on a hot afternoon; this is because the water is 
 evaporating from the leaves faster than the roots can take 
 it in from the soil. At night evaporation is not so fast, 
 and tlie roots catch up with their work. 
 
 Wet Soils too Cold. — In speaking of water for crops, we 
 mean water in the form of capillary moisture. A soil full 
 of standing water will neither water nor feed most crops 
 
42 
 
 elemp:nts of agriculture 
 
 to the best advantage, because it is too cold. All soils in 
 our climate are too cold in early spring, and crops cannot 
 grow until the ground is warmed by the heat of the sun. 
 Even seeds will not sprout or germinate until the ground 
 has been somewhat warmed. It requires five times as much 
 
 Fk;. ].!. — S'l IRKING Soil whkn Wet and when in Right Condition 
 
 heat to warm a pound of water one degree as it does to 
 warm a pound of moist, sandy soil one degree. Therefore, 
 if a soil is full of water, it takes a loner time for the sun 
 to warm it up. Hence, land in sections where winter 
 rainfall is heavy should be handled in a way to get rid of 
 water before the spring. 
 
 Evaporation produces Cold. — Again you have noticed 
 that wet clothes in windy weather make you very cold. 
 The water evaporates, or dries off, and takes up the heat 
 
THE PilVSICS OF THE SOIL 43 
 
 from your body. That iiuikes yoa cold. So a soil full of 
 water has been found to lose from its surface by evapora- 
 tion several times as much water as a soil that contains 
 only the proper amount of moisture. Therefore the wet 
 soil will be much colder than a moist soil. 
 
 A very wet soil has sometimes been observed to evapo- 
 rate an i7ich depth of water a week more than a moist soil. 
 The heat required to evaporate this amount of water from 
 an acre of land would melt 600 tons of ice. The cold 
 produced by evaporating this quantity of water would 
 convert over 500 tons of well-water into ice. Hence it 
 is that a thermometer stuck into a very wet soil often 
 shows a temperature 10 degrees lower than it does when 
 put into a well-drained soil of the same kind. It need 
 not be wondered at, then, that corn and cotton will fre- 
 quently remain small and yellow on undrained soil. Corn 
 and cotton will not grow at 50 degrees Fahrenheit, but 
 they grow well at 60 degrees. A plant may stand with 
 its roots bathed in water and be able to use but little of 
 it. In fact, the large amount of water in the soil, and 
 the evaporation from it, may make tlie plant so cold that 
 its sap will not flow. To prevent evaporation of moisture 
 in summer and make cro[)s stand drought, land is cultivated. 
 The compact condition of the soil is broken so moisture 
 cannot be drawn up to the surface. Cultivating three 
 inches deep saves the moisture better than a less depth. 
 
 Least Amount of Water for Good Crops. — It has been 
 found that about the least amount of water required to 
 make crops is four inclies in depth for each ton of dry 
 material in the crop. On tlie Crreat Plains, where about 
 
44 ELEMENTS OF A(;HICULTURE 
 
 12 or 15 inches of rain can generally be counted on dur- 
 ing the growing season, the land may be so worked that 
 it will make three or four tons of hay to the acre ; and if 
 the rainfall were conserved in the best manner, probably 
 50 or 60 bushels of corn could be made to the acre. To 
 furnish water to plants we want a moist soil but not a 
 wet one. 
 
 Drainage is such an important question that it will be 
 discussed in a separate chapter, as will also the subject of 
 cultivation as a means of saving moisture. 
 
 Dark-colored Soils Warm. — Of soils of the same com- 
 position and equally well drained, those that are dark in 
 color will get warm earlier in the spring. You have 
 noticed that black clothes are much warmer in the sun- 
 shine than light-colored clothes. The dark-colored cloth- 
 ing allows the sun's heat to penetrate and reach the body, 
 while white clothing reflects the heat. So dark soils 
 absorb the sun's heat more readily than do light-colored 
 soils. 
 
 QUESTIONS 
 
 Where is the great storehouse of plant food? Suppose all the nitro- 
 gen, phosphoric acid, and potash in the land could be used by croj)s, 
 would the land make very many crops? Why do lands become ex- 
 liausted ? How is water for plants kept over from one rain to another? 
 Mow long do plants sometimes do without rain ? How long can most 
 field crops do without rain and not suffer? How much water will a 
 big corn stalk use during its lifetime? To produce a pound of dry 
 hay, how much water must the pl|ints use? Which will hold the most 
 water, clay land or sandy land ? Why will plenty of humus in the 
 land make it hold water better ? Wliich will give up its water to plants 
 most completely, clay land or sandy land? Why will clay land not 
 always stand drought better than sandy land ? Explain what is meant 
 
THE PHYSICS OF THE SOH. T5 
 
 by capillary water in the soil. What do you understand by the ground 
 water of the soil? How near the surface does the ground water 
 have to come to be harmful? How is ground water got rid of? 
 p]xplain hygroscopic water. How could you compare the water 
 plants use to the blood in our bodies? What is a succulent plant? 
 How much of watermelons and strawberries is water? How much 
 more heat will it take to warm a pound of water than a pound of soil ? 
 What other reason is there for wet soil to be cold ? To evaporate an 
 inch of water from an acre would use up how much heat? How much 
 higher temperature can often be found in drained than in undiained 
 soil? About how many inches of rain are required to nuike a ton of 
 dry crop on an acre? AVhy are dark -colored soils w^ai iner than light- 
 colored soils ? 
 
 Experiment. — Grow a stalk of corn oi- other vigorous plant in a 
 box of soil at the schoolhouse or at home. Cover the top of the soil 
 with a piece of blanket or some material to see that water cannot 
 evaporate from the surface. Weigh box and contents from day to 
 day, and note losses in weight, which will represent evaporation from 
 the corn leaves. Fill lamp chimneys as shown in Fig. 12 with different 
 kinds of dry soil. Tie cloth over each and immerse ends<in pan of 
 water and watch rise of capillary water in each. 
 
 Grow corn or other plants in cans with no drainage holes, and in 
 cans with holes in the bottom. Water both liberally and note results. 
 
 Weigh potatoes, green grass, fruits, etc. Slice and dry them. 
 Note losses and calculate percentage of water originally contained. 
 
 W^eigh different kinds of well-dried soil after being put into pots. 
 Wet them and let excess of water drip as long as it will. Then weigh 
 again and note percentage and amount of water each kind holds. 
 
 Keep one box of soil excessively wet for some days and another 
 box about right for growing plants. Keep them in the sun. Insert 
 a thermometer three inches deep in each soil at midday and at 
 8 o'clock in the morning and note differences. Allow a crust to form 
 on two boxes or pots of soil. Spread an inch layer of coarse dry sand 
 on one. Weigh each from day to day and see w^hich one loses 
 moisture most rapidly. 
 
 All of the above are suitable school exercises. 
 
CHAPTER YTII 
 
 BACTERIA, OR GERM LIFE 
 
 Work of Bacteria. — As is well known, little forms of 
 life, plant and animal, too small to be seen except with a 
 powerful microscope, play an important part in nature's 
 processes. The souring of milk is caused by millions of 
 
 little living beings. The 
 decay of fruit and the 
 spoiling of meat are also 
 caused by minute forms 
 of plant life. Some kinds 
 of bacterial life bring 
 disease, and doubtless 
 other kinds assist us to 
 get well. It is entirely 
 likely that we have more 
 friends than enemies 
 among these little beings, 
 and without them we could not live long. Only a year 
 or two ago the French people took a vote on whom the}^ 
 regarded the greatest man that ever lived. A man named 
 Pasteur was voted first, and Napoleon stood seventh- Pas- 
 teur's fame comes from his study of microscopic life. Pie 
 learned to prevent and cure by inoculation human and 
 animal plagues. He learned to prevent charbon and 
 rinderpest of cattle and to cure hydrophobia of man. 
 
 40 
 
 Fig. 14. — Different Bacteria 
 greatly magnified 
 
BACTERIA, OR GERM LIFE 47 
 
 Influence on Industries. — Patting up fruit and sirup 
 in cans is merely heating and killing the germ life in 
 the material to be canned, and then sealing it up so the 
 air cannot enter and bring more germs into it. Meats, 
 milk, vegetables, fruits, and most of the products likely 
 to spoil may be preserved in this way. In making bread, 
 wine, vinegar, alcohol, cheese, butter, and in many other 
 industrial processes of the household, the farm, and the 
 factory, we are directly de23endent on our little servants, 
 the bacteria. 
 
 Effects on Soils and Manures. — It has long been known 
 that the bacteria play an important part in making soils 
 productive, and in bringing about changes in animal ma- 
 nures. The organic matter, the remains of plant and 
 animal bodies, in the soil, rots because it is attacked and 
 eaten by myriads of microscopic beings. As this organic 
 matter decays, it furnishes plant food to the growing crop. 
 Many other chemical changes that take place in the land 
 are helped or hindered in the same way. Barnyard 
 manure is full of germ life. It has often been noticed 
 that manure loses half its value in six months' time. 
 Certain bacteria attack it, and convert its nitrogen into 
 nitric acid, whicli washes away in the rain water, or into 
 carbonate of ammonia, which escapes into the air. The 
 odor coming from stables is often caused by escaping car- 
 bonate of ammonia. 
 
 The best way to prevent germ life from destroying 
 so much of the value of manure is to keep the manure 
 well packed. An experiment in stall-feeding steers, at 
 the Pennsylvania Experiment Station many years ago. 
 
48 
 
 ELEMENTS OF AGRICULTURE 
 
 showed that when the manure remained in the stable many 
 months and became thoroughly packed, only about five or 
 six per cent of the plant food was lost. When manure 
 can be put out on the land and plowed 
 under, the soil will catch and hold 
 much phmt food that would other- 
 wise be lost. 
 
 Bacteria on Legumes. — As far back 
 as the time of the Romans and the 
 Greeks, it was known that clover, 
 beans, and some other crops made 
 the land they grew on better, but it 
 was not known hoAv these plants 
 made the improvement. It was sus- 
 pected, and even asserted, about half 
 a century ago, that these plants took 
 in nitrogen of tlie air througli the 
 leaves. This was proved to be un- 
 trtie. Yet these legumes, or pod 
 [)lants, were always rich in nitrogen 
 and left the soil rich in it. Some 
 said they sent deep roots into the 
 subsoil and dissolved nitrogenous 
 compounds and other plant food, 
 and brought them up near the surface. 
 Finally it was proved that plants 
 do get nitrogen from the air, but not through their leaves. 
 They get it through their roots, and by the help, in a 
 remarkable way, of bacteria that live on the roots. If 
 you will dig up a cowpea or a peanut plant, you will find 
 
 Fig. 15. — Tubercles 
 ox Roots of Legumes 
 
BACTERIA, OR GERM LIFE 49 
 
 aii}^ number of little warts, or tubercles^ on the roots. 
 These knots are the homes of bacteria that help the host 
 plant to get nitrogen. Corn, oats, cotton, potatoes, and 
 most crops cannot develop these bacteria on their roots, 
 and hence cannot use the free nitrogen in the air. 
 
 A crop of cowpeas, peanuts, or velvet beans grown on 
 a single acre has often been found to contain 200 pounds 
 of nitrogen in its fruit, leaves, stems, and roots. A ton 
 of cotton-seed meal does not contain so much nitrogen. 
 Of course, when such a crop is plowed under and rots, 
 the land is greatly enriched.' Even when the crop is not 
 plowed under, but saved for ha}^ the roots, stems, and 
 fallen leaves will enrich the land. 
 
 The same kind of bacteria will grow only on closely 
 related kinds of plants. So it is often found that when a 
 legume is planted for the first time in a neighborhood, 
 it is well to spriukle the land with soil that has already 
 successfully grown this kind of plant or a kind closely 
 related to it. This supplies the new land with germs 
 which inoculate the plant and enable it to produce a 
 better crop. 
 
 The effects of restorative crops on the land will be 
 more fully discussed in a chapter on rotation of crops. 
 
 Plant Diseases. — These little bacteria and fungi (singu- 
 lar /'kw^M.s-) cause most plant diseases. Cotton rust, grain 
 rust, pear blight, peach curl, tomato blight, and many 
 other diseases are caused by fungi of different kinds. 
 Some of these are very difficult to treat. Many fungous 
 diseases are checked in a great measure by spraying with 
 Bordeaux mixture. Some strains of crops are resistant 
 
50 ELEMENTS OF AGRICULTURE 
 
 to thete diseases. The red oat is much more resistant 
 to rust than other kinds. A strain of sea-island cotton 
 resistant to cotton wilt is said to have been found. In 
 the tropics a small wild tomato grows with perfect free- 
 dom from disease, where the finer cultivated kinds usually 
 fail on account of blight. Root rot of cotton is a serious 
 matter in much of Texas and in other sections. The crop 
 dies in patches. Alfalfa, peanuts, peas, different fruit 
 trees, and many weeds are subject to it. The fungus 
 causing it does not live on the roots of sorghum, corn, 
 wheat, oats, etc. Therefore, rotation with tliese crops is 
 about the only partial remedy known. Melon wilt and 
 cotton wilt are two other fungous diseases that cause great 
 loss in some sections. 
 
 Rotation of crops and burning of diseased plants are 
 measures adopted to prevent the spread of all fungous dis- 
 eases. The treatments for many plant diseases are given 
 in the Appendix. 
 
 QUESTIONS 
 
 What do you understand by bacteria? What causes the souring of 
 milk? Is gerin life harmful or beneficial to us? What is necessary 
 in order to preserve fruit ? Is germ life of much importance in the 
 arts and industries? Is it of any importance in soils and manures? 
 By what means are peas and other crops enabled to enrich the land? 
 How much nitrogen will a big crop of peas or peanuts add to an acre 
 of land? Will all kinds of bacteria grow on all kinds of leguminous 
 crops? What causes grain rust? Are there any grains resistant to 
 rust? What causes potatoes to rot? Why should cut or bruised 
 potatoes not be mixed with sound ones? What about root rot of 
 cotton? What other plants does it attack? What plants are not 
 attacked by this fungus ? How can one partly get rid of root rot ? 
 What other fungous diseases of cotton are mentioned? What disease 
 of melons ? 
 
BACTERIA, OR GERM LIFE 51 
 
 Experiment. — Dig up peas, peanuts, and other pod-bearing plants, 
 hi-iiig them to the schoolhouse, and examine little tubercles on roots. 
 I'erhaps the County Superintendent could acquire a large microscope 
 and let the schools have it by turns. In this case examine germs in 
 milk, water, etc. It will be most interesting. Cut sweet potatoes at 
 home, and inoculate with germs of rotting potatoes and note effects. 
 
CHAPTER IX 
 
 THE BOTANY OF OUR CROPS 
 
 Plant Families. — Botany, the science wliicli describes 
 plants, divides all plants into great tribes, having certain 
 degrees of relationship or resemblance. Corn, sorghum, 
 sugar cane, oats, wheat, rice, grasses, etc., are put into a 
 large tribe, because they all have leaves somewhat alike, 
 and grow somewhat in the same way. This large tribe is 
 again divided into grains and grasses. Some of the mem- 
 bers of this large family are very closely related, as oats, 
 wheat, barley, and rye. Sorghum and Johnson grass are 
 about first cousins, while milo-maize and kafir corn are 
 something like double first cousins, or probably as close 
 kin as brothers. 
 
 Another large family of plants bears seed in pods. 
 Most of these plants support on their roots bacteria tliat 
 enable them to feed on nitrogen from the air, as you have 
 already learned. This family includes all the clovers, 
 alfalfa, beans, peas, peanuts, beggar weed, and various 
 other plants. The cowpea is more closely related to the 
 bean than to the garden or English pea. This family 
 of plants is often called The Legumes. 
 
 Cotton and okra belong to another big family, and are 
 rather closely related. Of the fruit trees, peaches and 
 plums are likewise closely akin : also apples and pears. 
 
 52 
 
THE BOTANY OF OUR CROPS 53 
 
 Fruit trees closely enough related may be grafted on to 
 each other. 
 
 Genus, Species, and Varieties. — While a number of 
 plants somewhat alike are said to belong to a family, or 
 tribe, these tribes are divided into groups still more closely 
 related. Each of these smaller groups is called a genu^. 
 The different kinds of clover belong to the genus 
 Trifolium^ or three-leaved plants. Each genus is divided 
 into still smaller groups whose members are still more 
 closely related to each other. p]ach of these groups is 
 Ciilled a species. Sorghum and Johnson grass are different 
 species of the same genus. Then we have varieties of the 
 same plant. Short-limbed cotton and long-limbed cotton 
 are different varieties. Different varieties of a plant 
 may be said to be as closely related to each other as 
 brothers and sisters. (See Appendix for further descrip- 
 tion of the plant families.) 
 
 Length of Life. — Plants tliat grow on from year to 
 year, like fruit or forest trees, are called perennial plants. 
 So are plants that keep coming up from the same roots, 
 like Johnson grass and Bermuda grass. Plants like cotton 
 and corn, that die, root and branch, each year, and have 
 to come up from seed again, are called annuals. It is 
 true, cotton is a perennial in the tropics, and lives and 
 grows for many years, getting as large as plum trees. 
 Certain other plants grow two years and make seed the 
 second year and die. These are biennials. Turnips, 
 beets, and melilotus, or sweet clover, are biennials. 
 
 Storage of Plant Food. — Biennial plants generally store 
 up the first year a supply of rich food in their roots, so 
 
54 ELEMENTS OF AGRICULTURE 
 
 they grow very rapidly the second year. Perennials store 
 up in their twigs and buds food that causes very rapid 
 growth of young leaves the next spring. So all plants 
 store food in their seed for the use of the young plants 
 until the latter can take root. Irish potatoes may grow 
 a foot high from the food in the seed potato. It lias been 
 proved that if large pieces of Irish potatoes are planted, 
 much better yields are secured than when the seed pota- 
 toes are cut into small pieces. That is, the young plants, 
 being better fed, get a better start and grow more vigor- 
 ously if big pieces of seed are planted. 
 
 Sugar cane, of course, has a large store of sugar and 
 other food in the stalk planted. The young plant can 
 grow a long time just by feeding on this seed stalk. So 
 in the East Indies, where people want time to gather an- 
 other crop from the land, and yet want the sugar cane 
 early, they start the cane in beds and then transplant the 
 mother stalks bearing the young cane when the other 
 crop has been removed and the land prepared. To 
 lengthen tlie short growing season in the Gulf States, 
 cane might be sprouted under glass or cloth and trans- 
 planted in the same way. Even a mustard seed and a 
 tobacco seed contain some food to start the young plant 
 off. 
 
 Plants, if they had intelligence and speecli, would tell 
 us they do not store food for us, but for their own off- 
 spring. The sap in the sugar maple, sugar cane, and 
 sugar beet, that we take to make sugar, is stored there to 
 support new plants and new growth ; so of the starch and 
 other substances in I'ice, corn, wheat, and barley seed. 
 
THE BOTANY OF OUR CROPS 
 
 55 
 
 The rich protein compounds in beans, peanuts, and cotton 
 seed are primarily to support young plants. In one sense we 
 are robbers of the plant kingdom, and must be in order to live. 
 
 Roots, Stems, and Leaves. — Plants have roots to hold 
 them upright in the soil and to gather moisture and food 
 from the soil. The stems serve to hold the leaves up to 
 sun and air. The stems, as you have seen, also contain ; 
 little channels through which plant food and water are 
 carried from the roots upward to the leaves. Then the 
 finished chemical compounds made by the leaves pass 
 back into every part of the plant. Tlie leaves, as we 
 have seen, give off water, and take in carbonic acid gas. 
 
 Plants as Chemists. — 
 By means of the chloro- 
 phyll, or green coloring 
 matter, and sunlight, the 
 leaf is able to make starch 
 out of carbon and water. 
 No human chemist can do 
 this. Then the plant 
 readily turns its starch 
 into sugar. Cliemists can 
 perform this feat, but they 
 cannot turn sugar back 
 into starch. The plant 
 can do this. To the starch 
 or sugar the plant makes, 
 it adds a little sulphur, 
 phosphorus, and nitrogen, 
 which come up in the soil Fig. lO. — Fibrous Roots of Corn 
 
56 ELEMENTS OF AGRICULTURE 
 
 water, and a compound called protein is made. Chemists 
 cannot make this, and without it in our food we could not 
 live. Protein will be discussed later under the subject of 
 Feeding Animals. 
 
 Kinds of Roots. — Plants are often spoken of as having 
 either fibrous or tap roots. Corn and oats and wheat 
 have fibrous roots. Cotton has a tap root, and of course 
 has many small fibrous roots branching out from this main 
 tap root. The smaller roots of plants are the feeding 
 roots, and even the smallest roots that can be seen with 
 the unaided eye are covered with small hairs that take 
 in moisture and food from the soil. 
 
 Length of Roots. — Plant roots grow to a much greater 
 length than one would suppose. Most phmts have roots 
 longer than the height of the plant. We often see cotton 
 or corn injured at a distance of forty yards or more from a 
 large green tree. The tree is not shading the crop for 
 any great distance, as some people think. The little 
 roots of the tree are stealing food and moisture from 
 the crop. This injury is greatest in time of drought. It 
 has been estimated that if all the roots of a hill of corn 
 were placed in a straiglit line, they would reach a mile. 
 Plant roots often go many feet deep, but the majority 
 of the feeding roots of farm and garden crops will 
 nearly always be found in tlie upper six inches of the 
 soil. 
 
 Osmosis of Plants. — If a bladder containing strong 
 salt water be suspended in a vessel of pure water, the 
 pure water will pass througli the bladder rather rapidly, 
 and some of the salt water will pass out into the vessel. 
 
THE BOTANY OF OUR CROPS 
 
 57 
 
 The most rapid movement will be into the bladder toward 
 tlie strong solution. The mixing of liquids through a 
 membrane like this is called the principle of osmosis. 
 This is the way in which plant roots take in food and 
 water from the soil. Water containing dissolved salts is 
 inside the plant, and water contain- 
 ing salts is also about the roots in 
 tlie soil. As the leaves of the plant 
 evaporate water, the liquid inside 
 becomes stronger than that outside. 
 Hence the weaker liquid outside be- 
 gins to flow through the cell walls 
 of the roots into the plant and the 
 liquid inside passes out less rapidly. 
 As water continues to evaporate from 
 the leaves, the stronger solution will 
 be in the leaves and the weaker one 
 in the roots where the soil water is 
 entering. Hence the weaker solu- 
 tions move upward from cell to cell. 
 Iliis, at least, partially accounts for 
 the movement of sap in plants. 
 
 Beans when soaked swell up until 
 they burst. This is due to the prin- 
 ciple of osmosis. The weaker liquid 
 flows through the skin of the bean. A shriveled piece of 
 Irish potato will take in water when soaked and become 
 })lump. But if soaked in strong salt water, the potato 
 will become still more shriveled, because the juices of the 
 })()tato flow outward to the strong solution. 
 
 Fia. 17. — Showino 
 Osmosis 
 
68 
 
 ELEMENTS OF AGRICULTURE 
 
 Fig. 18. — Flower of the Apple 
 
 To show the pressure of the flow of sap, cut a small 
 
 grapevine and fit a rubber tube over it and put a glass 
 
 tube in the other end of the 
 rubber tube. The pressure 
 will raise water in the glass 
 tube many feet high. 
 
 Fertilization of Plants. — 
 Plants, in order to make seed, 
 have flowers. A perfect flower 
 has stamens producing a little 
 yellow powder called pollen, 
 
 and a pistil containing the little seed. In order to become 
 
 fertile and make good seed, some of the pollen must 
 
 reach the little seed. See Figure 19 for the names of the 
 
 different parts of the 
 
 flower. One part of the 
 
 corn flower is represented 
 
 by the shoot and silks, 
 
 the other part by the 
 
 tassel. As is well known, 
 
 no grain is made unless 
 
 the pollen of the tassel 
 
 falls on the silk of the 
 
 corn. The ears of corn 
 
 fill much better in a large 
 
 field than where there are 
 
 only a few stalks. In the 
 
 latter case, the pollen is blown off and does not reach the 
 
 silks. Corn of different varieties will sometimes mix 
 
 even when the fields are some distance apart ; this is 
 
 Fig. 19. — Lily of the Valley, show- 
 ing SIX Stamens and the Pistil 
 IN the center 
 
THE BOTANY OF OUR CROPS 
 
 due to the fact that the pollen is blown from one field 
 to the other. In order to be sure of effecting the most 
 rapid improvement by selecting seed corn, the shoots of 
 the desirable kind should be covered with paper bags 
 before the silks appear, and then the silks should be 
 dusted artificially with tlie pollen from the same stalk, 
 or an equally desirable one. 
 
 Still other plants have flowers containing pistils on one 
 plant and the flowers containing the stamens on another. 
 Often two varieties of strawberries must be planted close 
 together on this account. Date palms had been growing 
 on the Texas coast for a long time and had borne no fruit. 
 It was supposed they would not bear in this climate. 
 Finally, some one brought flowers from palms growing in 
 Mexico and fertilized those on the Texas trees, and as fine 
 dates as could be desired were produced. 
 
 Work of Insects. — Insects aid in carrying pollen and 
 fertilizing flowers. When cucumbers are grown in hot- 
 houses in winter, it has been found that fertilization can- 
 not be done so well by hand, and bees have been introduced 
 into the hothouses for the purpose. The bee or other 
 insect gets pollen on its body and carries it to the next 
 flower visited. The showy colors and the sweet perfume 
 of flowers, it is said, are nature's ways of attracting insect 
 visitors to the flowers. In the Philippine Islands and 
 Borneo, wherever a few flowers are cultivated, sticks are 
 stuck up with eggshells put on top of them, often giving 
 the appearance of numerous flowers. The people say that 
 the eggshells make the flowers grow better. Whether 
 this is a useless notion, or whetlier the eggshells may 
 
60 ELEMENTS OF AGRICULTURE 
 
 lielp attract the few insects that visit flowers there, the 
 writer lias often wondered. 
 
 Crossing and Hybridizing. — Phuits of different varie- 
 ties may be crossed by fertilizing the flowers of one vari- 
 ety with the pollen of another. Plants of different species 
 may often be crossed, and the resulting plant is called a 
 hybrid. Crossing and hybridizing sometimes produce 
 superior plants, but the chances are that the new plants 
 will be no better than the originals. As a rule the prac- 
 tical farmer and gardener had best leave crossing and 
 hybridizing on a large scale to the professional plant 
 breeders. To every hybrid or cross that is superior to 
 the parent plants, there are hundreds that are inferior. 
 
 QUESTIONS 
 
 What is the name of the science that describes plants? How are 
 plants classified? Name a near relative of sorghum. Name a dis- 
 tant relative of corn. Name a relative of the cowpea and one of 
 cotton. Can plants not related to each other be grafted together? 
 Are the plants in a species or in a genus more closely related ? What 
 is an annual plant? What is a perennial and what is a biennial 
 plant ? What provision is made by all plants in the fall for rapid 
 growth next spring? What is the reason that big pieces of Irish 
 potatoes will yield more when planted than small pieces will? 
 What does the sugar-cane plant feed on when young? In what 
 way do we rob plants? Of what use are roots to plants? Of 
 what use are stems and leaves? Can chemists make sugar out 
 of starch, and can they make starch out of sugar? Caii plants 
 do these things? What other compound in plants is necessary for 
 animal life? Can human chemists make this compound? What 
 two kinds of roots do plants have? Give exani])les of plants 
 that have both kinds of roots. How long are the roots of a 
 large tree? Explain the injury a tree will do to a crop in time of 
 
THE BOTANY OF OUR CROPS 61 
 
 drought. How deep do plant roots feed? Explain the principle of 
 Osmosis, or the mixing of liquids through a membrane. Exphiin 
 how the principle of Osmosis enables plants to get food from the soil. 
 What will happen if a shriveled Irish potato is soaked in salt water? 
 What is a flower? What are the principal parts of a flower ? Where 
 are the different parts of the Indian corn flower situated? What 
 would happen if all the tassels of corn were cut off? If you wish to 
 be sure that an ear of corn would not mix with other corn, what 
 would you do? Why do people sometimes have to plant two kinds of 
 strawberries near each other? Why would the date palm not bear 
 fruit in Texas, and what was done to make it fruitful ? Of what use 
 are insects to plants? Of what use are the pretty colors of flowers? 
 What do we mean by "crossing" plants? 
 
 Experiment. — Plant on the farm at home one row of corn from 
 nubbins and a row from fine ears, and see if there is a great differ- 
 ence in yield. Report next session for the benefit of the school. 
 
 Plant at the proper season at home a few single eyes of Irish 
 potatoes, cutting each eye off with a very small, thin piece of potato. 
 Then plant pieces as big as walnuts, with all eyes cut out but one on 
 each piece. Note how much better plants the latter will make. Make 
 report next session. 
 
 Watch a few stalks of corn growing in garden, and if you wish 
 take out all the tassels when they first ap]')ear. Note that few grains 
 or none at all will be made. 
 
CHAPTER X 
 
 GRAFTING AND BUDDING 
 
 Many plants do not produce offspring like themselves 
 when their seed are planted. This is true of peaches, 
 apples, plums, pecans, and other fruit-bearing trees. You 
 may plaut a seed from ever so fine a peach, and you are 
 nearly certain to get a tree bearing inferior fruit. If yon 
 plant the finest paper-shell pecan, the chances are you 
 will get a small, hard nut. But if a bud or graft be 
 taken from a good kind of tree and made to live and grow 
 on a stock of any kind, it will ahvays bear fruit like the 
 tree from which it was taken. 
 
 Budding. — Figure 20 shows the common metliod of 
 budding. Budding must be done in summer when the 
 bark slips readily. Peaches, plums, and cherries are 
 generally budded rather than grafted. Young seedling 
 trees are grown in large numbers, and buds of desir- 
 able kinds put under the bark of the seedling plant 
 near the ground. In the Southern States peaches are 
 often budded in June and September. When the June 
 bud is found to live, the top of the stock is broken 
 above the bud and allowed to remain attached until 
 the bud begins to grow vigorously ; the broken top is 
 then entirely cut off, and the new bud makes the tree. 
 The tops of the stocks budded in September are not cut 
 
 62 
 
GRAFTING AND BUDDING 
 
 63 
 
 away until the following spring. The Japanese per- 
 simmon may be budded into seedlings of the common 
 persimmon grown in the same way as peach seedlings. 
 
 Figure 21 shows the ring method of budding pecans 
 and oranges commonly practiced in the South. Buds of 
 the finest kinds of pecans may be inserted in pecan seed- 
 lings or hickories. If the hickory or pecan trees on which 
 the grafting is to be done are old, the limbs and tops 
 
 Fig. 20. — Steps in Budding 
 a. Cuts in Stock d. Bud Inserted 
 
 6. Bark Slipped Away e. Bark Wrapped 
 
 c. Bud /. Bud making New Tree 
 
 should be cut off in the winter so that a new growth will 
 be put forth. Several buds are inserted in the new wood 
 the following summer, and then fine kinds of pecans will 
 be produced in two or three years (see Fig. 24). 
 Satsuma orange buds are grafted into a hardy, worth- 
 less orange, called the trifoliata, grown from seed. As 
 the sap ceases to flow vigorously in this trifoliata stock 
 in the fall, the trees become so nearly dormant that they 
 are not much affected by cold. Hence we have a hardy 
 
64 
 
 ELEMENTS OF AGRICULTURE 
 
 and valuable orange for South Texas, Louisiana, and 
 other Southern States, where the orange industry is one 
 
 of great promise and 
 is already assuming 
 
 commercial 
 tions. 
 Grafting. 
 
 propor- 
 
 - Apples 
 and pears are more 
 often grafted than 
 budded. Seeds are 
 planted and many 
 young plants pro- 
 duced. These form 
 the stock on which 
 cuttings, or scions of 
 good varieties, are 
 grafted. Figure 22 
 s h o \v s different 
 methods of grafting. 
 Grafting is generally 
 done in winter and 
 very early spring. 
 The main caution to 
 be observed is to see 
 that the inner bark 
 of the stock and scion exactly join for at least a part of 
 the way around, so that the sap can flow back and forth. 
 
 Different species of plants may be grafted or budded 
 on each other, as apples, pears, and quinces. This is also 
 true of cherries, peaches, and plums, and with pecans and 
 
 ING BUDDIN<J FOK OrANGKS AND 
 
 Pecans 
 
GRAFTING AND BUDDING 
 
 65 
 
 hickories. Better results are often secured when 
 the stock and the scion are of the same species. 
 
 Fig. 22. — Grafting 
 a. Sciou ; b. Stock 
 
 Whip 
 Graft 
 
 Many people think peaches and 
 apples can be grafted or budded on 
 each other. That is not true. 
 Plants must be rather closely related 
 to be grafted and budded together. 
 In almost every neighborhood 
 there are men who are skilled in budding and 
 grafting. It is suggested that each pupil 
 seek an opportunity to witness the art of 
 budding and grafting, and by a little prac- 
 tice, learn to do it. 
 
 Cuttings and Layering. — It is often not 
 necessary to bud or graft in order to propa- 
 Depth to ^ate and multiply plants. Many plant cut- 
 
 PLANT Fig ^ , -, . r 1,1 -1 
 
 Cutting tings simply stuck down m tavorabie sou 
 
 Fig. 23. - The 
 Proper 
 
m 
 
 ELEMENTS OF AGRICULTURE 
 
 will live and grow. Figs are fairly easily multiplied 
 in this way by planting cuttings in winter or early spring. 
 
 The limbs of other 
 
 M 
 
 Fig. 24. 
 
 }) 1 a n t s m ay be 
 brought down to the 
 ground and covered, 
 and when they take 
 root, they may be 
 set out as any other 
 plant. This is called 
 layering. Grapes are 
 often propagated in 
 this way. 
 
 In the tropics most 
 plants grow from 
 cuttings set in the 
 early part of the 
 wet season. There 
 I - %«^ i^ V^\ ^ ^^^^ ^^^^y^ often see a 
 rt^^k ' V ^^^^v^s- ^^»^1 <^f mw^ tied to a 
 limb which has been 
 cut half in two, or 
 liad the bark cut. 
 This is done to en- 
 courage rooting at 
 Tliis method is about the same as ordinary 
 
 Old Pecan Tree growing Paper- 
 shell Buds 
 
 that point, 
 layering. 
 
 Runners. — Many plants are multiplied by root stocks 
 or runners. The blackberries and raspberries put up 
 numerous plants from the roots. They are propagated 
 
GRAFTING AND BUDDING 67 
 
 by planting pieces of roots. Strawberries send out run- 
 ners that root and make new plants. Bermuda grass, 
 in tliis climate, is propagated from the trailing stems that 
 root at each joint. It may also be produced from seed 
 got from the tropics. Johnson grass, one of our most 
 dreaded pests, grows from seed and from large, flesh}^, 
 jointed underground stems, usnally called roots. 
 
 QUESTIONS 
 
 Suppose you plant the seed of line peaches, will they always pro- 
 duce trees having fine fruit? What is necessary, then, in order to re- 
 produce fine peach trees? AVhat other fruits will not come true from 
 .seed? What two methods do we have of multiplying such fruits? 
 Describe budding. Describe different methods of grafting. How 
 are oranges propagated in the Gulf States? Do we graft or bud 
 apples and pears? At what time of year is budding done? What 
 time of year is grafting done? How are figs propagated? How are 
 grapes propagated ? How do we propagate strawberries, blackberries, 
 and raspberries? 
 
 Experiment. — Practice grafting and budding and see what success 
 you liave. 
 
CHAPTER XI 
 
 SEED SELECTION 
 
 People appear to believe in selecting the best seed for 
 planting and the best animals for breeding. Yet, as a 
 rule, but a half-hearted effort is made, especially in regard 
 to seed selection. It is true, a great deal of money has 
 been spent for seed which are supposed to represent 
 years of careful selection, and which are claimed to have 
 a producing power two or three times as great as tlie 
 seed usually planted. These purchases have generally 
 been disappointing ; the seed in many cases have proved 
 to be not so good as some of those planted for years in 
 the purchasers' neighborhood. 
 
 Do Seed run Out ? — It is not true, certainly with most 
 crops, that seed '' run out," and that new seed from a 
 distance must be brought in. In fact, it has been 
 generally found that seed of a certain variety of crop 
 grown in any locality will be better for that locality 
 than those brought in from a distance. Seed grown in a 
 localit}^ for a number of years go through a process of 
 adaptation and natural selection, better suiting the crop 
 to its conditions. Of course the farmer can hasten this 
 adaptation by intelligent artificial selection of planting 
 seed. In this way corn has been developed to grow 
 farther north, wheat to suit certain sections and give 
 
 68 
 
SEED SELEC'i'IOX 
 
 69 
 
 >^^ 
 
 better yields; cotton is being' developetl to make fair 
 crops ahead of the boll weevil, etc. Other cru[)s have 
 been adapted to i-esist disease. In a measure, also, 
 varieties of crops have been produced to suit diffei-ent 
 types of soil, to vary in their fertilizer requirements, 
 resistance to excessiye wet or dry weather, etc. 
 
 Plants resemble Parents. — In a general sense, a plant 
 is like its parents. Jt is not true, howeyer, that seed from 
 a nearly perfect ear of corn will, of necessity, produce only 
 stalks haying perfect ears. A 
 fine ear of corn may have been 
 fertilized (pollenized) by one 
 bearing a little nubbin. The 
 nubbin may have been pollenized 
 by the stalk having the fine eai-. 
 In that case the nubbin would 
 make as good seed as the fine 
 ear, if the grains are as sound 
 and individuall}" as large. Even if the fine ear is crossed 
 with another stalk having a fine ear, and the nubbin witli 
 a stalk having a nubbin, it is not at all likeh^ that tlie 
 seed will be so widely different in productive power 
 when planted as the parent ])lants were. Eacli grain 
 has in it not only the strain of its immediate parents, 
 l)ut of a hundred generations of })arents. One or two 
 generations of nubbins, or even almost barren stalks 
 as ancestors of one parent, caused by poor soil, poor 
 culture, or dronght, will not be likely seriously to reduce 
 tlie yield when planted, if good conditions are again 
 provided. 
 
 Fig. 25. — Testing Seed 
 
70 ELEMENTS OF AGRICULTURE 
 
 The Farmer his Own Seedsman. — As far as possible 
 eveiy farmer should select liis seed in his own neighbor- 
 hood or on his own farm. He should select seed witli 
 a view of obtaining a size and type of plant that suits tlie 
 soil and seasons of his locality. It is higlily probable that 
 all the desirable qualities cannot be combined in any one 
 type of cotton, for example. We shonld like earliness, 
 hardiness, prolificness, high per cent of lint, large bolls, 
 and long staple. It is probable that some of these quali- 
 ties are antagonistic to each other, and consequently all 
 of them can never be fully attained in one variety. lUit 
 large bolls, earliness, and at least fair prolificness, can be 
 obtained in short staple cotton. This has been proved 
 many times. 
 
 Sound, Heavy Seed. — I'he farmer should see to it that 
 only sound, heavy seed are saved. The Department of 
 Agriculture at Washington has devised a little machine 
 to separate light cotton seed from heavy, plump seed. 
 The latter, in a planting test, gave a much better yield 
 than unseparated seed. Good stands of all crops are 
 necessary in order to make good yields. Seed corn in 
 the corn-growing states is often unsound, and the innn' 
 stand resulting cuts off the yield several bushels })er 
 acre. Of course good, sound, heavy seed of all kinds 
 should be insisted on when buying. As all seed lose 
 their vitality with age, new seed should be demanded. 
 Seed bought should be subjected to a germination test. 
 That is, one hundred average seed should be kept under a 
 moist cloth, or in moist sand, at a temperature suitable to 
 germination, to see how many are good. 
 
SEED SELECTION 
 
 71 
 
 Weed Seeds. — In buying alfalfa, clover, wheat, oats, 
 and many other seeds, one should be on his guard against 
 introducing^ the seed of noxious weeds. In examinino- 
 many sam})les of alfalfa seed brought into Texas, the 
 Experiment Station has found large percentages of dod- 
 der, Russian thistle, dock, and other exceedingly ]>ad 
 
 Fig. 2G. — ^Pure and Impure Alfalfa Seed, Magnified 
 
 weeds. Oats and wheat are very likely to carry Johnson- 
 grass seed, when grown in sections where that grass 
 exists. It would be advisable to have a microscopic 
 examination made of all seed that are likely to have 
 mixed with them the seeds of harmful weeds. No doubt 
 the experiment stations and agricultural colleges of all 
 the states will do this work free of charge. 
 
 Watching for Sports. — The farmer, by careful watching 
 for just the type of plant wanted, and selecting, keeping 
 pure, and planting, can accomplish much more than by 
 
72 ' ELEMExNTS OF AGRICULTURE 
 
 artiticially stimulating big yields and depending on these 
 seed to make big yields. A new type of plant is called 
 a sport. Sports do not alwa3^s breed true, but they often 
 do, and thus produce new varieties. An extraordinary 
 crop secured by high fertilizing, good seasons, etc., will 
 not be likely to afford better seed than a crop which has 
 made a poor yield on account of unfavorable conditions. 
 The large yields of many of the high-priced seed which 
 are sold are due rather to liigh fertilizing than to special 
 merit in the seed. 
 
 Dr. de Vries and Dr. Nillson, quite noted European 
 plant breeders, pronounced the plan of the German plant 
 breeders a failure. The German plan is to select a large 
 amount of seed from the whole of a good crop and plant 
 these together. Dr. de Vries and Dr. Nillson watch for a 
 single plant differing from the others and of a desired 
 kind, called a sport, tlien isolate it and multiply from it. 
 In this way they chiim to have accomplished certain and 
 excellent results. 
 
 All the evidence points to the fact that if there is any 
 variety which is best for a given locality, it will not be 
 the best for all localities growing this crop. With a long 
 season of growth and plenty of rain, a late-maturing kind 
 of corn will outyield an early kind. But for a northern 
 latitude, or the dry western climate, we should hardly 
 recommend the large-stalked, late kinds of corn. It is 
 also evident that the same kind of cotton does not do 
 equally well over any hirge extent of country. 
 
 Limits to Improvement. — It seems reasonable that 
 crops that have been higlily improved already cannot be 
 
SEED SELECTIOX 78 
 
 improved so rapidly in future as in the past. Tliat is, a 
 limit can be reached somewhere beyond which improve- 
 ment cannot go on. It is said the sugar beet has had its 
 sugar content doubled since Napoleon began its improve- 
 ment as a means of raising revenue for his wars. Whetlier 
 this is true, or part of the improvement actually came 
 from better liandling and later ripening of tlie beets and 
 better methods in tlie factin-ies, it is immaterial. It 
 is true, liowever, that the sugar content of tlie beets 
 grown in Germany, the greatest sugar-making country 
 on earth, has not increased on an average so much as 
 one per cent on the Aveight of the beets in nearly forty 
 years. 
 
 Java, next to Hawaii the jnost intensive cane-suo-;ir 
 country in the world, was forced to give up its sweetest 
 cane and grow a vigorous, hardy kind, able to resist 
 certain cane diseases. The same country once grew an 
 immense quantity of as fine coffee as was ever known. 
 Disease came and entirely destroyed the industry, which 
 is now being built up again, with an inferior but liardy 
 Ivind of tiee, able to resist the disease. 
 
 Less hardiness and less resistance to disease seem gener- 
 ally to follow improvement in other directions. Whether 
 this evident tendency can be guarded against and disease 
 resistance combined with improvement in yield and quality 
 of product, are questions as yet unknown. Such a com- 
 bination has not been attained in improved live stock, and 
 certainly has not in most cases witli improved plants. 
 Hopkins, of Illinois, has bred corn to contain some 45 per 
 cent more protein tlian average corn. Tn doing so. he 
 
74 ELEMENTS OF AGRICULTURE 
 
 appears to have reduced tlie size of ears, and presumably 
 the yiehl of corn, about 25 per cent. 
 
 Potatoes and Cane. — Phmting small sweet potatoes and 
 Irish potatoes is a general practice in some sections, and 
 has been for generations, but potatoes show no marked 
 tendency to become smaller. It is true that planting 
 small Irish potatoes, where they are cut to two eyes, will 
 result in smaller yields than larger potatoes cut to two 
 eyes. You have seen why this is so. When the same 
 sized pieces are cut from small potatoes as are cut from 
 large potatoes, there will be more eyes in the pieces 
 cut from the smaller potatoes, and with some varieties 
 several of these eyes come up, resulting in too many 
 plants, and consequently a larger proportion of small 
 potatoes. 
 
 Above the Louisiana sugar belt proper the practice 
 of sirup makers has been for years to save for planting 
 the small, worthless stalks of cane. In the tropics the 
 practice has been for ages to plant the immature, worth- 
 less tops. In neither case has any deterioration in the 
 cane occurred. In the tropics much experimental work 
 has been done to find the effects of planting poor 
 stalks and tops, but no change one way or the other has 
 been found. 
 
 In the case of sweet potatoes, Irish potatoes, and cane, 
 we plant parts of the old plants just as in budding and 
 grafting. In each of tliem real seed may be grown, and 
 are grown and planted. When sugar cane grows a year 
 or more in the tropics, it makes a head of fine feathery 
 seed. These are planted and a little, weak stalk of cane 
 
SEED SELECTION 
 
 75 
 
 is produced. This stalk is planted and cane is produced 
 in the usual way, but there is never any telling what kind 
 of cane it will be. It is never likely to resemble the par- 
 ent, and is entirely likely to be different from any other 
 variety of cane ever produced. You are more likely to get 
 
 Fig. 27. — New Mexico Date Palm 
 
 from the seed of red cane either white, green, striped, or 
 even black cane, than red cane. Only one in thousands 
 of the kinds produced in this way has been found to have 
 better qualities than well-known kinds. Irish potatoes 
 and sweet potatoes are said to show^ these same variations 
 when grown from real seed. 
 
 Other Seed -producing Plants. — With plants that cross 
 
76 ELEMENTS OF AOKICULTUKE 
 
 ])()llenize, variation is iiincli more likely to occur. Luther 
 Jiurbank plants a vast number of seeds of eacli kind, and 
 Avatches for sports. By growing this sport and fixing 
 the type by preventing cross fertilizing, he obtains the 
 new variety. 
 
 Rapidity of Improvement. — Plants are not so rapidly 
 and certainly improved by usual methods of selection and 
 breeding as some people l)elieve. Of the one hundred 
 or more so-called varieties of cotton tested at several 
 Southern experiment stations, no one kind has often 
 made the best return two years in succession at the same 
 station. No one kind tliat yielded best for early plantiaig 
 lias often yielded best for late planting. No one kind 
 has often made best returns the same year at any two 
 stations. Frequently the variety that yields most on 
 one kind of land yields least on another kind. If we 
 take averages, the kinds known to be old have yielded 
 nearly as well as those which are claimed to have been 
 improved in recent years. 
 
 QTE'^TIOXS 
 
 AVhat are comparative merits of home grown seed and seed brought 
 from a distance? What about seed "running out"? What have 
 experiment stations found out about the best variety of cotton ? How 
 about seed from a croj) that was poor on account of drought? Can 
 seed be improved by merely fertilizing the crops ? Tell about the 
 experience in planting sugar cane and potatoes. What is a '-sport "? 
 How are new varieties produced? Can all desirable qualities be 
 combined in one variety of plant? What soit of corn should be 
 selected for a dry country ? How are seed tested? What undesirable 
 ])lants are likely to be introduced in seed? To what extent do you 
 think we can go on improving oni- crops? 
 
SEED SELECTTON 77 
 
 Experiment. — Use a niagiiifying- glass and examine seed of alfalfa, 
 turnip, and other small seed for weed seed, rotten seed, etc. Make 
 germination tests at proper season with different seed. You may 
 have heard the old saying that wheat turns to cheat. Suppose you 
 get some clieat seed and some pure wheat seed and plant each sepa- 
 rately in boxes. See if each does not make its own kind. You can 
 do these things at school. 
 
CHAPTER XII 
 
 IMPROVING THE LAND 
 
 The rapidity with which lands wash and wear lias al- 
 ready been mentioned. The humus of Southern soils has 
 been found to decrease much faster than in northern lands. 
 The same open winters and heavy rainfall that cause the 
 Avaste of humus and soluble plant food also cause the soil 
 of much of the rolling Soutliern lands to wasli off into the 
 valleys and creeks, leaving red gullies and poor subsoil. 
 
 Poor Land Unprofitable. — The question of improving 
 tlie soil is the great question of the farm. If one-fourth of 
 a bale of cotton to the acre pays all expenses of its pro- 
 duction, including land rent, labor of man and team, seed, 
 gathering, ginning, marketing, etc., then a half bale to the 
 acre will pay over twelve dollars an acre net profit when 
 lint sells at ten cents a pound and seed at -f 20 a ton. 
 While a quarter of a bale makes no net profit, a half bale 
 to the acre makes a net profit as large as il20, drawing 
 ten per cent interest. If fifteen bushels of corn to the 
 acre pays all expenses, then thirty bushels at fifty cents a 
 bushel will pay a net profit of about $7.50. Poor, worn 
 land producing small crops is very poor property ; but 
 good land producing large crops pays l)etter than almost 
 any other kind of investment. 
 
 Land Easy to Improve. — The buildiug up of the soil is 
 tlie surest and quickest way to make large and profitable 
 
IMPROVING THE LAND 79 
 
 crops. It is not difficult or expensive to improve land 
 wiiicli produces a quarter bale so that it will make a half 
 bale or even a bale of cotton to the acre. Much of the 
 thin land of the South which now yields only fifteen 
 bushels of corn or less to the acre could be easily made to 
 yield thirt}^ bushels or more. It is a general fact that the 
 thin, poor lands are the easiest lands to improve. 
 
 Amount of Plant Food. — If even the poorest land is 
 analyzed and calculations made of the amount of phos- 
 })horic acid, nitrogen, and potash contained in a depth 
 of three or four feet, enough plant food is found to sup- 
 port several hundred, or perhaps a thousand, big crops. 
 But such land ceases to produce w^ell because crops and 
 the leaching and washing of the rains have taken aw^ay 
 most of the soluble, or available, plant food. Perhaps 
 almost all the humus has been exhausted and the land is 
 no longer dark in color, i)orous, and fresh, as it was when' 
 it was new. A¥ith most of the humus gone, germ life 
 has little to feed upon, and germs no doubt play an im- 
 portant part in dissolving plant food and making it fit for 
 plant use. 
 
 Nature enriches Land. — If this poor land is left uncul- 
 tivated, grass and weeds and ])riers and bushes soon take 
 possession of it. These hardy plants thread the soil and 
 subsoil with their roots, wdiich can extract food out of the 
 l^oorest land. If protected from fire these plants make a 
 sliade and a soft covering for the land. When they die 
 they decay and form humus. The roots decay and leave 
 channels for air and water to pass through the soil. The 
 sliade and humus encourage germ life, which thrives and 
 
80 ELEMENTS OF AGRICULTURE 
 
 multiplies. Rotting vegetable matter also feeds and shel- 
 ters innumerable earthworms and other low forms of ani- 
 mal life that burrow and eat and grind and pulverize the 
 soil. By a few years of such treatment, nature makes this 
 land just as fresh and productive as it ever was. 
 
 With a crop of peas, velvet beans, or peanuts, or a coat 
 of barnyard manure now and then, land should retain 
 its freshness and prodnctiveness. By such management 
 it will remain fresh and open and porous ; the air can 
 enter ; it will hold moisture better ; germ life will thrive, 
 and all these things help to dissolve plant food in the 
 soil for the use of crops. 
 
 Physical and Chemical Improvement. — Improvement in 
 land may be effected by adding chemical plant food in the 
 form of concentrated fertilizer, or by making some physi- 
 cal change in the soil. Plowing or draining would be 
 a physical improvement. Adding sand to a tight, heavy 
 soil, if it could be done profitably, would often help it, and 
 yet the sand may have no plant food. Coarse manure 
 contains plant food, but one of its chief uses is to open 
 up the land or otherwise put it in better physical con- 
 dition. It adds vegetable matter, or humus, to the soil, 
 makes it drain better, and lets the air enter. It also 
 makes a coarse, sandy soil less porous, and causes it to 
 hold water better. A good supply of humus is the corner- 
 stone of soil improvement, particularly for the w^orn up- 
 lands of' the humid part of the South. 
 
 Terracing. — To prevent rolling lands from washing, a 
 very successful plan followed in the South Central and 
 Southeastern States is to lay off with a cheap leveling in- 
 
IMPROVING THE LAND 
 
 81 
 
 strument lines around the hillside on a dead level. A 
 sharp bed is thrown up on these lines with a turn plow 
 
 
 Fig. 28. — Terraced Land 
 
 and weeds and grass are allowed to grow on 
 lines are generally run 
 so that one will be 
 three perpendicular feet 
 higher than the one 
 next to it down the 
 hill. Of course, the 
 lines will be closer to- 
 gether on steep land 
 than on gently rolling 
 land, and they will be 
 closer together at some 
 points than at other 
 points. Rows are gen 
 erally laid off parallel 
 to each of two terraces, 
 beffinnins:, say, above ,, 
 one and laying off until on Terracp:d 
 
 them. These 
 
82 ELEMENTS OF AGRICULTURE 
 
 iialfway to the next terrace up the hill at the point where 
 the two terraces are nearest together. Then begin 
 below this next terrace and make rows till this halfwa}' 
 point is reached. Last of all the short rows are filled 
 in. Tliis scheme enables each row as nearly as possible 
 
 ,iL to take care of its own 
 
 f.\V-.-.%<f<,Y^ ,,>>j(^:'-'- :'■■■:■■. water, while whatever water 
 
 ^-\^:<::f~\'}'.\\}^^^::r.\\\:\::'^^^ breaks ovcr the rows soon 
 
 'H^S:;y;;-\-;:^v;V-::^f^-::V^ comes to a terrace line 
 
 ^^^^^^^::{-}!:'::^-:^^'[ii^ covered with weeds and 
 
 <«<««<<^ grass. Here the speed of 
 
 Fig. 30. — Terraced Land and Rows , j • i i i i 
 
 the water is checked, and 
 
 whatever sediment it carried is deposited. In a few years 
 the old terrace lines are richer than the other land. These 
 are plowed np and the terraces made along new level lines. 
 Figures 28 and 30 will make clear the description of this 
 plan for preventing washing. 
 
 Drainage. — There is a great deal of land in all humid 
 sections that is unproductive because of poor drainage. 
 
 Fig. 31. — Best Shape for an Open Ditch 
 
 We have seen that too much water makes the land cold, 
 shuts out air, prevents the growtli of microscopic life, etc. 
 Straightening channels of small creeks, clearing out ob- 
 structions, and making a few simple, open ditches will often 
 make much excellent creek bottom land very productive. 
 Any open ditch or channel for water to flow in sliould 
 
IMPROVING THE LAND 83 
 
 be made widely V-sliaped (Fig. 31). Such a channel will 
 always clean itself out much better than a wide-bottomed 
 ditch, and will not be liable to cave and fill up. Often by 
 merely starting such a channel with a plow and replowing 
 after heavy rains, one can make excellent drainage chan- 
 nels at trifling expense. 
 
 Draining Marsh and Creek Lands. — Near the seacoast 
 there are immense bodies of marsh land too flat to be 
 drained in such a way. This land needs to be surrounded 
 with low levees with channels cut through them, and to 
 have the water pumped out over the levees. A trifling 
 amount of pumping will permanently drain such lands 
 and make them highly valuable. The drainage canals 
 might be made the very best and cheapest means of trans- 
 portation. Holland has hundreds of square miles re- 
 claimed even from the sea at a cost of perhaps over one 
 hundred dollars an acre. Even rivers are pumped out 
 over the great levees, or dikes. This land is below sea 
 level and is cut here and there with drainage canals. The 
 people are said to go to market in boats in summer and 
 on skates in Avinter. 
 
 There are also large bodies of fine creek bottom land 
 that could be drained by dredging out straight channels 
 for some miles. As this is usually too large an under- 
 taking for one mcin, the land to be reclaimed should be 
 organized into a drainage district and taxed or bonded to 
 get money to make the improvement. 
 
 Tile Draining. — A great deal of land in the Northern 
 and Central States is drained with tile, or burned clay 
 pipes. These pipes are laid end to end in ditches dug 
 
84 
 
 ELEMENTS OF AGRICULTURE 
 
 
 ':-^-^. 
 
 :>A. 
 
 at suitable distances, and covered over. This makes an 
 excellent and permanent system of drainage. Tile drains 
 do not draw water from the land any better than open 
 
 r===— ==^== — -=^ ditch(is of equal depth ; but they 
 ' '^ ' ^ ^ -^j^^^ ^ ] are never in the way of teams or 
 L^ . _^ "- - r'.Miiiiiij" i> iiiihil 
 
 machinery, they cause no loss of 
 land, and they never fill up 
 when well laid. When tiles are 
 once laid, the expense is over, 
 but open ditches have to be 
 worked on every year. 
 
 In the Gulf States there has 
 been almost no tile drainage, 
 because land has been cheaj) and 
 tiling has been costly. Perhaps 
 the cost of tiling an acre would 
 buy two acres that do not need 
 tile. Moreover, the seasons are 
 long, and we can generally wait 
 for the excess of water to dry 
 off, and yet have time to make 
 a crop. Figure 32 will show the 
 method of draining with tiling. 
 
 Fig. 32.-TILK Draining ^^ ^^^, ^^^^^^^ increase in value 
 
 and we come to want to use our whole season in maturing 
 two or more crops, tiling will likely come into favor. 
 
 In some places, brush, poles, rocks, etc., have been put 
 into ditches and covered over so as to make cheap under- 
 drains. 
 
IMPROVING THE LAND 
 
 QUESTIONS 
 
 Why do Southern lands wear out more rapidly than Northern 
 lands? AVhy do Eastern lands exhaust faster than Western lands? 
 Why is good land of such great importance to the farmer? What 
 lands are generally most easily improved? Suppose exhausted land 
 grows up in weeds, grass, and briers, will it become productive again ? 
 Sliould land thus growing up be burned off, or should the growth be 
 allowed to rot? What can we do to improve poor land faster than 
 turning it out? Besides growing crops on land to improve it, what 
 can we add to it? Give an example of physical improvement and 
 chemical improvement of land. Describe the plan used in the South- 
 ern States to prevent hilly or rolling land from washing into gullies. 
 What can be done to make creek bottoms productive? What shape 
 should an open ditch have to be most serviceable ? What can be done 
 to make large areas of flat marsh land productive ? What country has 
 reclaimed from the sea a great amount of land ? How do people go 
 to market in that country? Describe tile drainage. Why have the 
 Southern people not used much tiling ? 
 
 Observation. — Observe how much more productive old fencerows 
 and old building sites are than land regularly cultivated. Observe 
 liow much, better crops are grown this year on land that grew peas 
 last year. Note how much better the crop often is near a ditch 
 where drainage is good than farther away where the land is not so 
 well drained. 
 
CHAPTER XIII 
 
 ROTATION OF CROPS 
 
 English Rotation. — In England, clover, turnips, beans, 
 and wheat follow each other in regular order, and consti- 
 tute a five-year rotation. The lands of Great Britain were 
 once so poor that only about three bushels of wheat were 
 raised for each bushel planted. While invading France, the 
 people learned the value of such crops as clover, turnips, 
 and beans. By rotation of crops, bone fertilizers, and 
 stock feeding, they have built up the land till it makes 
 over twice as much wheat to the acre as the land in the 
 United States. 
 
 A Southern Rotation. — If an East Texas farmer plants 
 on a held cotton one year, corn and peas the next year, 
 and oats followed by peas the third year, he not only has 
 an excellent three-year rotation, but grows five crops in 
 the three years — two of them restorative crops. Where 
 cotton can be matured and gathered early, it might be a 
 good plan to have the oats follow the cotton. Corn and 
 peas leave the land very dry, and oats come up much bet- 
 ter if sown on land that has been well worked in cotton. 
 It might be well to sow oats after one of the pickings and 
 cover them Avith a cultivator run between the rows. 
 
 Different crops do not require different elements of 
 plant food. They all require the same elements, but they 
 
 80 
 
ROTATION OF CROPS 
 
 87 
 
 use them in different proportions. Therefore, one kind 
 of crop may temporarily exhaust the soil of one element, 
 and cease to grow well, while another crop can still do 
 well. But the greatest benefit of this, or any other rota- 
 tion, arises from the restorative crops grown, and the 
 
 CowPEAs AND Sweet Sou(iHiM 
 
 great amounts of nitrogen the bacteria enable them to 
 get from the air. 
 
 Cotton Every Year. — The constant planting of land to 
 cotton rapidly exhausts the humus of the soil, because if 
 cotton is cultivated close and clean, there is little in the way 
 of grass, weeds, and trash left to rot on the land. For the 
 same reason cotton land washes badly. A corn and pea 
 crop, followed by an oat and pea crop, will build up the 
 
88 
 
 ELEMENTS OF AGRICULTURE 
 
 land rapidly ; for these crops leave stalks, stubble, and 
 vines, which, when plowed under, rot and make humus, 
 and supply plant food. 
 
 A good system of rotation also affords an opportunity 
 to use commercial fertilizers most profitably, if the land 
 is of a kind that responds to fertilizing. 
 
 Fig. 34. — Hogs grazing Cowpeas 
 
 Fertilizing Restorative Crops. — Commercial fertilizers 
 have their best effects Avhere there is plenty of humus. 
 A pea crop does not need nitrogen in its fertilizer, as it 
 gets nitrogen from the air. It will seldom need potash. 
 So it can be fertilized cheaply with acid phosphate, which 
 supplies only phosphoric acid. The 5aeld of pea vines 
 will often be doubled by this cheap fertilizing, and conse- 
 
ROTATION OF CROPS 89 
 
 queiith^ the nitrogen the peas get from the air will be 
 di)ubled, and the good effects on the land will be greatly 
 increased. Since land once well enriched with pea vines 
 needs only acid phosphate for corn and cotton, all the 
 fertilizing can be cheaply done. 
 
 The teacher and the pnpil are referred to bulletins of 
 the Louisiana, Mississippi, and Georgia Experiment Sta- 
 tions, which give the results of many years of work with 
 this three-year rotation in connection with commercial 
 fertilizers. In each state very poor land was soon built 
 up so that it produced a bale of cotton to the acre, and 
 other crops in the same proportion. 
 
 Dividing the Farm. — To follow such a rotation, a farm 
 should be divided into three parts, having one third in 
 each crop each year. This plan would better distribute the 
 labor of men and teams over the season. It would afford 
 so much corn, peavine hay, oats, etc., to feed on, that 
 more stock could be kept and more manure saved, — both 
 of which would be helpful in further building up the land. 
 
 It would make no particular difference if cotton now and 
 then should be grown two years in succession on a field, 
 or if oats should be left out once in a while. Other crops 
 might be substituted for some of those mentioned. One 
 need not follow absolutely any particular plan of rotation. 
 Some lands are not equally well suited to all these crops, 
 but grow one particularly well. Such lands may well be 
 used for one crop and fertilized, if need be, to keep up 
 their fertility. Then certain land for orchards, gardens, 
 and for other special purposes could be set aside, and the 
 rest of the land could be used for crops in rotation. 
 
90 ELEMENTS OF AGRICULTURE 
 
 Other Rotations. — Rotations may be cliangecl to suit 
 the crops, and to some extent the markets. In the lime 
 lands, alfalfa should be a particularly valuable crop. 
 Once planted, it would be profitable as long as a good 
 stand holds out, maybe five or six years. The land could 
 be used for alfalfa so long, and then planted in cotton and 
 corn five or six years. In some sections wheat may be 
 substituted for oats in the rotation. 
 
 Rice land would be greatly benefited if, in off years, 
 when the planter is waiting to get rid of red rice, the 
 land could be drained and grown in cowpeas or other 
 restorative crops. The sugar planter generally rotates 
 his cane land with corn and peas. In West Texas, small 
 grain should be followed with cowpeas the same season, 
 provided cotton, corn, kafir, milo, or sorghum is to grow 
 on the land next season. The land should catch enough 
 rain and snow, especially if plowed and harrowed in early 
 winter, to bring up the spring crops. But if fall-sown 
 grain is to follow small grain, then the land should be 
 plowed and kept disked to make it moist enough to bring 
 up seed in fall. 
 
 QUESTIONS 
 
 What is a rotation of crops? What crops do the people grow in 
 rotation in England? Has the rotation been very beneficial in that 
 country? What is a good rotation of common crops for the South- 
 ern States ? Why is this a good rotation ? What effect does it have 
 on land to grow cotton constantly on it? Can fertilizers be used 
 profitably in rotation ? Why would yoi;. not fertilize peas or peanuts 
 with fertilizers containing nitrogen? With what would you fei'tilize 
 peas? What Experiment Stations have succeeded well with a three- 
 year rotation? AVould following this rotation require one to put 
 
KOTATION OF CROPS 91 
 
 all of his farm in one crop each year? What crop maybe used to 
 advantage on the lime lands of Texas? What crop might take the 
 place of oats in rotation? Why do rice farmers have to stop grow- 
 ing rice for a year or more now and then? What could be done 
 with the rice land to advantage when it is lying out? 
 
 Experiment. — Get your father to rotate his crops on a small piece 
 of land as an experiment, if he does not do so regularly. 
 
CHAPTER XIV 
 
 MANURES AND FERTILIZERS 
 
 Value of Bones. — About seventy-five years ago a Ger- 
 man chemist named Liebig analyzed plants and found out 
 what they contained. By experimenting, it was learned 
 what ingredients the plants are unable to get in sufficient 
 quantity from poor land, and attempts were begun to com- 
 pound suitable mixtures of fertilizer ingredients. Liebig 
 was perhaps the first chemist to teach that bones, being 
 rich in phosphoric acid and fairly rich in nitrogen, are 
 good fertilizers. He afterwards wrote, bitterly complain- 
 ing that, after he had taught the Englishmen the value of 
 bone as a fertilizer, they had robbed the battlefields of 
 Waterloo, Leipsic, and the Crimea of a hundred thousand 
 tons of bones to enrich their fields. 
 
 Guano and Composts. — Peruvian guano, a bird manure 
 of certain rainless South American islands, was the first 
 concentrated commercial fertilizer used in this country. 
 It was used in the older cotton states from just after the 
 war between the states until about 1880, when the supply 
 was mostly exhausted. About 1870, David Dixon, of 
 Georgia, made composts, or mixtures of guano, manure, 
 leafmold, salt, and other things, and let them lie for 
 some time in large moist heaps, and then applied in the 
 cotton row before planting. He raised enormous crops 
 
 92 
 
MANURES AND FERTILIZERS 9S 
 
 of cotton, and accumulated a great fortune. It is prob- 
 able the salt and some other things were useless. But 
 a compost of commercial fertilizer ingredients with barn- 
 yard and stable manures or cotton seed never fails ta 
 give good results. It has been found, however, that 
 putting the manure or cotton seeil in the furrow, sprin- 
 kling the commercial fertilizer on it, and then bedding on 
 the mixture, does quite as well as first composting in a 
 heap. 
 
 Phosphate Rock. — Rock, rich in lime phosphate, a com- 
 pound of phosphoric acid and lime, is mined in Florida, 
 Georgia, Tennessee, Arkansas, and in many other parts 
 of the world. This rock is ground up by powerful mills 
 into a fine powder called ^oafs. As the phosphoric acid 
 is not easily soluble in this form, the powder is mixed 
 with sulphuric acid. This sulphuric acid combines witli 
 part of the lime, leaving the phosphoric acid in a condi- 
 tion to dissolve in water and to be used by crops. The 
 floats, thus treated with sulphuric acid and dried, are called 
 acid phosphate or superphosphate. This acid phosphate is- 
 the largest ingredient in most commercial fertilizers. It- 
 contains usually fourteen to sixteen per cent of pure phos- 
 phoric acid. The next prominent ingredient in commer- 
 cial fertilizers is cotton-seed meal, which contains about 
 seven per cent of nitrogen, three per cent phosphoric acid, 
 and one and a half per cent potash. A little kainit, or 
 other potash salt, found in Germany, is usually put into 
 the mixtures. When containing nitrogen, phosphoric 
 acid, and potash, a fertilizer mixture is called a complete- 
 fertilizer. Nitrate of soda, which is mined in Chile and 
 
94 
 
 ELEMENTS OE AGRICULTURE 
 
 contains about sixteen per cent of nitrogen, may be used 
 in place of part or all of the cotton-seed meal. The 
 nitrogen in nitrate of soda is more quickly available than 
 that in cotton-seed meal. For early, quick-maturing 
 crops, nitrate of soda should take the place of some of 
 the cotton-seed meal. Dried blood or other slaughter- 
 house refuse and dried fish are also often used. The 
 nitrogen in these is about as quickly available as that in 
 cotton-seed meal. The dried fish is rich in nitrogen and 
 phosphoric acid. 
 
 Where Potash is Needed. — It has been learned from 
 
 experiments that 
 the soils of Mis- 
 sissippi, Louisiana, 
 and Texas do not 
 generally need 
 potash. So no pot- 
 ash salt should be 
 used in the mix- 
 tures for these 
 states. In Georgia, 
 the Carolinas, and 
 Alabama, a little 
 potash is generally 
 found beneficial. 
 
 Fertilizer Mix- 
 tures. — Equal 
 parts of cotton- 
 seed meal and acid phosphate mixed will make an excellent 
 cotton fertilizer for old and worn lands. Such a fertilizer 
 
 Fig. 35. 
 
 Fertilized and Unfertilized 
 Cotton 
 
MANURES AXD FERTILIZERS 95 
 
 will contain about three and a half per cent of nitrogen and 
 nine per cent of phosphoric acid, and about three fourtlis 
 per cent of potasli. For land not so badly worn or land 
 that has been in pasture, or been lying out one or more 
 years, 1300 pounds of acid phosphate and 700 pounds of 
 cotton-seed meal, making a ton, would probably be better 
 than the other meal-acid-phosphate mixture. For land 
 needing potash about two hundred pounds of kainit 
 should enter into each ton of mixture. Trade conditions 
 now seem to warrant us in valuing nitrogen in fertilizers 
 at seventeen cents a pound, and phosphoric acid and 
 potash at six cents a pound each. 
 
 Balancing Manures. — Barnyard and stable manures are 
 not well enough balanced without some additional phos- 
 phoric acid to give the most valuable results on most of 
 the thin lands of the cotton states. If every load of 
 manure had a hundred pounds of acid phosphate added 
 to it, the results would be better, and it would go much 
 farther. Manure, as a rule, is much richer in nitrogen 
 and potash than in phosplioric acid. Experience has 
 shown that for most sections a fertilizer should be richer 
 in phosphoric acid than in anything else. 
 
 Rich Food makes Rich Manure. — The quality of fresh 
 animal manures largely depends upon the kind of food 
 the animals eat. No food eaten by animals loses much of 
 its fertilizing value by passing through the animals. The 
 manure made from feeding cotton-seed meal will never 
 contain less than seventy -five per cent as much fertilizing 
 value as the meal had, and it may contain as much as 
 ninety per cent. Manure made from feeding cotton seed 
 
96 ELEMENTS OF AGRICULTURE 
 
 will be richer than that from feeding corn, because cotton 
 seed is richer than corn. 
 
 The liquid manure from well-fed cattle will contain 
 half or more of the total fertilizing value of the feed. 
 From cattle eating mostly coarse food, the liquid will not 
 contain so much of the fertilizing value. 
 
 In order to save the liquid manure properly in stables, 
 bedding for the cattle should be provided so as to absorb 
 and hold it. 
 
 As has been said before, if animals are allowed to tramp 
 the manure down in the stables, its value will be preserved 
 better than in any other way, unless it be applied to the 
 land and mixed with the soil from day to day. 
 
 Value of Manure. — A dairy cow, well fed, will produce 
 ten cents' worth of manure a day, if the plant food is 
 rated at the same price that has to be paid for it in com- 
 mercial fertilizers. A horse well fed on oats and grass 
 hay will produce nine or ten cents' worth a day, but of 
 course not all of it will be dropped in the stable. If tlie 
 horse is fed on peavine, peanut, or alfalfa hay, the manure 
 will be worth more. Your past lessons have taught you 
 why this is so. Immense losses occur every year on ac- 
 count of the poor way in which farm manures are handled. 
 In fact, on most farms no attempt is made to save and use 
 them. 
 
 A ton of cotton seed has about the same plant food that 
 a thousand pounds of cotton-seed meal has. The meal 
 rots quicker, and is perhaps better for quick-growing 
 crops. As the seed supplies more humus to the land, it 
 will give results the second and third years after using. 
 
MANURES AND FERTILIZERS 97 
 
 QUESTIONS 
 
 Who was the first man that analyzed plants? What complaint 
 did he make against the English people? What was the first con- 
 centrated fertilizer used in the United States? Tell about David 
 Dixon's first experience in using this concentrated fertilizer. Where 
 is the phosphoric acid of fertilizer obtained? How is phosphate rock 
 treated? What is the name of the product made from phosphate 
 rock ? What is generally mixed with it? What may take the place 
 of cotton-seed meal in fertilizer mixtures? What is meant by com- 
 plete fertilizer ? What advantage has nitrate of soda over cotton- 
 seed meal as a fertilizer? What other materials are rich in nitrogen? 
 What states appear to need no potash added to their soil? What 
 states appear to need some potash in their fertilizer mixtures? Name 
 a suitable mixture of acid phosphate and cotton-seed meal for cotton 
 to be grown on worn land. What may be added to barnyard manure 
 to make it more valuable? W^hat fertilizer ingredient should nearly 
 all fertilizer mixtures be richest in? Is very much fertilizing matter 
 lost from feed stuff by being eaten by animals? Which will produce 
 richer manure when fed to animals, corn or cotton seed? Which will 
 produce richer manure when fed, peavine or Johnson-grass hay? 
 How much cotton seed will equal a ton of cotton-seed meal in ferti- 
 lizing value ? Which will have the most lasting effect when used as a 
 fertilizer, cotton seed or cotton-seed meal? Which will give the 
 quickest results? 
 
 Experiment. — Manage to get a few rows of cotton and corn on the 
 farm at home fertilized with cotton-seed meal, a few rows with acid 
 phosphate, and a few rows with kainit, using all fertilizers at almost 
 the rate of one hundred and fifty pounds per acre. Watch growth of 
 crops carefully and if possible weigh and measure yields. Then use 
 a mixture of meal and phosphate, a mixture of meal and kainit, and 
 a mixture of phosphate and kainit in the same way, and also note 
 results. See if the author is correct about the kinds of fertilizers 
 needed. 
 
 Try fertilizing peas or peanuts with cotton-seed meal, with phos- 
 phate, and with kainit in the same way. Report results to school 
 next year. 
 
CHAPTER XV 
 
 COMMERCIAL FERTILIZERS 
 
 Large Use of Fertilizers. — The use of commercial fer- 
 tilizers has grown enormously in a few years. Georgia 
 used in 1907 perhaps $15,000,000 worth and used them 
 profitably. Texas used perhaps less than 20,000 tons, yet 
 Texas probably has more land suited for using such fer- 
 tilizers profitably than Georgia has. Arkansas and Okla- 
 homa also have much of such land. Practically all of the 
 timber belts, most of the coast prairies, and much of 
 the sandy and loamy lands in the red-land sections in 
 Louisiana, Arkansas, Oklahoma, and Texas would prob- 
 ably readily respond to commercial fertilizers. The lime 
 lands and the dry lands of the West are generally too rich 
 for ordinary amounts of commercial fertilizers to be used 
 on them with profit. 
 
 Valuing Fertilizers. — A mixture of 1200 pounds of 
 cotton seed and 800 pounds of acid phosphate to the ton 
 makes a good fertilizer. 
 
 This mixture contains about 36 pounds nitrogen, worth 
 $6.12, about 126 pounds phos23horic acid, worth $7.56, 
 and about 20 pounds potash, worth $1.20. Total value, 
 $14.88 per ton. 
 
 Of the meal and acid phosphate mixture first named 
 on page 91, 2000 pounds contain: — 
 
 98 
 
COMMERCIAL FERTILIZERS 99 
 
 70 pounds nitrogen @ .17 $11.90 
 
 180 pounds phosphoric acid@ .06 10.80 
 
 15 pounds potash @ .06 .90 
 
 Total value per ton, $23.60 
 
 For Georgia, Alabama and the Carolinas 1200 pounds 
 phosphate, 700 pounds cotton seed meal, and 100 of 
 muriate or sulphate of potash are often recommended ; 
 also 1000 pounds phosphate, 700 pounds meal, and 300 
 pounds kainit. Kainit contains 12% of potash, and 
 muriate and sulphate about 50% of potash. 
 
 Nitrate of Soda. — The nitrogen in nitrate of soda acts 
 more quickly than that in cotton-seed meal. All plants 
 need fertilizers when young. So a mixture probably 
 better than the last one named would be 1400 pounds 
 acid phosphate, 400 pounds cotton-seed meal, and 200 
 pounds nitrate of soda to the ton. Or, for badly worn 
 land, 1200 pounds acid phosphate, 600 cotton-seed meal, 
 and 200 nitrate of soda. Where whole seed are used 
 instead of meal, 1000 pounds seed, 850 pounds acid phos- 
 phate, and 150 pounds nitrate of soda are recommended. 
 For quick-growing crops like early truck crops a still 
 larger proportion of nitrate is recommended. 
 
 Richness of Mixtures. — The different fertilizer mix- 
 tures which contain cotton-seed meal and cotton-seed 
 meal and nitrate of soda are all richer than the aver- 
 age fertilizer which is sold for cotton. One hundred and 
 fifty pounds to the acre are about equal to 200 pounds 
 of ordinary cotton fertilizer. These mixtures are about 
 as rich as most of the so-called vegetable fertilizers. 
 
100 ELEMENTS OF AGRICULTURE 
 
 except that the latter usually have a large amount of 
 potash. 
 
 Do Fruits need Large Proportions of Potash? — It lias 
 been generally supposed that fruits and vegetables need 
 larger proportions of potash than ordinary field crops do ; 
 but from what would seem conclusive results in Louisiana, 
 Mississippi, and Texas, potash is not profitable to use for 
 any crop on any soil yet tried in these states. There 
 seems to be no proof anywhere that fruits and vegetables 
 need a larger proportion of potash than corn or cotton. 
 The kind of land more than the kind of crop seems 
 generally to determine the kind of fertilizer. For well- 
 known reasons this statement does not apply to legumi- 
 nous crops and their nitrogen supply. Tobacco needs a 
 larger proportion of potash than most crops, as its ash 
 contains a very large amount of this ingredient. 
 
 Proportions of Plant Food in Mixtures. — The Southern 
 manufacturers and users of fertilizers, in mixing their 
 materials so as to contain two per cent of nitrogen, eight 
 per cent of available phosphoric acid, and one and a half 
 to two per cent of potash (or in about those proportions), 
 seem to be much nearer the best practice than Northern 
 manufacturers and mixers follow. Books have been writ- 
 ten giving what are supposed to be the fertilizer needs of 
 almost all crops, and the only basis for supposing the 
 crops to need plant food in the proportions recommended 
 seems to have been the analysis of the crops themselves. 
 Analysis shows that nearly all crops contain more potash 
 than phosphoric acid. That is no indication that ferti- 
 lizers for such crops should contain more potash than 
 
COMMERCIAL FEHTILIZERS 101 
 
 phosphoric acid. Ahiiost all lands are richer in potash, 
 generally three to four times as rich. From the best- 
 known chemical means of determining available plant 
 food, there are many times as much available potash in 
 average soil as there is phosphoric acid. 
 
 Many of the largest fertilizer companies in the country 
 are putting more potash than phosphoric acid in their 
 fertilizers. Such practice is, without doubt, causing the 
 loss of millions of dollars annually. 
 
 Experiment Necessary. — Only actual field trials with 
 crops will afford proof of what they need on different 
 soils. The experiment stations of the country have made 
 the most reliable literature of agriculture we have, and 
 their results clearly show that, with rare exceptions, crops 
 need much more phosphoric acid than potash in fertilizers, 
 and in much of the country the latter is not needed at 
 all. In nearly all cases, the kind of land instead of the 
 kind of crop should decide which one of these elements 
 is most needed. A slightly worn, muck land in Illinois 
 and the neighboring states needs only potash to make it 
 productive again. Very poor sandy land in Florida 
 needs potash, but still more phosphoric acid and nitrogen. 
 Some land in Mississippi and the states west of the Missis- 
 sippi River probably need potash — particularly deep sandy 
 land. Farmers should make some tests for themselves. 
 
 Stimulating Effects of Fertilizers. — Many people ask if 
 commercial fertilizers do not have a stimulating effect, 
 and if they do not wear out the land. 
 
 It is true that 100 pounds of fertilizer will often increase 
 the cotton crop 500 pounds of seed cotton to the acre. 
 
102 ELEMENTS OF AGRICULTURE 
 
 This cotton, together with the seed, contains more plant 
 food than the fertilizer contained, notwithstanding some 
 of the latter is always washed away. The explanation is 
 that the fertilizer causes a strong growth of root that en- 
 ables the crop to get more plant food out of the soil than 
 it would get otherwise. To that extent fertilizer wears 
 the land. But if we can get the plant food in the form 
 of valuable cotton, we shall be more than repaid for the 
 wearing of the land. 
 
 Effects Permanent. — By using reasonable amounts of 
 fertilizers with coarse manures and cotton seed, or with 
 suitable rotation of crops, lands are steadily and perma- 
 nently enriched. We have abundant evidence that where 
 large quantities, say from 800 to 2000 pounds to the acre, 
 are used for vegetables, such as cabbage or Irish potatoes, 
 and these crops are followed tlie same season by cotton or 
 sweet potatoes, the land grows better from year to year. 
 
 Where Fertilizers Pay. — Fertilizers seem to pay best 
 on land which is sandy enough to drain perfectly, and 
 which, at the same time, has a good percentage of clay 
 in the subsoil. Such are the long-leaf and short-leaf pine, 
 oak, and hickory lands of the Southern States. Also 
 much of the coast prairies and practically all of the post- 
 oak timber lands of Texas and Louisiana are of this char- 
 acter. For staple crops, fertilizers seem to pay best on 
 land naturally rather poor in plant food, making at best 
 less than half a bale of cotton to the acre. The author 
 has frequently seen moderate applications fail to show 
 any good effects on land fertile enough to yield two 
 thirds of a bale of cotton. 
 
COMMERCIAL FERTILIZERS 103 
 
 For vegetables, large applications of fertilizer on land 
 of almost any character will generally pay. Fertilizers 
 have generally been unprofitable on lime land. These 
 lands have such large stores of plant food that they only 
 need to have their physical condition improved. Rota- 
 tion of crops, coarse manures, pasturing, etc., will make 
 available enough of their own food to restore their former 
 productiveness. The Alabama Experiment Station, how- 
 ever, did find that large applications of commercial fer- 
 tilizers, containing an abundance of nitrate of soda, paid 
 well on well-drained, worn lime land. Nitrate of soda 
 used in side furrows during cultivation also gave good 
 results in frequent trials at that station. 
 
 Method of applying Fertilizers. — Barnyard manure is 
 generally spread broadcast on the land, wliile commercial 
 fertilizers are usually applied in the drill before planting. 
 For cotton, the fertilizer is generally sprinkled in a furrow 
 and bedded on. 
 
 Experiments have well demonstrated that all manures 
 and fertilizers give better results if they are strewn in 
 the drill, or under the drill, where the crops are to be 
 grown. It used to be thought that it was best to put 
 fertilizers very deep in the ground. The Louisiana Ex- 
 periment Station and others have proved that probably 
 it is better to use them about the depth of the seed or a 
 little deeper. The Georgia Experiment Station got better 
 results by bedding on fertilizers than by putting them in 
 the furrow with the seed. It has been believed that some 
 of the fertilizers should be used at or before planting, and 
 some in side furrows during the cultivation of the crop. 
 
104: ELEMENTS OF AGRICULTURE 
 
 Wliere moderate amounts of fertilizers are used for 
 cotton, all experiments indicate that it is a little more 
 profitable to use the full amount just before or at plant- 
 ing time. It has often paid to use part of corn fertilizer 
 at the second cultivation. Nitrate of soda applied during- 
 the cultivation of cotton has proved to be profitable in a 
 number of experiments. 
 
 Amount of Fertilizers to Use. — It has been proved by 
 all experiment stations tluit small applications of concen- 
 trated fertilizers, say 100 to 200 pounds to the acre for 
 cotton, pay a larger percentage of profit on the cost of 
 fertilizer than larger applications ; but larger applica- 
 tions, 300 to 400 pounds, or even 600 pounds, often pay 
 a bigger profit to the acre. It is always unprofitable to 
 use too large an amount. 
 
 It appears to be well established that land badly worn, 
 and having little humus, will give good profits on only 
 small applications of fertilizers. The land seems not to 
 hold water enough to support a large crop. It follows that 
 land in good condition from rotation of crops, pasturing, 
 being allowed to grow up in weeds, or plowing under 
 coarse manure, will supply water for a big crop, such as a 
 large amount of fertilizer ought to produce. 
 
 Every farmer should, by careful observation, find out 
 just how much fertilizer it will be profitable to put on his 
 land. From three to ten times as much fertilizer is often 
 used on Irish potatoes, cabbage, onions, and other vege- 
 table crops, as on cotton or corn. 
 
 Fertilizers almost always pay better on cotton than on 
 corn. ( 
 
COMMERCIAL FERTILIZERS 105 
 
 QUESTIONS 
 
 Give an example to show how large the trade in commercial 
 fertilizers has become. Should fertilizers be used more largely 
 in Texas than at present? What lands in Texas would probably 
 give profitable results with commercial fertilizers? What amounts 
 of cotton seed and acid phosphate mixed would make a ton of good 
 fertilizer? What are nitrogen, phosphoric acid, and potash valued 
 at in fertilizers ? Would you use a larger proportion of cotton- 
 seed meal on badly worn land than on better land ? Why would 
 some nitrate of soda be of advantage in every fertilizer mixture? 
 What are the vegetable fertilizers, generally sold, rich in ? What was 
 the belief about commercial fertilizers wearing out land? What mis- 
 takes are made by some Northern manufacturers in mixing fertilizers ? 
 Do commercial fertilizers wear out the land? Do large amounts of 
 fertilizers improve the land rapidly? Do small applications of com- 
 mercial fertilizer pay better on rich land or poor land? What kind 
 of crops, if any, need the highest percentage of potash in their fer- 
 tilizers? Tell about fertilizing lime land. What is usually the 
 best treatment to make lime land productive? Are fertilizers and 
 manures most effective when spread broadcast over the land or 
 when used in the row ? How deep has it been found necessary to put 
 fertilizers in the ground? Has it been found profitable to use part 
 of the fertilizer before planting and part while working the crop? 
 Which pays the better, a small application of fertilizer or a large 
 application? Why can large applications not be used profitably if 
 the land is very badly worn ? How much more fertilizer is generally 
 used to the acre for cabbage and onions than for cotton and corn ? 
 
CHAPTER XVI 
 
 PLOWING 
 
 Subsoiling. — Plowing is the primary operation of the 
 farm or the garden. Yet people hold very different opin- 
 ions as to how it should be done. All the older agricul- 
 tural literature advised that the deeper plowing could be 
 done the better on all classes of land and for all kinds 
 of crops. This same opinion seems to be held by many 
 agricultural writers even now. Subsoiling, particularly 
 following a turn plow with a bull-tongue, running deep 
 in the same furrow, so as to loosen the subsoil twelve 
 to eighteen inches deep, is frequently recommended. 
 
 The Georgia Experiment Station tried subsoiling on 
 perhaps hundreds of plots of land for some ten years or 
 more, but the crops were never any better than those that 
 received ordinary plowing. The Mississippi Stations, 
 two of them, thoroughly tested subsoiling on different 
 lands, for different crops, and at different seasons of the 
 year. The crops were never increased over those made 
 on lands plowed in the usual way. 
 
 The Kansas Experiment Station tried subsoiling for 
 many years, but the yield of the crops was never in- 
 creased. The experiment stations of. many other states, 
 including Texas, have been similarly disappointed in sub- 
 
 100 
 
PLOWING 107 
 
 soiling. It is expensive to subsoil land, and if it does no 
 good, it should not be recommended. The truth seems ta 
 be that there is very little land where subsoiling pays. 
 Many farmers have reported good results from subsoiling^ 
 while others have reported no results, and still others,, 
 injury from it. 
 
 Depth to Plow. — There is a difference of opinion among 
 people who do not subsoil land as to how deep it should 
 be broken in its preparation. Doubtless different soils 
 and different crops should influence the depth of prepara- 
 tion, if their requirements could be definitely known. 
 The Alabama Experiment Station for a number of years 
 subsoiled some land and broke other pieces to depths 
 varying from three and one half to six and one half 
 inches. The subsoiling did not pay for either cotton or 
 corn, and the different depths for breaking did not seem 
 to give any marked difference in crops. One depth 
 yielded most one year, and another depth yielded most 
 another year. The different depths of breaking averaged 
 about the same yield for both corn and cotton. The 
 Indiana and Oklahoma stations tried eight-inch plowing 
 against four-inch for many years, and generally did not 
 get increase enough in yield to pay for the extra work of 
 breaking deep. Every farmer should make some tests 
 for his own land. 
 
 The Texas Experiment Station planted sorghum on one 
 piece of land subsoiled fifteen inches deep, on another 
 plowed five inches deep, and on still another plowed three 
 inches deep. That broken five inches deep yielded much 
 more than either of the others. The subsoiled piece made 
 
108 ELEMENTS OF AGRICULTURE 
 
 a little more than the piece broken three inches deep. So 
 it would seem that breaking the land or bedding it an 
 ordinary depth is best, and we know it is cheapest. 
 
 Deep Plowing for Cane. — In Australia and Hawaii, deep 
 breaking and planting have proved best for sugar cane, 
 but it is probable that the deep planting serves to keep 
 the tall tropical cane from falling down, and that it yields 
 more on this account. Many experiments at several ex- 
 periment stations in Australia failed to give any good 
 results for especially deep breaking for other crops. 
 
 H. W. Campbell, who has won something of national 
 fame on account of the results achieved in farming 
 semiarid land, claims that it is far more important to 
 compact the soil plowed and make it thoroughly fine 
 than to plow it deep. He recommends plowing from 
 three to seven inches deep, according to the conditions, com- 
 pacting again, and then working up a fine mulch of sur- 
 face soil about three inches deep. In a conversation with 
 the author, Mr. Campbell said that it would be well-nigh 
 impossible to compact land plowed twelve inches deep 
 so as to get it again in good condition for drawing up 
 moisture from the subsoil. 
 
 Purposes of Plowing. — Plowing serves to bury trash 
 and manure, to make a seed bed, to conserve moisture, 
 to kill weeds and grass, to allow air and water to enter 
 the soil better and promote chemical changes, to allow 
 roots of crops to grow better, etc. 
 
 All farmers' boys and girls know a plow and its differ- 
 ent parts. If not, they should ask their fathers and 
 neighbors about these things. 
 
PLOWING 109 
 
 Black-land and Sandy-land Plows. — A plow is a sort 
 of twisting wedge. The more twisting the wedge the 
 more it turns the soil and the more it pulverizes it, but 
 the harder it is to pull, and the poorer it will scour in 
 black or stiff soil. The straighter and more tapering 
 the moldboard, or wedge, the easier it will be to pull, 
 the less it will turn and break and crumble the soil, the 
 
 Fig. 36. — Sandy-land Plow 
 
 Fig. 37. — Black-land Plow 
 
 brighter it will keep, and the better it will work in stiff 
 and black land. Figure 37 shows a good type of a black- 
 land plow, also suitable for any stiff clay soil. Figure 36 
 is a good picture of an ordinary, or sandy-land plow. 
 
 Sandy-land plows are apt to choke and cake on black 
 land. The black land may be broken up cloddy, but as 
 
110 ELEMENTS OF AGRICULTURE 
 
 explained before, the lime it contains soon causes the 
 clods to melt down into little shotlike particles. This is 
 xdso true of much of the bottom land. 
 
 Killing Bermuda Grass. — It is often advisable to use a 
 black-land plow in sandy sections. To kill Bermuda 
 grass where it has been pastured, the sod should be 
 broken in the fall or winter about three inches deep 
 with a small black-land plow, going at such speed and 
 held in such a manner that the furrow slices will be 
 turned on edge. This causes the grass to freeze and die. 
 On pastured land, the underground stems of this grass 
 have to come near the surface for air, and hence shallow 
 23lowing at the right season causes them to freeze. The 
 land on which the Bermuda grass has been killed in 
 this way is always rich and productive when brought 
 back into cultivation. 
 
 Killing Johnson Grass. — Johnson grass may be pastured 
 two years and killed by careful working of the land in 
 cotton a year or two. The big fleshy runners, which go 
 down so deep in cultivated land, come close to the surface 
 when pastured, and get small and weak. If, after being 
 pastured, the land is broken in the fall and then thor- 
 oughly plowed again in the spring and worked well and 
 late in cotton, the grass can be entirely killed. After 
 the turf has been killed and rotted, the land becomes 
 very productive. 
 
 QUESTIONS 
 
 What was the old idea with regard to plowing? What is sub- 
 soiling? What have the Experiment Stations found out about sub- 
 soiling? Is it definitely known how deep land should be plowed? 
 
PLOWING 111 
 
 What about plowing deep for sugar cane? What is the Campbell 
 system of soil culture? Name some of the different purposes for 
 which plowing is done. How may a plow be compared to a wedge ? 
 What sort of plow should be used in black land? Which will pul- 
 verize and crumble the soil most, a black-land plow or a sandy-land 
 plow ? What would happen to a sandy-land plow if used in sticky 
 black land? How would you kill Bermuda grass? Could you kill 
 Johnson grass in the same way? lu what condition is the land after 
 killing Bermuda grass? Explain why this is so. After killing 
 Johnson grass, what condition will the land be in? What effect will 
 the rotting of any grass, weeds, or other vegetable substance have on 
 the land? 
 
CHAPTER XVII 
 
 PREPARATION FOR PLANTING 
 
 Bedding or Flat-breaking. — As to whether land should 
 be broken flat or thrown into beds is a question which 
 depends on the character of the land, the kind of crop, 
 the season of the year, and the amount of moisture in the 
 soil. On sandy soil in the West it would be undoubtedly 
 a fine plan to plant corn in the bottom of a lister, or 
 "buster," furrow, either with a planter attachment or 
 with a drill to follow after the lister. In case you d(nvt 
 know what a lister is, get some good farmer to show you 
 one and explain it to you. By planting the corn in the 
 bottom of the furrow on hard ground, it will be sure to 
 get enough moisture to come up. Your father will tell 
 you that cotton, wheat, or clover planted in well-settled, 
 firm ground, will come up much better than in freshly 
 made, loose ground. Hard, firm land can draw up 
 moisture from below. A fresh, loose bed, with seed 
 planted far above the firm ground, is something like a 
 lamp wick cut in two between the flame and the oil. 
 The seed cannot get enough moisture to come up. When 
 the young corn is in the bottom of a furrow with ridges 
 of loose dirt in the middle, the dirt can be gradually 
 worked to tlie corn, and little weeds and grass can be 
 covered at each working. The corn, when deep rooted, 
 
 112 
 
PREPARATION FOR PLANTING 113 
 
 is better able to endure drought and to stand up in the 
 storms. Cotton in some cases might also be worked in 
 the same way, but when young, it is a more tender 
 plant than corn, and it is more likely to need starting 
 on a small bed or on level ground, even in dr}^ sections. 
 
 In Eastern or Southern States, land must be very 
 sandy, or the planting must be late, to justify planting in 
 lister furrows. Generally, on clay or bottom land, early 
 corn and cotton are both planted on beds for the sake of 
 getting sufficient drainage to secure good stands. Corn 
 is sometimes planted on beds eight feet wide, two rows 
 being planted on each bed. This gives drainage on one 
 side of each row of corn. 
 
 Bedding with Lister. — One of the best and cheapest 
 Avays to bed for cotton is to use a lister. The old rows 
 should be broken out in the fall, winter, or early spring. 
 This will make beds in the old middles. Then if, some 
 time before planting, these beds are burst with the lister, 
 the beds for planting will be where they were the pre- 
 vious year. This preparation is much cheaper than bed- 
 ding and re-bedding with a turn plow, and so far as we 
 know, is quite as good. If fertilizer is used, it should 
 be sprinkled in the middles just ahead of the lister when 
 the land is being re-bedded, so that the beds will be over 
 the fertilizer, or else tlie fertilizer should be put in the 
 furrow at planting time. In the drier districts the earlier 
 and deeper application of fertilizer is best. 
 
 Fall or Spring Breaking. — There has been much experi- 
 menting done to determine whether fall or spring break- 
 ing of land is best. In a majority of cases in the liumid 
 
114 
 
 ELEMENTS OF A(;RICULTURE 
 
 sections of the South, land broken in the spring has pro- 
 duced as good crops as that broken in the fall. Even 
 where pea vines have been grown, plowing the dead vines 
 under the next spring has done quite as well as plowing 
 them under green in the fall. Some believe that crops 
 
 Fig. o8. — Steam Plow on the Plains 
 
 turned under when very green form acids that are hurtful 
 to future crops. 
 
 It has been said that tillage is manure ; that is, tillage 
 enables the earth, air, and moisture to form soluble plant 
 food. This is true, and hence we should till or plow little 
 in a warm, wet country, unless we have crops growing or 
 soon to be started that will take up and use this plant 
 food, and prevent its being leached and washed away. 
 
 Where moisture is scarce, as in the Avestern part of 
 Texas, Oklahoma, and Kansas, fall plowing would un- 
 
PREFAIIATION FOR PLAN TIXG 
 
 llr: 
 
 (loubtedly pay. One of the things to be feared so far 
 west, where it rains little in winter and early spring, is 
 that there Avill not be moisture enough to bring up early 
 crops. Plowed land in arid or humid climates, summer 
 or winter, always contains more moisture than unplowed 
 land. One of the disadvantages of clay or bottom land in 
 humid climates is that, if plowed in the fall, it holds so 
 much moisture that it cannot be planted early in the 
 spring. Usually land that has not been plowed in the fall 
 can be bedded and planted in the spring before a team 
 can stand on the fall plowed land without bogging. The 
 trouble is still greater if the land is subsoiled in the fall. 
 
 Much land is of such a nature that if plowed in fall, 
 it compacts again and requires just as much preparation 
 the following spring. Lime lands, heavy bottoms, grass 
 sods, and lands hav- 
 ing large amounts of 
 weeds and trash, are 
 most likely to be ben- 
 efited by fall or early 
 winter plowing. Fall 
 plowing is often ad- 
 visable to destroy in- 
 sects, such as boll 
 worms, cut worms, 
 etc., and to kill cotton stalks, so as to deprive the boll 
 weevil of food. 
 
 Plowing Land when Wet. — Ordinary types of land 
 such as clays and loams are very likely to be injured 
 when plowed too wet, especially in late spring. It does 
 
 Fig. ol). — Sub-surface Packer 
 
116 ELEMENTS OE AGRICULTURE 
 
 not hurt light sandy hinds, lime lands, and the buckshot 
 lands of the bottoms to plow them wet, because the clods 
 that are formed crumble easily. It probably would not 
 hurt any land to plow it wet, if it were not that in dry 
 weather the clods become very hard. The rice land of 
 China and Japan is all plowed in the water, but owing 
 to the fact that the land is kept wet by irrigation, it con- 
 tinues to make good crops, as it has done for ages. 
 
 Plowing for Fall Seeding. — Any kind of land in which 
 small seeds, like alfalfa, turnips, rape, etc., are to be sown 
 in the fall, should be broken early in summer, if possible, 
 and kept clean of weeds by harrowing and disking till 
 planting tmie. Such land will be much more moist than 
 the land that grew a crop of grass or weeds until late in 
 the season. All kinds of plants, as we have seen, draw 
 heavily on the water of the soil. When two crops of 
 Irish potatoes are to be grown on the same land in one 
 year, the land should be well plowed and kept clean, 
 from the time of digging the early croj:) until planting 
 time of the second crop. In no other way, without irri- 
 gation, can land be kept moist enough in most seasons to 
 bring np and grow a fall crop of potatoes. 
 
 Working Crops. — Cultivation of growing croj)s is given 
 to kill weeds, to form a dirt mulch, to prevent too rapid 
 evaporation of moisture, and to stir up the soil to admit 
 air and cause rapid formation of soluble plant food in the 
 soil. It is often advised that cultivation should alwaj^s 
 be shallow — from one to two inches. Hundreds of ex- 
 periments have been made cultivating all depths to five 
 and six inches. Results have been very conflicting. 
 
PREPARATION FOR PLANTING 117 
 
 Three inches deep has perhaps averaged better yields than 
 deeper or shallower cultivation. This is about the depth 
 run by single sweeps so largely used for cotton in the 
 Soutli. A safe rule would seem to be to cultivate the 
 most convenient depth for destroying weeds and grass. 
 Cultivation may be given too often as well as too 
 seldom. For staple crops, 'cultivation each twelve to 
 fifteen days gives about as good results as more frequent 
 working. Where drought is feared, it may pay to work 
 oftener to break a crust formed by hard rains. 
 
 QUESTIONS 
 
 Would you plow land iu ridges or beds, or plow it level? How 
 may corn be j)lanted to advantage in dry sections? What is the 
 ditficulty sometimes experienced in planting cotton on fresh, loose 
 beds V Why is it better to plant on land that has had time to settle 
 and pack by rain ? If corn is planted in the bottom of a lister furrow, 
 can it be worked cheaper ? Why do we plant on beds at all ? Explain 
 how a lister is used in bedding land for cotton. Explain how fertilizer 
 is applied. Which has proved better, breaking land in the fall or in the 
 spring ? Has it been found best to plow pea vines under when green, or 
 to wait until they are dead ? In what part of the country would you 
 always plow land in the fall ? Which will always have the more water 
 in it, plowed land or unplowed land ? In the humid sections do you 
 have too much or too little water in the early spring? Which can 
 you plant earlier in spring in humid sections, fall-plowed or spring- 
 plowed land? What classes of land will do best for fall plowing? 
 Is it ever advisable to plow in the fall to kill insects? What kinds of 
 land may be plowed wet and not be injured? Why will it injure 
 clay land to plow it wet? How do the Chinese and Japanese manage 
 to plow land wet without injuring it? If you wanted to get a stand 
 of alfalfa in the fall, how would you treat the land? How would 
 you treat land to grow a fall crop of Irish potatoes ? 
 
 Experiments. — Get your father to plow a few rows twelve inches 
 deep, and a few rows about three or four inches deep, and plant both 
 
118 elp:ments of agriculture 
 
 alike. See if there is any value in subsoiling. If you can't get this 
 done, spade a small piece of ground twelve inches deep and another 
 three or four inches; plant and observe results. Let the ^Yhole school 
 know result next year. 
 
 Plant at school or at home a few seeds in two boxes of soil. Have 
 soil rather dry, and plant seeds in quite loose soil in one, and in the 
 other pack the dirt well after planting and then loosen soil above 
 seed. See what difference in the germination of the seed. This can 
 be done at school. 
 
 In the time of drought take off the top soil on well-cultivated land 
 on the farm and get a little box of subsoil, closing it up tight. Take 
 some subsoil from a hard-packed weed patch near by and close it up 
 in a can or box. Weigh each one and then see how much water you 
 can dry out of each one. 
 
 Observe whether fall plowing enables your father to plant earlier 
 or later in spring, and whether it helps or hinders early growth of 
 plants. 
 
 Wet some clay in boxes and stir one while wet, and then let it di-y 
 in the sun and note effect. Stir the other when it is moderately dry 
 and note difference. This is a suitable school exercise. 
 
CHAPTER XVIII 
 
 IRRIGATION 
 
 Watering Rice. — The importance of irrigation cannot 
 be overestimated. It is absolutely essential to make rice- 
 growing profitable, and to make other kinds of farming 
 possible in many sections. The fact that when arid lands 
 are irrigated, they at once become highly productive and 
 lasting in their qualities, has already been referred to. In 
 the rice-growing districts, large pumping machinery is 
 used, sometimes raising a hundred thousand gallons of 
 water a minute. This water is raised a few feet from 
 the large rivers, creeks, and bayous, and emptied into 
 broad, shallow canals, some of them a hundred feet wide. 
 The water flows along these canals a little higher than the 
 surface of the flat rice lands that are to be watered. 
 Smaller canals take water out of the big ones, and still 
 smaller ones take it out of these and distribute it to the 
 fields. By the time the big canal flows a few miles, and 
 has had half its water taken out by laterals, or small 
 canals, the water has become too low to flow out, and 
 another pumping station is put in to raise the water a 
 few more feet into a canal made with higher banks. 
 
 Storing Water. — In the mountain states, millions of dol- 
 lars liave been spent to build large concrete dams, some- 
 times a hundred feet high and a mile long, across canyons 
 or stream beds. These dams sometimes make lakes many 
 
 119 
 
120 ELEMENTS OF AGRICULTURE 
 
 miles long and tAvo or three miles wide, and the lakes hold 
 water enough to irrigate one hundred thousand or more 
 acres of land. The United States Government is putting 
 in a large number of these big storage reservoirs in the 
 West. By wise laws, the mone}^ derived from the sale of 
 public lands in the districts to be irrigated, is used for 
 building more dams, catching more water, and reclaiming 
 more rich, semidesert land. It is confidently believed that 
 eventually all the flood waters now flowing down the Mis- 
 souri, Arkansas, and other rivers, will be stored and lield 
 for summer irrigation. When this is done, there will be no 
 more danger of the great levees of the Mississippi River 
 breaking and flooding the rich delta country through 
 which the river flows. These are vast undertakings, but 
 our country is great and rich, and our people are enter- 
 prising and daring in developing its natural wealth. 
 
 Small Reservoirs. — There are thousands of small streams 
 and canyons that may be dammed by individuals or small 
 companies, where water enough may be stored to irrigate 
 from a few acres to several thousand acres. It may be 
 said that small reservoirs may be made at less expense 
 to the acreage reclaimed than in the case of larger ones. 
 
 Irrigation in Humid Sections. — The possibilities for irri- 
 gating profitably in tlie humid sections have been par- 
 ticularly neglected. Nearly every crop in every section 
 suffers more or less from drought at some time. Much 
 rain falls in Mississippi, yet the autlior has seen the 
 profits on strawberries increased by irrigation as much 
 as a hundred dollars to the acre. A Louisiana truck 
 raiser, by irrigating during a drought, made two hundred 
 
IRRIGATION 121 
 
 Hud fifty crates of cabbage to the acre, while the best yield 
 made by any neighbor was one hundred and fifty ci-ates. 
 The Wisconsin Experiment Station, situated in a humid 
 climate, pumped water from a depth of twenty- six feet 
 for irrigation, and burned coal costing five dollars a ton 
 to do the work. The increased yields averaged about 
 forty per cent on the different crops irrigated over those 
 that were not irrigated. The net extra profits made to 
 the acre one year, by means of irrigation, after paying 
 for pumping and distributing the water, were as follows: — 
 
 Hay -f 20.60 
 
 Corn 11.18 
 
 Potatoes .... 73.12 
 
 Water Reservoirs. — Water can be found in abundance 
 in many humid sections, and may be got cheaply on the 
 land itself. Small streams often flow through the land, 
 and these may be dammed up and made to flow over 
 it by gravity, or the water may be raised by pumping. 
 In the clay or lime districts where lasting streams are 
 not plentiful, storage reservoirs can be easily made by 
 damming stream beds, or hollows. In nearly all the large 
 vallej^s of streams, and on low-lying lands near the sea- 
 coasts, overflowing artesian water may be had. Through- 
 out much of the sandy and loamy areas of the country, 
 large shallow wells afford water at depths of from ten 
 to sixty feet, and the supplies may often be sufficient for 
 irrigation. 
 
 Crops needing Irrigation. — Among the crops that with 
 irrigation may be made very profitable in the Southern 
 
122 ELEMENTS OF AGRICULTURE 
 
 States are sweet potatoes, sugar cane, and fall Irish pota- 
 toes. Sweet potatoes and cane do their best growing 
 in September and October, when there is nearly always 
 a deficient moisture supply. In fact, the states east of 
 Texas are drier in these two months than the country 
 
 Fig. 40. — Irrigating between Rows 
 
 along the one hundredth meridian. With irrigation there 
 is little doubt that a hundred bushels can be added to the 
 yield of each acre of potatoes and one hundred gallons of 
 sirup for each acre of cane. Cane and potatoes both grow 
 in wide rows and on ridges; water can be easily applied 
 to each crop, by causing it to run along the middles be- 
 tween the rows. Whenever there is enough rain, tlie fall 
 crop of Irish potatoes, planted about August in tlie Gulf 
 States, makes quite as large and profitable a yield as the 
 
IRRrCiATION 123 
 
 spring crop. On account of drought in April or May the 
 early Irish potatoes scarcely produce a full crop one year 
 in ten. There is no crop more easily injured by deficient 
 moisture supply. 
 
 Mistakes in Irrigation. — A great mistake almost certain 
 to be made by a beginner in irrigation is, that he tries to 
 make a little stream of water, say ten to fifty gallons a 
 minute, irrigate a large piece of ground. To make such 
 a stream water even a quarter of an acre, troughs, hose- 
 pipes, etc., must be used, and that would make the labor 
 of distributing the water cost too much to be profitable 
 with ordinary crops. If one undertakes to run such a 
 small stream along rows or furrows, it will lose itself 
 perhaps in the first twenty feet. In order to run water 
 along ditches and distribute it to tlie rows and over the 
 land at a reasonable labor cost, at least two hundred 
 gallons a minute should be at command. Sucli a stream 
 may be let out of the ditch into several rows at a time, 
 and the water will perhaps follow the rows a distance of 
 a hundred yards. With this amount of water, one man 
 can probably irrigate from one to two acres a day. With 
 five hundred gallons' flow a minute, four or five acres a 
 day can be watered. Another mistake where water is 
 abundant is to use too much. Moderate applications of 
 water followed by cultivation as soon as the land will 
 work well will be found most profitable. 
 
 Storage Ponds. — Those who have small artesian wells 
 or small pumping plants, should construct reservoirs a 
 little above the level of the land to be watered, and should 
 accumulate water and let it out in large volume when 
 
124 ELEMENTS OF AGRICULTURE 
 
 it is to be applied. A flow of fifty gallons a minute will 
 accumulate about seventy-five thousand gallons of water 
 in twenty-four hours. This will afford a little over one 
 and two thirds inches of water for an acre of land, a 
 sufficient Avatering if it is applied in rows or furrows. 
 In an arid country, when the land is very dry, as much 
 as four inches may often be put on the land at one 
 irrigation. 
 
 Distributing Water. — In distributing water over a field, 
 the ditches must, of course, be kept on the highest ground. 
 The rows, or furrows, to carry the water must be run at a 
 suitable angle to the ditches, so as to have fall enough to 
 run the water at a reasonable rate of speed, and at the 
 same time not to wash the land. A little experience will 
 enable one to give the rows the best fall on his partic- 
 ular kind of land. Head ditches should sometimes be 
 one hundred yards apart and sometimes two hundred. 
 Experience and common sense will be the best guides as 
 to this. 
 
 In the arid country farmers sometimes flood the land 
 somewhat as the rice farmers do, keeping water on the 
 land just long enough to wet it thoroughly. 
 
 QUESTIONS 
 
 Tell about rice irrigation. What is the nation doing in the way of 
 irrigation? What about farming in arid countries under irrigation ? 
 What profits from irrigation are possible in humid countries? What 
 crops would probably respond profitably to irrigation? What 
 amounts of water are necessary? AVhat suggestions are made about 
 catching and storing water? What mistake is a beginner apt to 
 make at first in irrio'ation? 
 
CHAPTER XIX 
 
 INSECT FRIENDS AND ENEMIES 
 
 Losses Caused. — In 1907 the cotton boll weevil no doubt 
 destroyed, in Texas alone, a million bales of cotton, worth 
 not less than sixty millions of dollars. When we consider 
 the great number of harmful insects, we must conclude 
 that the losses occasioned b}^ them for the whole country 
 are enormous. 
 
 Not all insects are harmful. We have seen how many 
 of them, by carrying pollen and fertilizing flowers, make 
 plants fruitful. Then we have the bee and many other 
 useful kinds of insects. A little insect brought from 
 the Old World made possible the Smyrna flg industry 
 in California. 
 
 Insects destroy Other Insects. — Sometimes we can get 
 rid of bad insects only by finding other insects that will 
 destroy them. The great sugar industry of the Hawaiian 
 Islands was threatened some three years ago by a little 
 creature, called a sugar-cane leaf-hopper, that was intro- 
 duced by means of seed cane brought from Australia. 
 The government of the island territory hired a staff of 
 entomologists and sent part of them to Queensland to 
 find and send over the natural enemies of the hopper, 
 while the others were kept at home to breed these im- 
 ported insects and place them in the fields. In this way 
 the cane industry was saved. When we cannot cope 
 
 125 
 
126 
 
 ELEMENTS OF AGRICULTURE 
 
 \A'ith an enemy of this kind, we try to find some brave 
 little ally that will fight for us. We can keep up, in 
 some cases at least, a sort of balance of power among our 
 insect enemies. 
 
 Real insects have six legs and have their bodies in three 
 divisions — the head, the thorax, and the abdomen. Grass- 
 hoppers, bees, wasps, ants, etc., are typical insects. 
 
 
 ^l-r^'^J^^^^ ^^^-r- ^ :^ 
 
 
 'Ji 
 
 
 
 
 Fifi. 41. — Spkaying Fruit Trees 
 
 Classes of Insects. — Insects may be divided into two 
 large classes. One class, such as the grasshopper, the leaf 
 worm, and the potato bug, for instance, bite and eat their 
 food. These can be killed by sprinkling the plant with 
 a very weak solution of Paris green, sa}^ a heaping tea- 
 spoonful to a bucket of water. In eating the leaves, the 
 insect will get enough of the poison to cause its death. 
 
 The other class of insects are those that have tubes for 
 inserting into the tissues of the plant and sucking the 
 juices. Poisons will not kill these because they get none 
 of them. The only way to destroy the sucking insects is 
 
INSECT FRIENDS AND ENEMIES 127 
 
 to use some kind of spray that will burn their bodies. 
 A worm, called the cotton boll worm, tomato worm, or 
 corn worm, according to the kind of plant on which it is 
 found, eats leaves at times and can be killed with poison, 
 but after it has eaten into the ear, the boll, or the fruit, 
 it cannot be easily reached by poisons. 
 
 Cabbage growers often use Paris green to kill the cab- 
 bage worm, but do not let their customers know it. 
 Sucli applications are so small, and the poison is so nearly 
 washed off by rain, that no person has ever been known 
 to be hurt by eating cabbage treated in this way. 
 
 Killing Grain Weevils. — Corn and pea weevils that in- 
 fest our grains after they have been gathered can be easily 
 killed by placing the grain in barrels, boxes, tight bins, or 
 tight rooms, and placing on top or near the top of the 
 grain a cup or tin can containing a little bisulphide of 
 carbon, sometimes called "high life." This liquid evapo- 
 rates and forms a gas heavier than air, and this gas sinks 
 down through the grain and kills the insects. A tea- 
 spoonful to each two or three bushels of grain will accom- 
 plish the desired result. The gas soon passes off, and 
 does not hurt the seed for planting or for other use. 
 Weevils will get back in the grain later, and a new appli- 
 cation will be needed. 
 
 Insects carry Disease. — One kind of Southern cattle 
 tick carries the germs of the deadly Texas fever from 
 Southern cattle to Northern cattle. This will be discussed 
 later. The dreaded surra, which kills the horses of India, 
 China, Java, and the Philippines, is carried by biting flies. 
 
 It is now very well known that malaria, yellow fever, 
 
128 ELEMENTS OF AGIUCULTURE 
 
 and dengue fever are carried from one person to an oilier 
 by different species of mosquitoes. In biting a person 
 having malaria, the mosquito gets the germs of the dis- 
 ease, carries tliem away, and injects them into the next 
 person bitten. Since the discovery of this great truth, 
 people, by protecting themselves against mosquitoes, have 
 good health even in the great river bottoms of the South. 
 Typhoid fever is carried sometimes by the house fly. An 
 insect called the tsetse fly of Africa carries the dreadful 
 sleeping sickness of that country. It is quite likely that 
 insects play a more important part in the carrying of the 
 germs of human diseases than we yet know. 
 
 The Boll Weevil. — This insect pest came into South- 
 west Texas many years ago from Mexico, and has spread 
 
 Fig. 42. — Boll Weevil (Magnified) and Larva (Greatly Magnified) 
 
 eastward and northward till it has reached parts of Okla- 
 homa, Arkansas, and Mississippi. 
 
 About first frost the grown weevils appear to go into 
 winter quarters in timber, grass, weeds, and in any rub- 
 bish that may be convenient. The fact that weevils are 
 always numerous in fields near forests shows that the 
 woods afford them suitable places for hibernating, or liv- 
 ing through the winter. 
 
INSECT FRIENDS AND ENEMIES 129 
 
 The weevils begin to come out and hunt for food in 
 
 i*"it^t)k^^ 
 
 Fig. 43. — Different Life Sizes of Adult Weevils 
 
 April, and often continue to come out until late in June. 
 The cotton plant furnishes their only food. Those that 
 emerge early feed on the leaves and buds of the young 
 plant until 
 squares begin 
 to form. After 
 this they live 
 by puncturing 
 the squares with 
 their long bills 
 and sucking the 
 juice. The fe- 
 males also punc- 
 ture the squares 
 in order to de- 
 posit their eggs. 
 little grub (Fig 
 
 Fi( 
 
 44. — Pi \< TTTRBD Square containing 
 Young Weevils 
 
 The egg soon hatches and produces a 
 44), which eats the inside of the little 
 square and causes it to fall to the ground. In about 
 eighteen or twenty days from the time the egg is laid 
 in the square, the new weevil is old enough to begin 
 laying eggs. This gives a new generation of weevils at 
 least every twenty days. As each female weevil lays 
 
130 ELEMENTS OF A(;R1CLTLTUKE 
 
 over a hundred eggs during her life, one pair of weevils 
 will produce a vast number in one season. 
 
 Starving the Weevils. — It has been proved by Professor 
 F. W. Malley of the Texas Experiment Station, and Dr. 
 W. D. Hunter and others of the Department of Agricul- 
 ture at Washington, that if cotton stalks are destroyed 
 early in the fall, the w^eevils will have to endure a longer 
 fasting period, and fewer of them will live till spring. It 
 may be said that if all the cotton stalks were destroyed, 
 so as to deprive the weevils of their food in October, 
 probably only one per cent would live till cotton came 
 up the following spring. If deprived of food in Novem- 
 ber, perhaps three per cent would live through the winter, 
 but if deprived of food in December, five or six per cent 
 would live till spring. The cotton should, therefore, be 
 picked as soon as possible, and all the stalks should be 
 cut and burned. Perhaps an easier plan for many would 
 be to turn cattle into the fields. Cattle will soon strip the 
 stalks of all squares, bolls, and leaves, leaving the weevil 
 nothing to feed on. This plan not only furnishes excel- 
 lent grazing for cattle, but it preserves the fertility of the 
 land much better than the burning of the stalks does. 
 Unfortunately few people will burn their cotton stalks or 
 allow their cattle to graze on them. As weevils are 
 known to go as far as twelve miles from where they 
 grew to maturity, the practice of burning or grazing the 
 cotton stalks would have to be somewhat general in order 
 to accomplish results that would be at all satisfactory. 
 
 Selecting early kinds of cotton, planting early, fertiliz- 
 ing liberally on poor lands, and working the crop well are 
 
INSECT FRIEXDS AND ENEMIES 131 
 
 the means that are chiefly relied on for raising cotton in 
 spite of the weevil. By means of these methods, a suffi- 
 cient number of bolls matures to make a fairly good crop 
 before the weevils get numerous enough late in July and 
 early in August to destroy all the squares and young bolls. 
 Sometimes a full crop is made in spite of the weevil and 
 other pests. As the average cotton stalk ordinarily makes 
 six times as many squares as mature into bolls, most of 
 the squares may be destroyed and still a sufficient number 
 may be left to make as many bolls as the stalk can bring 
 to maturity. 
 
 Fall Plowing. — Some people recommend deep, fall 
 plowing as a means of planting early, and of getting the 
 young cotton to grow rapidly. This is certainly the cor- 
 rect practice for the dry West Texas country, where the 
 weevil first appeared, but clay and bottom lands farther 
 east have too much water in early spring to permit very 
 early planting and the most rapid growth of the young 
 cotton. If plowed deep in the fall, this difficulty is only 
 increased. If practicable, such lands should be handled 
 in a way to make them get rid of water as rapidly as 
 possible until about planting time. At that time there 
 will be an abundance, if not an excess, and if the land 
 is worked from then on so as to conserve moisture, every 
 requirement of good agricultural practice will be met. 
 
 Destroying the Weevils. — Some people believe in dusting 
 cotton with Paris green at the time the weevils are eat- 
 ing the young leaves before the squares appear. Most 
 observers, while agreeing that some weevils are killed, do 
 not agree that this is a pr.. Stable practice. In the early 
 
13^ 
 
 ELEMENTS OF AGHICULTURE 
 
 !.Of»p- I 
 
 
 *.-i;*-^^.4*i.?.-«. 
 
 ."«5..o:>,-'^' - >; 
 
 mc«i* 
 
 
 m^ '- 'im ' r 
 
 Fig. 45. — Early and Late Cotton in Boll Weevil District 
 
INSECT FRIENDS AND EXEMIES 133 
 
 part of the season, when a few squares fall on account of 
 being punctured by weevils, it is generally agreed that 
 it is profitable to pick tliese squares up and burn them, 
 since each one contains a young weevil. One weevil de- 
 stroyed the first of June probably prevents tens of thou- 
 sands of offspring later in the season. This practice is 
 profitable to each farmer who adopts it, whether his 
 neighbor follows his example or not, because weevils 
 generally stay in the fields where they are hatched until 
 late in the season, wlien food becomes scarce. 
 
 Enemies of the Weevils. — Some farmers are raising tur- 
 keys and guinea fowls in large numbers not only for the 
 profit to be derived from the fowls, but for their service 
 in destroying weevils. These birds are said to lessen 
 appreciably the damage done by weevils. Very many 
 species of birds eat weevils, and as a general rule birds 
 should be protected. A little native black ant destroys a 
 great many weevils while they are in the larval stage in 
 the square. These ants are said to be multiplying in the 
 weevil districts, and to be greatly lessening the damage 
 done by weevils in some places. Weevils are also, to some 
 extent, subject to fungous diseases. 
 
 This pest is spreading rapidly into the wet districts, 
 but is not moving northwest in Texas, where the air is 
 dry and the heat is intense. Hot, dry weather dries out 
 the squares and kills the young. The indications are that 
 this pest will be more destructive as it moves east, on 
 account of abundance of moisture, the shade of the rank- 
 growing cotton, and the late maturing of the crop. 
 Unless the extra moisture also favors bird, insect, and 
 
134 ELEMENTS OF AGRICULTURE 
 
 funo-ous enemies of the weevil, it will be more destructive 
 east of the Mississippi River than it ever was in West 
 Texas. 
 
 One especial enemy of insects and friend of man is the 
 toad. He eats an unusual number of cut worms and 
 other pests. It would undoubtedly pay to have pools, 
 or tanks, of water about the farm and garden to encour- 
 age toads to multiply. There is little doubt but they 
 would catch a good many boll weevils. 
 
 See Appendix for descriptions and means of destroying 
 most insect pests. 
 
 QUESTIONS 
 
 What is the estimate of the damage done by the boll weevil in 
 1907? Are all insects harmful? Name some beneficial insects and 
 tell what great service insects render to plants. How can we estab- 
 lish a balance of power among insect enemies ? Give an example of 
 such use of insects. Define a real insect. What two classes of in- 
 sects are there ? How are the two classes killed ? How are cabbage 
 worms killed sometimes? How are corn and pea weevils killed? 
 What cattle diseases are carried by insects ? What human diseases 
 are known to be carried by insects and what insects carry the germs 
 in each disease? Show on a map what sections the cotton boll 
 weevil now infests. What food mut:*" the weevil have? What goes 
 wdth them through winter? What do they eat when they first come 
 out in spring? How long does it take for a generation of weevils 
 fully to mature? How many eggs does each female lay and how 
 long will it take one pair to produce a million offspring? Of what 
 advantage is it to cut and burn or graze the cotton field in October 
 as compared with doing the same in December ? What methods are 
 chiefly relied on to make a crop where there are weevils? How about 
 fall plowing to help early planting and rapid growth of plants? 
 What kind of cotton should be selected? What disadvantage will 
 the cotton raisers in the more rainy districts have in fighting the 
 weevil ? 
 
CHAPTER XX 
 COTTON 
 
 History and Statistics. — The great crop of the South- 
 ern States is cotton, and it is one of the great crops of the 
 world. The United States raises something like four- 
 fifths of the world's commercial supply of this staple. 
 The East Indies produce something over 2,000,000 bales- 
 of cotton, but it is inferior. Egypt raises a good quan- 
 tity of fine quality, and China raises a considerable 
 amount, but its quality is inferior. The Chinese often 
 sow their cotton broadcast, and crawl through the patches- 
 and pick out the weeds. Russia raises a few hundred 
 thousand bales in the southern part of her Asiatic pos- 
 sessions. Small patches of cotton may be seen in Japan 
 also, but it seldom grows over a foot in height. 
 
 In all tropical countries small quantities of cotton are 
 grown from perennial plants that often grow wild and 
 become almost as large as fruit trees. The tropics were 
 the original home of the cotton plant, but the temperate 
 zones grow it much better. 
 
 Our forefathers in America commenced to grow cotton 
 perhaps two hundred and fifty years ago, but it is not 
 definitely known whether the first seed planted came from 
 Europe and Asia, or from Mexico and South America. 
 It is supposed that seed came from all these countries. 
 
 135 
 
136 
 
 ELEMP]NTS OF AGRICULTURE 
 
 In round numbers, the United States is now planting 
 35,000,000 acres in cotton and producing 13,000,000 bales 
 weighing 500 pounds each. The crop is worth in all about 
 
 Fig. 46. — Good Typk of Cotton Plant 
 
 $700,000,000, not including the seed, which are worth 
 over 1100,000,000. 
 
 Where Cotton Grows. — Cotton is grown as far north as 
 SI degrees on our lowlands and 34 degrees on the lands 
 of West Texas having an elevation of three thousand 
 feet. It was at one time believed that cotton needed a 
 
COTTON 
 
 137 
 
 moist atmosphere, but its successful growth in West 
 Texas proves that it is adapted to a very dry climate 
 also. It is grown in the entire cotton belt on every 
 
 Fig. 47. — Poor Type of Cotton Plant 
 
 kind of land that is even partially well drained and cul- 
 tivated. There is no other crop that will stand the same 
 abuse in the way of poor preparation, poor culture, poor 
 di-ainage, w^eeds, grass, and other unfavorable conditions, 
 and make as good returns. After neglect that would 
 ruin corn or other crops, cotton has often done better 
 
138 
 
 ELEMENTS OF AGRICULTURE 
 
 than when carefully cultivated. Since the coming of the 
 boll weevil, good rapid cultivation has become necessary. 
 How Planted. — Cotton is generally planted on a ridge, 
 but in the dry areas, and in the sandy lands in the eastern 
 sections, it is sometimes planted on a level. The farmers 
 in each community know when it is safe to plant, and 
 
 Fig. 48. 
 
 Rolling Fresh Cotton Bed to firm the Soil 
 FOR Planting 
 
 whether it is necessary to plant on a ridge. The 
 pupils should learn the details of the cultivation and 
 handling of cotton from their fathers and neighbors. 
 Early planting generally yields better than late planting, 
 but this is not always so. Early planting is very impor- 
 tant where there are boll weevils. Late plantings on any 
 rich bottom land are very likely to grow too much stalk 
 and leaf to make a good 3'ield. 
 
 Preparation of Land. — In order to be certain of getting 
 a stand of cotton, the land should be prepared some time 
 
COTTON 
 
 139 
 
 before planting, so that it may settle and become com- 
 pact. A compact, firm condition enables enough water 
 to be drawn up from the subsoil to sprout the seed even 
 in dry weather. A good plan is to list cotton land in the 
 fall, winter, or early spiing, with two furrows of a turn 
 plow. Then, just before planting, the middles should be 
 
 Fig. 49. — Mississippi Cotton Field 
 
 broken out. This gives a firm soil to plant in, and a 
 fresh, clean bed for the young plants. Planting time 
 usually marks the beginning of dry weather, when the 
 planter should begin to work to save moisture. The 
 loose, fresh bed will help to save moisture. If prepared 
 just before planting, without previous listing, the land 
 should be rolled, dragged, or harrowed, so as to make it 
 firm. Often when the weather is dry, cotton seed lie in 
 the ground from April to June on account of being 
 
140 ELEMEXT8 OP^ AGRICULTURE 
 
 planted on a loose, fresh bed. Did you ever notice in 
 a very dry season that the cotton or wheat came up well 
 near a turn row where the teams had packed tlie ground, 
 Avhen it did not come up over the rest of the field ? 
 
 Depth of Preparation. — As cotton has a long period of 
 growth, it does not need to have the land so thoroughly 
 prepared as some crops do. It is often planted on rough, 
 clodd}^ land, and if the land is put into good condition 
 during the first working, it will make a good crop. It 
 does not need deep preparation of soil. Some of the best 
 cotton raisers in the country sprinkle the fertilizer in the 
 old cotton or corn middle, and make the bed over an 
 unbroken center. Other successful planters make beds 
 with a buster, as explained heretofore. These methods 
 are cheap ; they allow tlie work to be pushed along, and 
 make about as good seed beds as the more expensive 
 methods. It is often the case, as explained before, that 
 clay or bottom land in the rainy belt, when deeply pre- 
 pared in the fall, winter, or earl}^ spring, holds so much 
 water that it cannot be planted early, and when it is 
 planted, remains so cold that the crop does not grow 
 rapidly. Cotton also adapts itself well to different modes 
 of cultivation. Where coco, or nutgrass, is bad in Mis- 
 sissippi and Louisiana, the farmers fight this grass by 
 throwing dirt in the rows with turn plows and covering 
 the grass. When laid by the cotton is often on a ridge 
 two feet high, but it makes just as good a crop apparently 
 as if cultivated on a level. 
 
 Different Methods for Different Sections. — It is a great 
 advantage, in many cases, to list the land in the fall or 
 
COTTON 141 
 
 winter, with two furrows, as has been explained, and let 
 it remain firm and compact until just before planting 
 time. This will allow the excess of moisture to evaporate, 
 and make the land warm enough for the crop to come up 
 and grow fast. This advice applies especially to land in 
 the eastern part of the cotton belt, where there is almost 
 always too much moisture in the early spring. To secure 
 the best results in the dry parts of the belt, it is im- 
 perative that the land be prepared in the fall or early 
 winter, and be kept harrowed and in good tilth right up to 
 planting time in the spring. In fact, where the rainfall is 
 only about twenty inches a year, the land on which crops 
 are planted in rows should never be allowed to get out of 
 tilth. Cultivators or broad sweeps should be run at in- 
 tervals until corn-gathering or cotton-picking time, and 
 then the same implement should follow the gatherers or 
 pickers in order to save moisture for the next crop. 
 
 In the more rainy sections this same thing should be 
 done if crops of any kind are to be planted on the land in 
 fall or early winter, for in the rainy sections of the cotton 
 belt the conditions for fall seeding are about as unfavor- 
 able as they are in the semiarid sections. If, however, 
 the land in the humid sections is not to be planted 
 again till the following spring, it needs no such treat- 
 ment, for it almost always gets too much water before 
 spring. 
 
 Professor R. L. Bennet, Cotton Expert of the Depart- 
 ment of Agriculture, after studying cotton at the Texas 
 Agricultural College for four years, came to definite con- 
 clusions as to the method of securing an early, prolific 
 
14: 
 
 ELEMENTS OF ACiRTCL'ETURE 
 
 cotton which will make a good crop before the weevils 
 get numerous enough in summer to do serious damage. 
 
 He found that certain types of big boll cotton are easy 
 to pick, and make bolls just as early as small boll cotton. 
 
 Although the big bolls 
 do not dry and open so 
 quickly as the small bolls, 
 yet they become large 
 enough to be secure from 
 the attack of the weevils 
 just as early in the season 
 as the small bolls do. 
 These types have an ad- 
 ditional advantage in that 
 when the cotton opens, it 
 is not so badly blown out 
 by storms. 
 
 By selecting certain 
 types of stalks from fields 
 of good kinds of cotton 
 grown in each neighbor- 
 hood, and growing the 
 seed from the single 
 stalks separately, the farmer can get kinds of cotton far 
 superior to that produced from most seed that are offered 
 for sale at high prices. Usually the seed from a single 
 stalk will yield very true to the parent plant. Efforts 
 to improve the seed gradually by high fertilizing every 
 year have not proved satisfactory. If the right type is 
 selected and this type breeds true, the improvement is 
 
 Fig. 50. — Round Cotton Bales 
 
COTTON 143 
 
 made all at once. The seed from one stalk can be multi- 
 plied fast enough to plant a good-sized field the third year. 
 
 Cotton plants have nodes or joints. Short-jointed stalks 
 that grow fast and fruit rapidly should be selected. 
 Mr. Bennett makes the following suggestions : — 
 
 1st. The stalks selected should have fruit limbs begin- 
 ning not higher than the fifth or sixth joint above the 
 lowest, or seed-leaf joint. 
 
 2d. The wood limbs, or primary limbs (large branches 
 which themselves put out fruit limbs) should be low, and 
 preferably not over four in number. 
 
 3d. Joints on primary and on fruit limbs should be 
 short — from one to three inches in length. 
 
 4th. Fruit limbs should grow at the successive joints 
 of the main stem and the wood limbs. 
 
 5tli. All the fruit limbs should continue to grow and 
 fruit until the plant is matured. 
 
 6th. The widest leaves should not be over six inches 
 across. Wide leaves keep out the sun, and the weevil 
 thrives in the shade. Figure 46 shows the type of cotton 
 to select. Figure 47 shows the type not to select. After 
 Mr. Bennett gets the right type of seed, he plants early, 
 fertilizes highly, and works the crop rapidly to make it 
 grow and fruit as fast as possible. He believes in pick- 
 ing up the fallen squares in the early part of the season, 
 and in pasturing the fields early in the fall or destroying 
 the stalks, or doing both, as a means of making the 
 weevils less numerous the following year. 
 
 Cost of Cultivation. — Cotton is much easier to cultivate 
 in the western part of the belt than in the eastern. In 
 
144 
 
 ELEMENTS OF AGRICULTURE 
 
 f^^ 
 
 the western part, one hoeing or chopping, costing about 
 fifty cents an acre, is required. In the eastern part, from 
 two to three hoeings are required, costing perhaps on an 
 average of |2.50 an acre. The cultivators should be run 
 as often in the west to save moisture as they are in the 
 
 east to kill grass and weeds. 
 Cultivation is always easier 
 and cheaper anywhere if 
 the crop can be worked 
 often and kept from getting 
 foul with weeds. 
 
 Thickness of Planting.— 
 All the experiment stations 
 in the South agree that the 
 yield and earliness of a crop 
 of cotton are increased if 
 the plants are rather thick 
 in the rows — from twelve 
 to twenty-four inches aj)art 
 when the rows are from 
 three to four feet wide, the 
 widest spaces in each case 
 being on the richest lands. 
 Length of Staple. — Short- 
 staple cottons, having a lint about one inch long or less, 
 make up the great bulk of the crop. In some cases, 
 however, on rich bottom lands and highly manured 
 uplands, cotton having a staple one and a half inches 
 long or more is raised. These long-staple cottons bring 
 perhaps fifty per cent more than the short-staple cottons. 
 
 Fig. 5L 
 
 Long and Short Staple 
 Cotton 
 
COTTON 
 
 145 
 
 The black-seeded sea-island cotton, grown near the coast 
 and on some islands of Sonth Carolina and Georgia, is 
 the finest cotton grown in the world. It is worth three 
 times as mucli as short-staple cotton. Short-staple cottons, 
 however, generally yield more and tnrn out a larger pro- 
 portion of lint to the seed than 
 the long-staple kinds. 
 
 Ginning and Baling. — Cotton 
 has nearly always been poorly 
 handled. It is often carried to 
 the gin when moist. Tlie gin runs 
 too fast and cuts the lint badly 
 even when the cotton is dry. 
 Each bale carries to Europe or to 
 the domestic mill thirty pounds of 
 bagging and ties that are thrown 
 away, and yet it is poorly wrapped. 
 It is cut and torn in taking numer- 
 ous large samples from the bales. 
 It lies out in the rain and suffers 
 damage. It goes to the compress for repacking, and 
 finally goes to the ship for export so poorly packed 
 that it has to be screw-pressed into the ship at heavy 
 expense. For all these expenses and losses the farmer 
 actually pays in the smaller price he gets for his cotton 
 at home. If all these losses, or nearly all of them, could 
 be avoided, cotton would perliaps bring the farmer a cent 
 a pound more than it does under the present conditions. 
 
 Kind of Bale. — If the cotton could be packed densely in 
 a round bale that would save so much sampling and require 
 
 Fig. 52. — American Bale 
 OF Cotton as it gets 
 TO Europe 
 
146 elp:ments of agriculture 
 
 l)ut a few yards of cheap burlap covering, the saving to 
 tlie farmer would amount to a great deal. Heretofore 
 this method of baling has been objected to, because the 
 owners of the presses would not sell them, and appeared 
 to be seeking to create a monopol}' of baling cotton. As 
 soon as patents expire and ginners can buy these presses, 
 it would seem to offer a means of effecting great saving 
 to tlie cotton farmers. 
 
 Judging Cotton. — All farmers and farmer boys and 
 girls should learn how to judge cotton. They should get 
 some samples of known classes and practice judging. 
 While cotton is in the seed, a fairly correct judgment of 
 its quality can be formed. Pull the seed apart and 
 straighten out the lint, as in Figure 47, and compare the 
 lengths. You will find the longer staples will make much 
 larger tufts. Then if the cotton is quite free from trash, 
 dirt, and stain, and is ginned carefully, you will know 
 that it sliould bring a large premium over ordinary kinds. 
 If a farmer sells a steer, he knows whether it is fat ; if he 
 sells butter, he knows whether it is of good quality ; yet 
 he allows the cotton bu3^er to be the sole judge of the 
 quality of his cotton. 
 
 The Seed. — Cotton seed, until a few years ago, were for 
 the most part wasted. Mississippi has an old law on her 
 statute books prohibiting ginners from throwing seed into 
 creeks. Seed are now known to be very valuable as a 
 fertilizer and as a feeding stuff. They yield oil that is 
 refined and made into compound lard, butter, and salad 
 oils; the cake and meal are used for fertilizers and cattle 
 feed ; the hulls have proved to be a good rough feed for 
 
COTTON 147 
 
 cattle; and the short lint, called linters, got by running 
 the seed through the gin before they are hulled, has 
 various uses. A ton of seed yields about 40 gallons of oil, 
 800 pounds of meal, 800 pounds of hulls, and 40 pounds 
 of linters. By studying market prices of these products, 
 remembering that the oil mill should have four or five 
 dollars a ton of seed for expenses and profits, one can 
 always form a correct estimate as to what is a fair price 
 for seed. 
 
 Large numbers of cattle <t,re fattened on cotton-seed 
 hulls and meal mixed, but the most of the meal is ex- 
 ported to Europe. The oil and linters are also largely 
 exported. 
 
 Feeding Seed and Meal. — People having cattle to feed 
 should not sell seed for less than two-thirds the price of 
 cotton-seed meal. The worth of seed for feed is fully 
 two-thirds that of meal, ton for ton, but somewhat more 
 care may be necessary in order to get the best results from 
 feeding seed Avhole. 
 
 QUESTIONS 
 
 Througli what degrees of latitude does cotton flourish in the United 
 States? At what elevation above sea level is it being grown? Is the 
 old idea that cotton needed a moist atmosphere correct? Is cotton a 
 very hardy crop? Are early or late plantings of cotton most likely to 
 yield good crops ? Would you recommend early or late planting where 
 the boll weevil is prevalent? What is likely to happen if cotton is 
 planted late on rich bottom land ? Explain how land may be listed 
 in the fall or winter for cotton, so that the beds may be finished just 
 before planting time. Give the advantages of this plan. If cotton 
 mast be planted on fresh beds, what advantage would it be to roll the 
 beds or drag something heavy over them ? Why is it that cotton will 
 sometimes come up near a turn row when it does not over the rest of 
 
148 ELEMENTS OF AGRICULTURE 
 
 the field ? Does cotton require as thorough preparation of land as 
 some other crops? Does it need the soil deeply prepared? Will it 
 make a good crop if the bed is made over an unbroken center? Tn 
 the humid sections, would you plow land to make it hold more water 
 in winter, or would you handle it in a way to make it get rid of some 
 of the water ? In the wet districts, about w4iat time in the spring 
 would you commence to work your land to make it hold its water? 
 Why would you harrow wheat and oats in the seraiarid sections while 
 they are growing? Why would it pay to run cultivators through 
 your cotton, kafir corn, and other crops in dry sections until the crops 
 are gathered ? Why is not cotton with bigbolls as early-opening as small- 
 boll cotton ? Why is big-boll cotton to be preferred to small-boll cotton ? 
 Describe the kinds of cotton that have proved earliest and that proved 
 to make the best crops where boll weevils are bad. Where is cultiva- 
 tion of cotton cheapest, in the dry or wet section? Will cotton make 
 more growing close together or far apart in the rows? Will cotton 
 make earlier if grown close in the drill? Will it make a larger 
 yield? What is the finest cotton known ? Tell some of the ways in 
 which cotton is badly handled. Tf handled in a better way, would it 
 bring the farmer a better price? Why should all farmers know how 
 to class their cotton? How can you tell something of the value of 
 your cotton before it is ginned ? What are some of the uses of cotton- 
 seed oil? What products do the oil mills get from a ton of cotton 
 seed? Can you tell from these products about what the farnier 
 ought to get for his seed ? What are the relative values of cotton 
 seed and cotton-seed meal for feeding cattle ? 
 
 Experiment. — Get a cotton buyer to give you samples of middling 
 cotton, low middling, good middling, and middling fair, with the 
 differences in value of them. Practice sampling and judging for 
 yourself. Do this at school. 
 
CHAPTER XXI 
 
 CORN 
 
 Indian Corn, so called because it was first found among 
 the American Indians, is the greatest single crop grown 
 in any one country on earth. The annual value of the 
 crop grown in the United States is about one and 
 a quarter billion dollars. Texas stands about fifth or 
 sixth among the states in corn production. Something 
 like a hundred different commercial products are manu- 
 factured from the corn plant, such as oil, rubber substi- 
 tutes, starch, sirup, alcohol, packing for battleships (the 
 pith of the stalk is used for this purpose), Missouri cob 
 pipes, and many other things. 
 
 Origin. — This giant grass had its origin in tropical 
 America, but like many other plants of like origin, 
 it makes its best gi-owth toward the northern limit of 
 the area of its production. It grows all the way from 
 Canada to Cape Horn, and has spread to the warm 
 l)arts of Europe and the Far East, including Australia 
 and Australasia. 
 
 Kinds of Corn. — AVe have dent, flint, sweet, and pop 
 corns. The dent corn is of especial interest in most of 
 the corn belt as a field crop. Flint corn matures quickly, 
 and is grown in the extreme northern part of the belt. 
 It does not usually make large yields. Dent corn is 
 
 140 
 
150 ELEMENTS OF AGllICULTURE 
 
 shriveled at the hirge end of the grain. Of the yellow 
 and white corns of the dent variety, the white kinds have 
 usually yielded better in all the southern half of the corn 
 belt, and they are somewhat better for making bread. 
 
 Soil and Fertilizers. — Corn is grown on all kinds of 
 land, but it does not flourish with as poor soil, drainage, 
 culture, etc., as cotton does. Corn does its very best on 
 rich, well-drained l)ottom lands, that have plenty of humus. 
 On thin uplands corn needs not only better fertilizing than 
 cotton, but also a somewhat larger proportion of nitrogen 
 in the fertilizer. Therefore all fertilizer mixtures for 
 corn should have a little less acid phosphate and a little 
 more cotton-seed meal, nitrate of soda, or cotton seed than 
 those which are intended for cotton. 
 
 Preparation of Land. — It lias commonly been supposed 
 that corn land needs deeper preparation than cotton land, 
 but evidence from Southern experiment stations does not 
 indicate this. The land needs thorough, but not neces- 
 sarily deep, prepai'ation — perhaps five inches deep. Corn 
 can be planted earlier than cotton — perhaps two or three 
 weeks. 
 
 Selecting Seed. — The same general principles for se- 
 lecting seed as have been recommended for cotton apply 
 to corn ; but as corn is very likely to cross, the desirable 
 shoots had better be covered and pollinated artificially. 
 For sections having plenty of rain a larger stalk and 
 later-maturing type would make a better yield. Farther 
 west, where moisture is less abundant, a smaller stalk 
 and quicker maturity would be better. It matters little 
 whether corn for seed tends to bear one ear or more 
 
CORN 
 
 151 
 
 than one. Corn yields best when planted so thick as to 
 average about one ear to each stalk. Testing out the best 
 selections from individual stalks in one's own neighbor- 
 hood, or on one's own farm, is better than ordering from 
 some distant 
 state seed corn 
 which is said 
 to have a fine 
 pedigree and 
 high yielding 
 record. Farm- 
 ers should 
 order at most 
 only s m all 
 quantities of 
 seed from a dis- 
 tance, and care- 
 fully test them 
 out for adapt- 
 ability to their 
 own localities 
 and conditions. 
 Corn generally 
 adapts itself to 
 a locality, and 
 yields better than the same kind brought from a distance. 
 Yields and Expenses. — In much of the South the aver- 
 age corn yield is low — being from ten to twelve bushels 
 to the acre. In some of the Northern States the average 
 yield runs up to nearly forty bushels. In both North and 
 
 Fkj. 53. — Corn and Peas 
 
152 ELEMENTS OF AGRICULTURE 
 
 Soutli from seventy-five to eighty bushels to the acre are 
 not uncommon. Suppose you find out how mucli work is 
 done on each acre of corn on your father's farm, including 
 2:)reparation of land, planting, plowing, hoeing, gathering 
 the crop, etc. ; then by counting a day's work of a man at 
 a dollar and the work of a horse or mule at fifty cents, and 
 estimating the value of land rent, seed, and fertilizer, find 
 out what is the expense of raising an acre of corn. Then 
 estimate the yield and give it the value corn has in the 
 neighborhood, and see how much is made or lost. You 
 jnight do the same with cotton and other crops. 
 
 Saving Fodder. — It used to be a very common practice 
 in the South to strip the leaves from the corn when it got 
 nearly dry, and to cure these for fodder. This makes a 
 fine feed, but a man can strip so little of it in a day that 
 people are abandoning this plan of providing rough feed. 
 The Texas Experiment Station many years ago tested the 
 plan of saving the fodder by cutting off the tops of the 
 corn. In proportion to the amount of feed saved, this 
 plan proved much cheaper than stripping the blades from 
 the stalks. The plan generally followed in the main part 
 of the corn belt is to cut down the whole stalks and put 
 them up in shocks until tliey are cured, and then to shuck, 
 or husk out, the ears of corn. What is left is called stover, 
 and is fed to cattle through the winter. This stover is 
 often torn up into fine pieces in a shredding machine, and 
 the product is called shredded corn stover. Shredding is 
 expensive, and the feed is not greatly improved by the 
 process, for the shredded stover is very hard to keep. In 
 the South, corn stover is more subject to injury than in 
 
CORN 153 
 
 the North, because tlie stalks of the corn are hirger and 
 liold more moisture. This process is not growing in 
 XK)pularity in the South. Even in the corn states perhaps 
 not one farjner in a hundred shreds his stalks. It is prob- 
 ably better to break the corn from the stalk in the old 
 way, and then allow the stock to graze on the fields. One 
 Northwestern experiment station has found this the more 
 profitable plan. 
 
 Another chapter will tell how to keep Aveevils from in- 
 juring corn. 
 
 QUESTIONS 
 
 Where was Indian corn first found? How does this crop compare 
 in importance with other crops of the world? Name some of the 
 products manufactured from corn. Where did corn originate, dnd 
 where does it grow best? What different kinds of corn iiave we? 
 A\'hat is the best kind of corn in the South? Does corn grow well on 
 all sorts of land? Does soil for corn need very deep preparation? 
 Are different varieties of corn likely to cross? What could be done 
 to prevent crossing? For sections having plenty of rain, would you 
 select late corn or early corn ? Would it be safe to order a large 
 quantity of seed corn from a great distance ? How large a yield of 
 corn can be got under good conditions? How could you estimate the 
 profits or losses on an acre of corn ? Is pulling fodder a profitable 
 practice? What is corn stover? What is shredded stover? Is it 
 profitable to save and shred corn stover in the South ? 
 
 Experiment. — If you live in a section where corn is grown for 
 market, get samples of market grades of corn from a buyer and learn 
 to judge these grades and value them. This is a suitable school ex- 
 e)'cise. 
 
CHAPTER XXII 
 
 WHEAT AND OATS 
 
 Wheat is one of the oldest grain crops. It is particu- 
 larly adapted to northern latitudes and elevated regions. 
 It is a cold- weather plant, though it may grow well in 
 sections where the weather gets very warm about the 
 Wheat thrives where the weather is too 
 cool or the rain- 
 fall is too little 
 for corn. It also 
 does well over 
 most of the corn 
 belt of the United 
 States. 
 
 It is hardly 
 advisable to 
 plant wheat in 
 South Texas or 
 in any part of 
 tlie Gulf States 
 east of Texas 
 unless it be on the highest lands of Alabama. It is liable 
 to rust, and the crops will usually not pay. 
 
 Wheat has a decided preference for clay soils. It does 
 not do well in a deep, loose seed bed. Preparatory plow- 
 
 154 
 
 Fig. 54. 
 
 Wheat planted in Loose Soil and 
 IN Soil Compacted 
 
AVHEAT AND OATS 155 
 
 ing may be shallow, and the soil should be firm and com- 
 pact. You perhaps remember the story of the English 
 peasant farmer whose wheat had been run over, and 
 trampled upon by the hounds of a nobleman who was 
 hunting on the peasant's farm. The peasant demanded 
 and received a certain sum of money as damages, but 
 afterwards returned the money, because he found the 
 
 Fig. 55. — AVheat Field on the Plains 
 
 wheat most trampled by the hounds was the best. Pas- 
 turing wheat moderately in fall and early winter is gen- 
 erally found beneficial, if done when the land is not too 
 wet. Pasturing is also good for oats, barley, and rye. 
 
 Fertilizers. — Wheat grown on the same grade of land 
 as corn needs a larger proportion of nitrogen in its fertili- 
 zers than does corn, because it grows in spring and ripens 
 in earl}^ summer before nitrogen compounds have begun to 
 form rapidly. But since wheat is mostly grown far 
 
150 KJ.EMENTS OF AGRICULTURE 
 
 enough north and west to insure soil having a hirger 
 supply of nitrogen than the thin Southern corn lands 
 have, a moderate [)roportion of nitrogen is likely to be 
 sufficient. 
 
 Wheat and Cotton. — Where cotton and wheat grow in 
 tlie same section, a crop of wlieat may very suitably follow 
 a cro2^ of cotton. If the cotton is well worked right up 
 to picking time, wheat may be sown after one of the pick- 
 ings and covered with a walking cultivator. The cotton 
 stalks may be cut and dragged off after the picking is 
 finished. This dragging will serve as a harrowing and 
 will help the wlieat crop. Often the cotton can all be 
 picked in time to sow wheat. In tliis case a good chopping 
 up with a disk harrow will put the land in fine shape 
 for the wheat drill. Where wlieat is to follow corn, 
 kafir, milo, or sorghum, the same treatment of land is 
 recommended ; at suitable intervals the land sliould be 
 w^orked with cultivators between the rows right up to 
 wheat-seeding time. This should be done as a means of 
 saving moisture. 
 
 Wheat after Small Grain. — If wheat is to follow small- 
 grain crops, the stubble of the latter should be disked and 
 plowed and re-disked from time to time till seeding time 
 again, in order to save moisture for the new crop in the 
 fall. In the dry sections of the West this would be safer 
 than to risk a pea crop between the two grain crops, 
 because a large pea crop pumps out an immense quantity 
 of water. If the pea crop is tried, it should be planted in 
 rows and kept well cultivated till it is cut. The land 
 should then be well disked and seeded. If the pea hay is 
 
WHEAT AND OATS * loT 
 
 particularly desirable, it might pay to grow it, even if it 
 caused a failure in the wheat crop. 
 
 In the southern part of its territory wheat is nearly 
 always seeded in the fall. Farther west, where the win- 
 ters and springs are dry, wheat fields should be harrowed 
 from time to time until as late as April, or as long as it 
 can be done without hurting the plants. This treatment 
 saves moisture, and the moisture helps to prepare food in 
 the soil for the crop. H. W. Campbell, in his dry -farming 
 operations, drills his wheat in twenty-inch rows and cul- 
 tivates between the rows with a cultivator that works 
 several rows at a time. 
 
 The Green Bug. — Proper working of the land to save 
 plenty of moisture for starting the wheat off vigorously, 
 and then pasturing in the fall, seems to be the best treatment 
 against the green bug that is sometimes so destructive. 
 This insect starts on the sickly yellow plants on poor spots 
 of land which have not been properly prepared. The cattle 
 and sheep while grazing eat up the bugs, and when the 
 young leaves grow out, dark and green, they are not so well 
 suited to the bugs' taste as yellow, unthrifty older leaves. 
 
 A Barrel of Flour. — It requires about 258 pounds of 
 wheat, or 4.3 bushels, to make a barrel of flour. This 
 amount of wheat should yield, according to Dr. H. W. 
 Wiley, Chemist of the United States Department of Agri- 
 culture, the following products : — 
 
 Patent Flour . . . 149.37 lbs. 
 
 Bakers' Flour . . . 29.13 lbs. 
 
 Low-grade Flour . . 17.50 lbs. 
 
 Total Flour . . . 196.00 lbs. or one barrel 
 
ir)8 ELEMENTS OF AGRICULTURE 
 
 Wheat Bran . . . 45.56 lbs. 
 
 Shorts . . . . 9.80 lbs. • 
 
 Screenings . . . 4.99 lbs. 
 
 Waste or loss . . . 2.35 lbs. 
 
 Total .... 258 lbs. or 4.3 bushels 
 
 By studying the market values of flour and the by- 
 products, bran, shorts, etc., farmers can tell pretty well 
 what price to demand of the millers for wheat, or what 
 amount of wheat to offer in exchange for flour, feed, etc. 
 
 Oats can be grown profitably farther south than wheat, 
 provided Texas red, rust-proof varieties, or other kinds 
 not so subject to rust, are chosen. The oat is a profit- 
 able crop clear to the seacoast in all the Gulf States. 
 Under a system of fertilizino- and rotation it is a g-ood 
 crop on the small farms throughout the large area of 
 sandy-loam lands of the Gulf and South Atlantic States. 
 On the lime and clay lands not artificially drained, the soil 
 is often too wet in winter and early spring for oats to do 
 well. In the South oats do much better when sown in 
 the fall, although fair crops are got from sowings made 
 in Fel)ruary. 
 
 Method of Planting. — To make sure that the fall sow- 
 ings will not be killed by frosts, tlie seed are often drilled 
 on freshly plowed land, the drill running northeast and 
 southwest and sinking well down in the plowed ground 
 and leaving little ridges between the drill rows. Tliese 
 ridges serve as wind-breaks, and prevent the little plants 
 from l)eing killed in the winter. 
 
 Fertilizers. — Oats need decidedly more nitrogen in their 
 fertilizer than cotton or corn needs, on account of maturing 
 
WHEAT AND 0AT8 159 
 
 before the weather gets warm enough to form nitrates in 
 the soil rapidly. Two or three hundred pounds of the 
 mixture recommended for okl lands, drilled with the seed, 
 and a top dressing of a hundred pounds of nitrate of 
 soda, harrowed in during March or April, can be counted 
 on to make a good crop. 
 
 Rotation. — Peas should ahnost always be grown on the 
 land after the oats are liarvested, not only on account of 
 tlieir value for hay, but because of their excellent effects 
 on tlie land. In one experiment on thin, sandy land at 
 the Alabama Experiment Station, previous crops of cow- 
 peas and velvet beans — part of each having been cut off 
 for hay and part turned under, vine and all — made 
 increases of the oat yield of about twenty-five bushels to 
 the acre over similar pieces of land, one of wdiicli had 
 grown sorghum and the other crab grass and hog weeds. 
 Oats, when not followed by a crop of peas, are very 
 exhaustive to the land ; but Avhen followed b}^ peas, the 
 land is greatly improved. 
 
 Oats and Vetch. — Hairy vetch seed are often mixed 
 with oats, and the two thrive togetlier and make a dense 
 growth. Tlie vetch is a legume, and improves the land. 
 Sometimes the vetcli climbs up on the oat stalks and in 
 stormy Aveather })ulls them down, causing considerable 
 loss. From tlie seed which it slieds on the ground the 
 vetch comes up volunteer in the fall. It makes a good 
 winter and early spring pasture, and a fine hay plant when 
 grown alone or with oats. 
 
 Winter Growth. — A crop of oats, or oats mixed with 
 vetch, followed by peas, makes a fine preparation of the 
 
160 
 
 ELEMENTS OF AGRICULTURE 
 
 land for cotton or any other crop the next spring. 
 Besides, the oat and vetch seed which are lost at harvest 
 time come up in the fall and clothe the land in green 
 during the winter. This is of great advantage in sections 
 Avhere the winter rains are heavy. The green crop takes 
 
 up the soluble 
 plant food and 
 prevents it from 
 being washed 
 away. It also 
 helps to evapo- 
 rate some of the 
 excess of water. 
 Then when the 
 land is plowed 
 in spring, tlie 
 plant food is 
 given to the 
 regular crop as 
 the green stuff 
 rots. Where 
 
 fall oats or fall 
 oats and vetch are grown in rotation with corn and cotton, 
 each field has a green cover crop two years out of three, 
 and this is of itself of great value. 
 
 The same general facts that have been given about 
 wheat and oats will apply to barley and rye. No attempt 
 has been made to give details about any of these crops. 
 Don't fail to learn more from your fathers and friends 
 about these crops, and about the tools, implements, and 
 
 Oats and V^etc h 
 
WHEAT AND OATS 161 
 
 macliines that are used for working and handling 
 them. 
 
 QUESTIONS 
 
 What kind of country and climate suits wheat ? Will corn do well in 
 all wheat countries? Which will grow farther south, wheat or corn? 
 Would you plant wheat in South Texas or Mississippi? How should 
 wheat land be plowed? Does it hurt wheat to graze it in the fall? 
 Does wheat need as niucli nitrogen as corn ? Do wheat and cotton do 
 well in the same section ? How could you sow wheat in cotton fields ? 
 In dry sections, how late would you work your crops? Why would 
 you harrow growing wheat in dry regions? If you intended to follow 
 small grain with wheat, in dry regions, would you plant a pea crop 
 after the small-grain crop? What time of the year is wheat sown 
 in the South? What treatment is suggested for the green bug? 
 How much wheat does it take to make a ban-el of flour? What 
 other things are got besides the flour? Which will grow profitably 
 farther south, oats or wheat? How are oats planted to keej) them 
 from winterkilling? Which needs the more nitrogen in the fertilizer, 
 oats or corn? Why is this so? What should be done with the oat 
 land after the oats are cut? Give an example of an increased yield 
 of oats on account of leguminous crops. What crop is often grown 
 Avith oats? Is the oat crop alone exhaustive to the land? Is 
 the oat crop, followed by peas, exhaustive to the land? Of what 
 advantage is a green crop to land in winter? In liumid sections, 
 what effect will the green crop have on the moisture? Would a 
 winter crop be of advantage in dry sections? 
 
 Experiment. — Study market grades of wheat in the way suggested 
 for corn and cotton. Try growing some wheat or oats in drills on the 
 farm at home and cultivating between the rows. See if you can 
 make a much larger crop and at the same time not plant over half as 
 much seed. Try nitrate of soda, one hundred pounds per acre, as a 
 top dressing in March or April on a small piece of oats or wheat. 
 
CHAPTER XXIII 
 
 RICE 
 
 Use and Varieties. — Rice is used as an article of food 
 b}' a great many of the earth's inhabitants. An enormous 
 amount of rice is grown and eaten by the hordes of people 
 in China, India, Japan, and Australasia. Rice is of many 
 colors, including black, red, and white. There are very 
 many varieties adapted to different conditions, from the 
 salty marsh lands near the sea, up to the mountain sum- 
 mits many thousand feet high. Some kinds assume a 
 dwarf habit, and come to maturity when two months old 
 in the dry, hot season. Other kinds are planted at the 
 beginning of the flood season in the great river bottoms of 
 the Far East, and grow and grow as the flood rises, till 
 they reach a height of twenty feet, and then mature 
 floating on the water, so that the harvesting has to be 
 done in boats. 
 
 Oriental Methods. — The people of Oriental countries 
 almost always plant their rice thick in seed beds. When 
 it is six weeks or two months old, they set it out in the 
 land where it is to grow, planting about 75,000 plants to 
 the acre. The land is first plowed and raked when muddy, 
 and all the grass is killed. The rice plants are set in this 
 mud, and rain water or irrigation water is made to cover 
 the land and keep down weeds and grass. In China, 
 
 162 
 
RICE 
 
 163 
 
 Japan, and India, transplanting is necessary in order to 
 give the people time to raise a crop of barley or vegeta- 
 bles, which they must grow in winter and spring, and yet 
 have their rice early enougli. In the Philippines, Java, 
 and Borneo, this plan is of advantage, because there are so 
 
 Fig. 57. — Rice Field in Louisiana 
 
 many coarse grasses, like Johnson grass or Avorse kinds, 
 that would grow faster than the young rice and choke it 
 out. By cleaning the land and setting plants when a foot 
 high and putting on water, the fields can be kept clean, 
 and good crops can be made. 
 
 In the Philippines, men, Avomen, and children — perhaps 
 a hundred or more — meet at a field that is to be set in rice. 
 They have a string band, and as the band plays, they set 
 rice in the mud, keeping time to the music, as if dancing. 
 
 Southern Methods. — Louisiana and Texas are growing 
 the bulk of the rice crop of tlie United States now ; South 
 Carolina, Georgia, and Arkansas grow a comparatively 
 
164 
 
 ELEMENTS OF AGRICULTURE 
 
 small amount. The level, stiff clay prairies of Texas, 
 Louisiana, and Arkansas are ideal for rice. They are level 
 enough for large areas to be surrounded by a small dike, 
 or levee, so as to hold the water over the land at an even 
 depth. Water plays an important part in the cultivation 
 of rice. P^nouorh water is turned on the field to drown the 
 
 FkJ. 58. — FiLIPIXOES PLOWING IN MUD PREPAUING 
 
 Land for Rice 
 
 weeds and grasses, but not enough to cover completely 
 the rice at any place in the field. The numerous streams 
 and bayous in such a flat country afford an abundant sup- 
 ply of water for the rice. Then })uniping from a deep 
 well in which the water comes up to or near the surface 
 will supply a good-sized plantation. Hundreds of these 
 wells are in use. 
 
 As this land holds water like a jug, no excessive amounts 
 
KICK 165 
 
 have to be supplied. When water is drawn off into the 
 drains about the time the crop is ripening, the land 
 readily dries and gets hard, so that harvesting machinery 
 can work on it as easily as on a wheat field. 
 
 Rice does not need rich land in order to produce a good 
 crop, but bigger yields are made on good land. 
 
 Preparing and Planting. — The land is plowed and har- 
 rowed when moderately moist, as for other crops. The 
 seed are put in witli a drill, as wheat and oats are planted. 
 Water is not turned on till the rice is six inches high. 
 Then lines are run with a leveling instrument, so as to 
 inclose the most land possible that does not vary in level 
 more than six inches, and these level lines are followed 
 by road graders or other implements to make the levees 
 or dikes, which are seldom more than eight inches high. 
 The land is plowed to a depth of about three inches only. 
 This depth of plowing makes just as good a crop as deeper 
 plowing, and it leaves the land harder for the harvesting 
 machinery to run over. Sometimes it is necessary to go 
 over the rice fields and pull out large Aveeds. In South 
 Carolina and Georgia rice is often planted in wide drills 
 and cultivated somewhat like corn. 
 
 Red Rice. — A prolific, early kind of rice, having red 
 grains or red streaks on the grains, has become a sort of 
 weed in the rice fields. The seed ripen early, and some 
 fall on the land and come up with the next crop. In this 
 Avay the variety multiplies so rapidly that the market value 
 of the whole crop is lessened, for in our markets there is 
 no sale for rice with red grains. In the Orient, however, 
 red rice is esteemed just as highly as white ; and the black. 
 
166 ELEMENTS OF AGRICULTURE 
 
 glutinous rice is thought to be the best of all. To get rid 
 of the red rice seed, the fields are usually allowed to lie idle 
 a year or two, and then fresh, clean seed are again planted. 
 
 Yields and Profits. — Rice in Louisiana and Texas aver- 
 ages about 1500 to 1600 pounds of rough, or uncleaned, 
 rice to the acre. This is about 35 bushels, or a little over 
 twice the average wheat yield in the United States. Some 
 plantations frequently produce twice this amount. The 
 Hawaiian Islands average 8000 pounds of rough rice to 
 the acre in two crops grown in one season, or something 
 over 175 bushels to the acre in one year. 
 
 As rough rice sells in the United States for about the 
 same price as wheat, it would seem to be a much more 
 profitable crop. It costs more, however, to grow rice. 
 Water must be pumped or paid for, if furnished by a 
 canal compan}^ dikes must be made and kept up, and the 
 water must be distributed regularly to the fields. Then 
 some weeding is required. Otherwise the metliods of 
 culture and harvesting of the two crops are much the 
 same. Rice allows a longer period of time for harvesting 
 than wheat, so that one man can save much more. By 
 planting kinds of rice which ripen early and kinds which 
 ripen late, the farmer may prolong his harvest season for 
 nearly three months. 
 
 Fertilization. — Rice is not extensively fertilized in this 
 country, but in the old w^orld it is fertilized in the same 
 way as other crops. Some very favorable results have 
 been reached by fertilizing in this country. Certainly pea 
 crops would give good results if planted during the years 
 the land is idle for the purpose of ridding it of red rice. 
 
RICE 167 
 
 Most planters, however, use their entire energies and re- 
 sources in growing a big rice crop on other land, leaving 
 themselves no time or means to grow and save a pea crop. 
 
 Time of Planting. — Rice may be planted from April 
 to June. Any rice field that can be well drained in winter 
 may be sown in the fall to hairy vetch or bur clover. 
 These crops will mature a good yield of green manure 
 by the last of April. If the land is well chopped up with 
 disks at this time, the rice may be drilled any time in May 
 or June, without other preparation. Some acid phosphate 
 may be used to advantage when the restorative crop is 
 sowed in the fall. Rice yields could no doubt be much 
 increased in this way ; and but for the red rice, big crops 
 could be grown every year. 
 
 Bur clover will mature seed by the 30th of April in 
 the Louisiana and Texas rice belt, and these seed might 
 stand the flooding and still come up volunteer in the fall, 
 as they do on dry land. 
 
 Manufactured Products. — A sack or barrel of rough 
 rice weighing 162 pounds contains approximately the fol- 
 lowing products: — 
 
 Clean rice 100.00 lbs. 
 
 Hulls (generally burned for power) . 32.10 lbs. 
 
 Rice bran 20.20 lbs. 
 
 Rice polish . . . . . 6.30 lbs. 
 
 Loss 3.40 lbs. 
 
 Total . . . . . . 162.00 lbs. 
 
 Some 60 pounds of the 100 pounds of the clean rice 
 should be best head rice, 30 pounds No, 2 (somewhat 
 
168 ELEMENTS OF AGRICULTURE 
 
 broken), and 10 pounds badly broken, called brewers' 
 rice. 
 
 Witli the help of these figures and the market value of 
 rice, bran, and polish, farmers can draw a fair conclusion 
 as to the market value of a sack of rice. Of course, the 
 better the quality of the rough rice, the more cleaned and 
 head rice there will be, and hence the higher the value it 
 will have. 
 
 QUESTIONS 
 
 Is rice a very important crop in the world? Where is it grown 
 largely? What different kinds of rice are grown ? How do Oriental 
 people plant rice ? Why do they plant it this way ? What states 
 grow most of the rice in the United States? What advantages do 
 these states have in rice-growing? What is water mostly needed 
 for in growing rice? Why do rice growers not plow land deep? 
 How do the rice planters keep the water covering the ground ? 
 What is red rice? What do the planters do to get rid of red rice? 
 How much rice is made on an acre in Texas and Louisiana? How 
 about the profits of rice as compared with wheat? How late may 
 rice be sown? What plant could be grown on the land to enrich 
 it in winter? Tell what products can be got from a sack of rice. 
 
 Experiment. — See if you can arrange to grow on the farm at 
 home a little piece of rice, planting by the Japanese method. Try 
 some bur clover on a piece of rice land and see how much increase 
 the rice makes next vear. 
 
CHAPTER XXIV 
 
 SUGAR CANE 
 
 Sugar cane is grown in all of the Gnlf and South At- 
 lantic States for sirup-making, and in parts of Louisiana 
 and Texas for sugar-making. About 300,000 tons of 
 sugar are made annually in 
 these two states. This is one 
 of the oldest industries in the 
 United States, having arisen to 
 commercial importance over a 
 liundred years ago, when people 
 Avere picking the seed out of 
 cotton with their fingers. 
 
 Cane in Tropics. — Sugarcane 
 is a tropical crop, and still does 
 best in the tropics. As it takes 
 twelve months to produce seed 
 and ripen, cane never gets fully 
 ripe in any country that has 
 frost. In two or three tropical 
 countries, where conditions are 
 very good, sugar cane grows for 
 
 seventeen or eighteen months before ripening. In most 
 parts of the tropics it ripens and seeds in the dry season 
 when just a year old. People in the tropics do not usually 
 
 169 
 
 Fig. 59. — Seeded Sugar Cane 
 
170 ELEMENTS OF AGRICULTURE 
 
 plant the seed. They phiiit a few joints of the tops of 
 the cane. When cane is really ripe, the eyes of the top 
 joints germinate and grow much better than the eyes on 
 the older parts of the stalk. 
 
 Saving Seed. — As the top joints of our cane are not 
 mature enough to grow well, we plant the whole stalk. 
 It is much better to dig up the stalks that are to be used 
 for seed, as the roots contain many of the best eyes, or 
 buds. The seed cane is cut or dug about tlie first frost 
 and piled in long piles and covered with dirt. It keeps 
 better if banked wlien well Avet by rain. It is planted 
 in deep furrows in early spring, sometimes in the fall, a 
 continuous line of cane being put down so that the top 
 of one stalk joins the root of another. In the sugar belt, 
 where cane is cut at the ground, sometimes as many as 
 three continuous lines of cane are put in the furrow. 
 
 Fertilizer for cane should contain a larger proportion 
 of nitrogen than fertilizer for cotton. Cane grows large, 
 and needs rich soil. In the Hawaiian Islands, where the 
 largest jdelds in the world are made, as much as two tons 
 to the acre of high-grade fertilizer are used, and the land 
 is given over 100 inches of water, pumped sometimes to a 
 perpendicular height of 600 feet. 
 
 In the United States cane needs a well-drained soil, 
 because poorly drained land is too cold for it. In the 
 tropics it may stand with its roots under water for weeks 
 without being seriously harmed. It needs plenty of rain 
 or irrigation. 
 
 Cultivation and Yields. — Cane is not difficult to culti- 
 vate. It has existed for ages almost as a wild plant in the 
 
SUGAR CANE 171 
 
 tropics, where, by doing battle for mastery of the soil with 
 other giants of the land, it grew strong and hardy. After 
 it gets a good start, it is kept clean mostly with turn plows 
 and disks, that heap dirt up to the stalks, and cover the 
 weeds and grass. This is kept up until the cane has- 
 grown tall enough and thick enough, by suckering, to 
 shade the ground and keep down other growth. In the 
 United States, cane when mature yields from 15 to 40 tons 
 to the acre ; in the tropics, the yields are usually much 
 larger. In Java, the average yield is 40 tons, and in the 
 dry parts of Hawaii, under irrigation, the average is 60 
 tons, and on some plantations the yield reaches as high 
 as 120 tons. 
 
 Rattoon Crops. — Cane will come up every year from the 
 stubble of the year before, but as the crops get smaller 
 and smaller, it does not often pay to grow more than one 
 or two of these " rattoon " crops. Cane should be cut 
 low, and then the stubble should be cut off with sharp 
 hoes under the surface of the ground. Otherwise, germs 
 will get into the roots and injure the buds that make the 
 stubble, or rattoon crop. 
 
 In the United States cane never gets very sweet until 
 frost scorches the leaves and checks the growth. At this 
 season the sirup makers and the sugar makers begin to 
 harvest the crop and manufacture sugar and sirup. 
 
 Best Land for Sirup. — Tlie light sandy loam lands pro- 
 duce decidedly the best-flavored and the best-colored table 
 sirup. The pine lands of the Southern States, when ferti- 
 lized, produce from 300 to 600 gallons of sirup to the acre. 
 This sirup is of such excellent quality that it readily sells 
 
172 
 
 ELEMENTS OF AGRICULTURE 
 
 for 50 cents a gallon. These highly profitable results are 
 reached in spite of the fact that the small horse-power 
 mills which are usually employed for crushing do not often 
 get over two-thirds of the juice that the regular sugar- 
 plantation mills would get from the same cane. 
 
 Making Sirup. — The apparatus for boiling the juice to 
 sirup consists of a kettle or evaporating pan set on a 
 rock or brick furnace. It has been 
 decided by the United States Depart- 
 ment of Agriculture that no chemical 
 whatever is needed to make first-class 
 sirup from sugar-cane juices. Careful 
 straining of the juice and skimming 
 while it is cooking, and then boiling 
 to a uniform density, is all that is 
 necessary. 
 
 Every sirup maker should have a 
 saccharimeter, a little floating instru- 
 ment that Avill measure the Aveight 
 of the sirup. The sirup should be 
 boiled down to about 75 degrees, Brix 
 saccharimeter. That is, it should still 
 contain about twenty-five per cent of water. If it is sealed 
 while hot in well-scalded jugs, bottles, or cans, it will keep 
 fresh for years. If the sirup is made rather thin, so that 
 the sugar will all, or nearly all, be held in solution, the 
 quality will be much better. If the sirup is to be kept 
 in barrels, it must be boiled thicker ; when this is done, 
 much of its sugar crystallizes and settles in the bottom of 
 the barrels. Sirup not sealed in sterilized vessels will 
 
 
 Fig. 60. — Way to use 
 A Saccharimeter 
 
SUGAK CANE 
 
 173 
 
 ^i^i?f;.f_^ 
 
 ferment when hot weather comes. If barreled sirup is 
 kept in cold storage, it will not grow the germs that cause 
 fermentation, and will keep well. 
 
 Making Sugar. — For making sugar, the juices of the 
 cane used to be boiled 
 to a thick sirup over 
 a direct fire, and the 
 sugar allowed to 
 crystallize out. The 
 molasses was then 
 sold as open-kettle 
 or sugar-house mo- 
 lasses. This plan is >i 
 occasionally followed 
 yet. But the great- 
 est forward step in 
 modern scientific 
 sugar-making was 
 the discovery that, 
 if cane juices can be 
 boiled at a low tem- 
 perature, more sugar 
 can be made. That 
 is, if the juices are 
 
 cooked over a fire, the high temperature used will invert a 
 large amount of the sugar, or put it in such a condition 
 that it will not crystallize. When the juices, or thin sirups, 
 are put in a large, air-tight vessel and the air pumped out, 
 the sirups will boil at a very low temperature, and less 
 sugar will be hiverted. The use of the vacuum-pan gives 
 
 Fig. ()1. — Cutting Sugar Cane, Louisiana 
 
174 ELEMENTS OF AGRICULTURE 
 
 large quantities of sugar and little molasses. The old 
 method gave less sugar and more molasses. 
 
 Products from a Ton of Cane. — A ton of Louisiana or 
 Texas cane, worked in a good factory and refinery, will 
 make about 140 pounds of sugar and some two or three 
 gallons of low-grade molasses, called " black strap^'' which 
 is used for feeding stock. Some centrifugal molasses of 
 better grade will also be obtained. A ton of tropical cane 
 will make from 200 to 250 pounds of sugar and probably 
 three gallons of low-grade molasses. 
 
 Impure Juices. — If cane is very green, it contains much 
 invert sugar, or non-cry stallizable sugar, called glucose. A 
 pound of glucose keeps more than another pound of real 
 sugar, called sucrose^ from crystallizing. If the cane juice 
 has other impurities in it, these keep still more sucrose 
 from forming crystals. Hence a cane juice showing no 
 more than 10 degrees, Brix, would hardly be worth work- 
 ing for sugar, because low density always means high 
 impurity of juice. 
 
 Grinding Season. — When frost comes, tremendous 
 •efforts are put forth by the sugar planters to grind all 
 the cane before it begins to spoil. The mills usually run 
 only 75 days. The machinery is so massive and costly 
 that the investment is very large in proportion to work 
 done. 
 
 In the tropics, mills run 150 days during the year. In 
 this country the short grinding season and the green con- 
 dition of the cane make the manufacturing of the cane 
 expensive. Good mills in the tropics have worked at a 
 total manufacturing cost of about 60 cents a ton of cane 
 
SUGAR CANE 175 
 
 handled, or about a quarter of a cent a pound for the 
 sugar made. But in our sugar belt the cane is greener, 
 the juices contain less sugar and need more boiling, the 
 bagasse^ or ground cane stalks, do not furnish sufficient 
 fuel, so that the manufacturing cost of each pound of sugar 
 is perhaps three times as great as it is in the best mills 
 in the tropics. The large mills in Louisiana and Texas 
 buy cane from the small farmers, paying about $3.50 a 
 ton for it loaded on the cars. With a thirty-ton yield, it 
 should be a profitable crop to grow. 
 
 QUESTIONS 
 
 Where is sugar cane grown in the United States, and for what 
 purposes is it grown ? Where is it grown for sugar making? Does 
 sugar cane mature in the United States? What part of the cane do 
 people of the tropics plant? How is the sugar cane kept over winter 
 in the United States? How is it planted? What sort of fertilizer 
 does it need? What country grows the most sugar cane aiid rice per 
 acre? Is sugar cane very hard to cultivate? How much cane does 
 land make in the United States? Where are the yields largest? 
 When does cane get sweet in the United States? How is sirup made 
 from the cane? What kind of land makes the finest quality of sirup? 
 What sort of instrument would enable you to boil your sirup just 
 right? How can sirups be kept fresh? How was sugar formerly 
 made in Louisiana? What is the principle of the vacuum pan, and 
 why does it make more sugar? Why is the manufacture of sugar in 
 the United States more costly than in the tropics ? 
 
 Experiment. — If your father does not put uj) sirup in cans or 
 sealed jugs, suppose you get a few clean bottles and new stoppers. 
 Run hot sirup into these and stop up thoroughly while hot and keep 
 till next summer, when barreled sirup is of bad quality. Show 
 samples to your teacher and schoolmates. 
 
CHAPTER XXV 
 
 THE SWEET POTATO 
 
 The Sweet Potato has always been an important crop 
 in the South. Thin, loamy soils produce fine crops of the 
 very best quality. The long-leaf pine soils are ideal for 
 this crop. When grown on heavy lime, clay, or bottom 
 land, the sweet potato has a poor flavor, and does not keep 
 well. 
 
 Varieties. — If, indeed, the farmers of every community 
 have not provided themselves with suitable varieties of 
 other common crops, they certainly have done so with sweet 
 potatoes. Perhaps the bunch, or vineless, yam has not 
 been distributed so widely as its merits would justify. 
 Experiments indicate that this kind makes better yields 
 during seasons of drought than most of the other kinds. 
 Then its bunch habit of growth permits better and late 
 cultivation, and this of itself makes it stand drought 
 better. 
 
 Preparation and Fertilizing. — The sweet potato needs a 
 good high ridge, or bed, to grow in. The soil should 
 be plowed deep enough to prevent the potatoes from 
 making above ground so as to be exposed to frost, fowls, 
 animals, etc.; and at the same time shallow enough to 
 prevent them from forming so deep in the ground that 
 they will be cut by the plow in digging. 
 
 176 
 
THE SWEET POTATO 
 
 177 
 
 Fig. 62. — Hill of vSweet Potatoes 
 
 Sweet potatoes do not need rich soil, and they are as 
 easy to fertilize as cotton. Some two or three hundred 
 pounds of good cotton fertilizer to the acre will be ample 
 for this crop. Anj^ thin 
 land that will make a quar- 
 ter of a bale of cotton to 
 the acre will make fine 
 sweet potatoes without the 
 help of fertilizers, if it is 
 first allowed to grow weeds 
 a year or two. 
 
 Planting. — Some farm- 
 ers plant the small, stringy 
 potatoes, which they cut into little pieces and plant as they 
 do Irish potatoes. A more general practice is to bed out 
 the potatoes in early spring, laying them close together in a 
 bed made rich with manure. They will sprout and make 
 slips in April and May. These slips are pulled from the 
 bed and transplanted in the field where they are to grow. 
 More slips come up from the bed, and these are likewise 
 transplanted. As soon as the slips in the field grow vines 
 a foot long, these are cut and transplanted. The crop is 
 thus multiplied from the bed and from the vines in tlie 
 field, and sometimes plantings are continued into August 
 in the Gulf and South Atlantic States. Potato slips or 
 vines should be planted only in clean beds. Otherwise, 
 the crop will become foul with weeds and grass, and this 
 will greatly diminish the yield. 
 
 Labor in Planting. — The time required to set out the 
 vines and slips is the greatest obstacle in the way of large 
 
178 ELEMENTS OF AGRICULTURE 
 
 })lantings. The plants should be set two feet apart in 
 four-foot rows. As the great bulk of the crop is planted 
 from vine cuttings, much time can be saved by opening 
 the row, or bed, Avith a small plow to receive the vines. 
 Lay the butt ends of tlie vines across the furrow and 
 step on them to press them down, letting the tops 
 extend out over the edge of the furrow all on one side. 
 Then cover by running a small plow on the opposite side 
 of the furrow from the tops of the vines and throwing 
 dirt into the furrow, but not far enough to cover the 
 tops. By this plan, very rapid and satisfactory work can 
 be done. Three or four hands and one horse can put out 
 tliree acres a day. 
 
 Harvesting and Keeping. — Cultivation should continue 
 as late in the season as the growth of the vines will per- 
 mit. Though the vines make fine grazing for cattle, 
 tramping is likely to bruise the potatoes so as to cause 
 fungous diseases that make the potatoes hard to keep. 
 The crop should be dug before a severe frost. If hard 
 frost catches the crop in the ground, the ends of many 
 potatoes will be injured, fungous diseases will enter, and 
 the whole crop will be liable to rot. 
 
 If the vines are cut by a sharp rolling colter, or some 
 similar tool run in each middle, they will not be difficult 
 to handle. Whatever plow or digger is used, it should 
 not be run deep enough to cut the potatoes or bruise 
 them. Barring off with a turn plow and splitting the 
 beds o})en with a big lister is a good plan. No other 
 arrangement which the author has yet seen is better to 
 keep the crop than the small cone-shaped "hill," or 
 
tup: swep:t potato 
 
 179 
 
 " bank," so made that the potatoes can be kept dry by 
 laj^ers of bark, straw, or corn stalks, and covered wi^h 
 dirt to keep out the cold. 
 
 Fig. 63. — Digging Sweet Potatoes 
 
 Yield and Profits. — The sweet potato is now being 
 largely shipped and sold at very profitable prices, bring- 
 ing from 50 cents to f 1 a bushel at the shipping station. 
 As 200 to 300 bushels are very common yields, it is easy 
 to see that the crop is profitable. 
 
 Canned Potatoes. — Of late years, canning factories are 
 buying large quantities at good prices, and putting them 
 up as they put up tomatoes, corn, and other vegetables. 
 No product keeps better in cans, and no canned goods 
 are meeting a better demand. Tliere is much more 
 food value in a can of potatoes than in a can of tomatoes 
 or corn of the same size, and the cost of canning them is 
 comparatively small. Some farmers are buying small 
 
180 ELEMENTS OF AGRICULTURE 
 
 canning outfits costing from fifty dollars down as low as 
 ten dollars, and putting up their surplus fruits and vege- 
 tables of all kinds. 
 
 As Stock Food. — As a stock food, the sweet potato is 
 highly esteemed. About three and one-third bushels are 
 equal to a bushel of corn in feeding value. If it were 
 not for the extra trouble and expense of growing and 
 handling a heavy, watery crop of this kind, and the un- 
 certainty of keeping them sound, sweet potatoes might 
 largely displace corn as a farm feed. At present they 
 are often grown for hog feed, and the hogs are allowed 
 to do the harvesting. As the hogs eat both vine and 
 tubers, a reasonable acreage of potatoes can be grown 
 very profitably for this purpose. A peanut crop near 
 enough for the hogs to graze on will increase the good 
 results, because the two foods together balance each other. 
 If the two crops are separated by a fence, the hogs can 
 easily be made to graze partly on each every day by 
 simply shifting them from one field to the other. 
 
 QUESTIONS 
 
 How would you grow sweet potatoes? What arrangement is 
 suggested for saving labor in planting out vines? Why not let 
 cattle run over the potato field? How can potatoes be kept best? 
 What is said of canned sweet potatoes? What is a fair yield for an 
 acre of sweet potatoes? What amount of sweet potatoes would be 
 equal to a bushel of corn for feeding ? 
 
CHAPTER XXVI 
 
 THE COWPEA AND PEANUT 
 
 The Cowpea. — This is one of the most valuable crops 
 grown in any country. The farmers of the South, failing 
 properly to estimate its importance, do not grow it as 
 extensive^ as they should. 
 
 Varieties. — The value of this pea as hay, as a fertili- 
 zer, and as a crop in a rotation, has already been men- 
 tioned. There are numerous varieties, some ripening in 
 seventy days from planting and others requiring the 
 whole season. The cowpea was originally a tropical 
 plant, and in the tropics varieties may now be seen that 
 run over the tops of large trees, and have pods two feet 
 long. In this country these kinds would be caught by 
 frost before they matured seed. 
 
 Curing the Vines. — Pea vines are usually considered 
 difficult to save for hay. If they are not cut until they 
 get old enough for a few pods to ripen, the curing is not 
 so difficult as it is generally supposed to be. One or two, 
 and sometimes four, tons of hay, equal to clover and 
 nearly equal to alfalfa in value, may be saved from an 
 acre of pea vines. 
 
 Saving Seed. — The seed of the cowpea is now being 
 saved in some of the states by mowing the vines when the 
 peas are ripe, and running them through a threshing 
 
 181 
 
182 ELEMENTS OF AGRICULTURE 
 
 machine. This crop yiekls from eight to twenty-five 
 bushels of seed to the acre. Where the seed can be saved 
 cheaply, they are very profitable, as they sell for from one 
 dollar to three dollars a bushel. 
 
 In the southern part of the Gulf States, two crops of 
 some varieties can be raised in one year on the same land. 
 One kind, a white, black-eyed variety, now being gener- 
 ally sold by grocers, is fast displacing the navy bean in 
 the markets. This kind retails at about six cents a pound 
 in the grocery stores. You might grow a crop and make 
 some money from it. 
 
 Peas for Hogs. — This crop has for a long time been 
 esteemed as a liog food. Certain experiments in Arkan- 
 sas, Mississippi, and Alabama indicate that an acre of 
 good peas gathered by hogs will produce from 300 to 400 
 pounds of gain in live weight. 
 
 Cultivation. — Peas are often sown broadcast and plowed 
 under, but they do better if drilled in rows wide enough 
 to permit cultivation. On thin land 150 pounds acid 
 phosphate will make them yield a large crop. They need 
 no nitrogenous fertilizer, as they can get nitrogen from 
 the air. In some sections a little potash salt with the acid 
 phosphate will be profitable. 
 
 Peanuts: Their Uses. — This crop has been grown rather 
 largely in some of the states for a long time, but the 
 United States has never grown more than enough to 
 supply the demand for nuts for parching. Peanuts have 
 been somewhat largely grown for hog feed, the Jiogs 
 generally being allowed to gather the crop. Different 
 experiments have usually shown that an acre of good 
 
THE COWPEA AND PEANUT 
 
 183 
 
 nuts will produce about 500 pounds of growth in young 
 hogs. Peanuts are also cured, vine, nut, and all, for hay 
 for horses, cattle, and sheep. A good yield of this hay, 
 when well cured, is two tons to the acre. 
 
 Fig. 64. — Spanish Peanuts 
 
 Varieties. — The variety generally grown for hay is a 
 small, quick-maturing kind, called the Spanish peanut. 
 When the vines are pulled up, practically all the nuts 
 adhere to the vines. The nuts of this variety are shelled 
 by machinery, and used in candies and confections, and for 
 parching and selling as salted peanuts. Somewhat larger 
 kinds, one of them being called the Virginia nut, are 
 
184 
 
 ELEMENTS OF AGRICULTURE 
 
 grown more largely for tiie parching trade, and have 
 been bringing a very high price for* some years. 
 
 Climate and Soil. — All the uplands of the South and 
 Southwest are well suited to this crop. The light-colored, 
 sandy lands make the smoothest and cleanest nut for tlie 
 market, but clay and lime lands make larger yields. In 
 the sections infested with the boll weevil there is great 
 interest in this crop as a market crop. 
 
 Peanut Oil. — If more nuts are produced than the 
 parching trade will take, the cotton-seed oil mills, with the 
 
 addition of a lit- 
 tle extra machin- 
 ery, could crush 
 them for oil and 
 cake. A bushel 
 of nuts will pro- 
 duce from one to 
 one and a half 
 gallons of oil and 
 
 
 
 
 1 
 
 
 «>% 
 
 
 ii 
 
 
 
 
 "" ¥"' ' 
 
 •i 
 
 
 
 \ 
 
 
 
 ^ 
 
 ^^ 
 
 Fig. 65. — SavinCx Peanuts ten tO fifteen 
 
 pounds of cake 
 fully as rich as cQtton-seed cake. Peanut oil is a high- 
 priced oil, and the cake is worth more than cotton-seed 
 cake, because it is suitable for feeding horses and hogs. 
 At prices lately prevailing for peanut oil, the mills could 
 afford to pay from sixty to seventy-five cents for a bushel 
 of nuts and still make a very fair profit. At such prices a 
 good profit could be made by the grower, as fifty bushels 
 can easily be made on an acre, and the crop can be 
 threshed cheaply by machinery. An acre of peanuts will 
 
THE COWPEA AND PEANUT 185 
 
 yield about a ton of good hay or straw, in addition to 
 the nnts. 
 
 Cultivation. — Peanuts, like peas, need only acid phos- 
 phate or phosphate and a little potash salt as a fertilizer. 
 Occasionally lime may be needed on very sandy land to 
 make the larger kinds fill their pods well. 
 
 Peanuts are often grown in corn, or after oats, just as 
 peas are, and sometimes take the place of peas in the 
 rotation of crops. They are more expensive to grow than 
 peas, as they need more hoeing. Good, well-selected, 
 clean peanuts are selling in Southern cities for eight cents 
 a pound. Suppose you grow an acre, making fifty bushels, 
 hoAv much money could you make ? 
 
 QUESTIONS 
 
 What are the many uses of the cowpea? What suggestion is 
 made for savhig the hay? What sort of machinery is being used to 
 save the seed? Where can two crops of cowpeas be grown on the 
 same land in the. same season ? What article of food is being dis- 
 placed by the cowpea? How much pork will an acre of cowpeas 
 produce? What fertilizer would you use for peas? What are the 
 uses of the peanut? How are they handled as stock food? What 
 kind are generally grown for stock food? How are peanuts shelled? 
 What kind is grown largely for parching? What sort of land makes 
 the best market nut? What kind of land will make largest yields? 
 How could oil mills handle peanuts? How much oil and cake would 
 a bushel make? What value ought this to give the peanut for crush- 
 ing in the mills? How much vines or hay will an acre make? 
 
CHAPTER XXVII 
 
 TOBACCO 
 
 Tobacco is one of the big crops of tlie United States. 
 A very large amount of tobacco is sold for domestic use 
 and for export ; also cigar tobaccos of such qualities as 
 are not grown in this country in sufficient quantity are 
 imported in large quantities. 
 
 Tobacco was being grown and used by the Indians of 
 both North and South America when Europeans dis- 
 covered the Western World. 
 
 When Magellan discovered the Philippine Islands in 
 1521, his ships first anchored in the Bay of Cebu, where 
 the king of the Philippines lived. The king sent his most 
 trusted minister out to see what manner of visitors had 
 come. The minister in his little boat circled around the 
 ships nearly all night, and observed closely all that took 
 place. Before day he went back to shore and reported to 
 the king that the new-comers were great, white giants 
 with hooked noses and red eyes, who ate stones, drank 
 fire, and blew smoke out of their nostrils. On receiving" 
 this report, the king killed a large number of carabao 
 (water buffalo) and pigs, prepared a great feast, invited 
 the Spaniards ashore, and gave tliem the country. 
 
 As Magellan's expedition had tarried some weeks in 
 Brazil, where the sailors could have learned to smoke, they 
 
 186 
 
TOBACCO 
 
 187 
 
 probably were smoking, and this gave rise to the wonder- 
 ful story about their drinking fire and blowing smoke out 
 of their nostrils. 
 
 Influence of Soil. — Very few plants are so much in- 
 fluenced by the kind of land they grow on as is tobacco. 
 If the seed of Havana cigar tobacco, which is grown on 
 sandy land, is planted on the stiff clay and limy land tl>at 
 grows the heavy chewing tobacco well, it will make a to- 
 bacco more like chewing tobacco than cigar tobacco. The 
 slightest change in soil materially changes the grade of 
 tobacco. 
 
 The great bulk of the chewing tobaccos are grown in 
 Kentucky, Virginia, Maryland, Missouri, Tennessee, and 
 North Carolina. 
 The states of 
 Pennsylvania, 
 Connecticut, 
 Ohio, Wiscon- 
 sin, and New 
 York grow 
 large quantities 
 of cigar tobacco. 
 
 Shade-grown 
 Tobacco. — 
 Some very fine 
 cigar tobacco is 
 being grown under partial shade in Georgia, Florida, 
 Alabama, and Texas. These tobaccos are grown on well- 
 drained loamy or sandy types of land. The field is en- 
 tirely covered with a thin cheese cloth supported on suit- 
 
 
 
 Tobacco growing under Cheese-cloth 
 Shade 
 
188 ELEMENTS OF AGRICULTURE 
 
 able framework. Sometimes the frames are partially 
 covered with narrow slats that shut out part of the sun- 
 light. This partial shade makes the leaf thin and of most 
 desirable quality. The covering protects the crop from 
 being whipped by winds, and to some extent from insects. 
 Often the expense of covering the land and producing the 
 crop amounts to several hundred dollars an acre. This 
 investment is, however, profitable, as it sometimes assures 
 the production of a crop of 1,500 pounds of tobacco, worth 
 from twenty-five cents to one dollar a pound. 
 
 Sumatra Tobacco. — Good Sumatra w^rapper leaves for 
 cigars cost the manufacturer, after paying duty, about 
 ^3.00 a pound. But the leaves are so fine and thin that 
 a pound will wrap from 500 to 1000 cigars. The planters 
 of Sumatra use Chinese labor under a system of peonage 
 that assures extreme care in handling the tobacco at every 
 .stage, and hence they make the finest leaf in the world. 
 Ordinary American-grown wrappers require six to eight 
 pounds to wrap a thousand cigars. 
 
 The shade-growing metliod enables Southern growers 
 to make leaf approaching the Sumatra leaf in value. 
 Havana tobacco is also coming to be largely grown on the 
 light lands of the South. It makes a filler tobacco nearly 
 as good as the Cuban product. Grown under partial 
 shade, the Havana tobacco turns out a good proportion of 
 desirable wrapper leaves. 
 
 Fertilizing. — Tobacco needs lil)eral fertilizing, and is 
 generally supposed to need a good percentage of potash 
 in its fertilizer. It contains an unusually large percentage 
 of potash, as well as nitrogen, but the analysis of a crop is 
 
TOBACCO 18!> 
 
 not always a safe guide as to its fertilizer needs. This 
 potash should never be in the form of potassium chloride, 
 or the tobacco will not burn well. Potassium sulphate is 
 the form in which the potash should be applied. Tobacco 
 grown within five or ten miles of the sea contains too 
 much chlorine to burn well. 
 
 Tobacco growing and handling must be specially studied 
 in order to be well understood. Students should send 
 for bulletins of the Department of Agriculture and of the 
 Experiment Stations of the states that grow large quanti- 
 ties of tobacco. 
 
 qup:stions 
 
 Where was tobacco originally found? What story is told of Ma- 
 gellan's discovery of the Philippines V What kind of land grows heavy 
 chewing tobacco? What kind of land grows the cigar tobacco? 
 What states grow most of the chewing tobacco? Tell where shade- 
 grown tobacco is made. Give an idea of the expense and returns on 
 shade-grown tobacco. Where and under what conditions is the 
 best cigar tobacco in the world grown ? What precautions must be 
 taken in fertilizins: tobacco? 
 
CHAPTER XXVIII 
 
 SORGHUM, KAFIR, AND MILO-MAIZE 
 
 Origin, Uses, and Adaptability. — These three, together 
 with chicken-corn, broom-corii, doiira-corn, etc., have been 
 grown for ages in the East Indies and in Africa. The sor- 
 ghnnis have been cultivated largely in the United States 
 only during the last twent}^ years. At first the sweet 
 sorghum was grown mostly for sirup-making, but is now 
 more largely used for hay. The n on -saccharine kinds are 
 very largely cultivated for grain in the semiarid parts of 
 the West, where Indian corn is uncertain. Although tropi- 
 cal plants, these sorghums have made themselves perfectly 
 at home in the northern part of the United States, and 
 will flourish where the climate is too cool for Indian corn. 
 Their great feature is their ability to stand drought. They 
 appear to become almost dormant in a dry time and to wait 
 for weeks, and even months, for rain ; and, after being 
 watered, they grow remarkabl}', and make good crops. 
 These plants can also stand wet conditions better than 
 most plants ; they will grow on poorer land and with 
 poorer culture than most crops, and will stand considerable 
 alkali. They are great, hardy, vigorous, giant grasses 
 that thrive under most all conditions. The tremendous 
 growth in the cultivation of these sorghums in late years 
 lias been one of the marvelous things about American 
 iigriculture. 
 
 190 
 
SORGHUM, KAFIR, AND MILO-MAIZE 
 
 191 
 
 For Hay. — The sweet sorghum is largely sown broad- 
 cast or drilled like wheat, at the rate of about a bushel of 
 seed per acre, to make hay. It generally produces two 
 crops of hay in the season, if planted early. In the Gulf 
 States it is often planted about April. In the states 
 farther north, May and June plantings will be safer. This 
 plant makes large crops of coarse but nutritious hay. For 
 
 m9 
 
 i>^m 
 
 ^^pm, 
 
 Fig. G7. — Harvesting Sorghum 
 
 early plantings it is necessary to sow it thick so the stalks 
 will be small. Otherwise the stalks will be too coarse and 
 woody to be eaten well when they get dr3^ Where sor- 
 ghum can be matured just before frost, large stalks may be 
 cut and stacked, and it will keep well all winter with the 
 juice in the stalks, and is greatly relished by stock. In the 
 dry belt sorghum ought to be planted in drills wide enough 
 to be worked a little, if possible, in order to save moisture. 
 
192 ELEMENTS OF AGRICULTURE 
 
 Planting and Culture. — The non-saccharine sorghums 
 are usually planted in drills. A favorite plan in the dry 
 country is to run a lister with a planter attachment so as 
 to drill the seed in the bottom of the lister furrow. This 
 plan assures a stand, and the gradual working of dirt to 
 the crop makes it stand drought well. On the plains these 
 crops are often put in by sowing seed in every third or 
 fourth furrow made by a turn plow while breaking the 
 raw sod. The next furrow covers the seed with two or 
 three inches of turf, and not another stroke of work is done 
 until time to gather the crop. The hard, unbroken soil 
 at the bottom of the shallow plow furrow appears to be 
 suitable feeding ground for the roots of these hardy plants, 
 and the coating of unrotted grass sod appears to let in the 
 rain water and to serve as a mulch to keep the water from 
 evaporating. Excellent crops are made in this way. As 
 land becomes older and weeds begin to appear, regular 
 cultivation becomes necessar3^ 
 
 Kafir and Milo Maize. — These crops always make more 
 grain per acre than Indian corn, and when seasons are 
 unfavorable may make twice or three times as much. 
 They are often cut near the ground with corn harvesters 
 and shocked in the field. From the shocks the grain and 
 the stover are fed ; sometimes the cattle are turned in 
 to help themselves and sometimes it is hauled to them. 
 When the grain is fed whole to cattle or horses, a great 
 deal of it is undigested ; but if fed in winter there need be 
 nothing lost. The undigested corn keeps perfectly in the 
 dry, cold winters of the plains until found and eaten by 
 hogs and fowls. The planting of these crops is done late 
 
SOKGIIUM, KAFIR, AND :\IILO-MAIZK 
 
 19a 
 
 enough so they will ripen just before frost. Then if any 
 grain is knocked down, it keeps. If labor is scarce, horses 
 and cattle are turned on the field to do the harvestinsf. 
 What they trample down keeps perfectly for the hogs. 
 Grinding. — These crops are made about as digestible as 
 
 Fig. ()8. - Field of Kafir Corn 
 
 Indian corn by grinding. In fact, all experiments indicate 
 that ground kafir or milo is about nine-tenths as valuable, 
 pound for pound, as corn meal for feeding animals. Some 
 people, therefore, thresh and grind these crops. To save 
 the expense of handling too much stover, some have little 
 attachments fastened on to a wagon bed for cutting the 
 
194 ELEMENTS OF AGRICULTURE 
 
 heads and loading them on the wagons. In this shape the 
 grain is easy to handle and thresh and grind. 
 
 Diseases. — In the humid sections of the South, where 
 only the sweet sorghum is grown to any extent, the seeds 
 have been blighting of late years, so that the people cannot 
 save their own seed. These are bought, usually from 
 western Kansas and Oklahoma. 
 
 Grazing. — Occasionally sorghums are planted thick for 
 grazing, and, if not grazed too closely, stand this treat- 
 ment well. It is used more for grazing hogs than for the 
 other stock. Hogs are turned on it Avhen tlie crop is knee 
 high, and continue to graze it until it ripens, when they 
 chew it and eat the seed. 
 
 Poisons in Sorghum. — Green sorghum has often killed 
 cattle. This seems to be caused by the poison called 
 " prussic acid " that is occasionally found in green sor- 
 ghum, especially at tlie end of a long drouglit. The East 
 Indian farmers knew of tliis poisonous property of sor- 
 ghum ages ago, and learned to cut and partially dry the 
 feed before giving it to their oxen and buffalo. By 
 partial drying, tlie poison disappears in large measure. 
 
 Sorghum Alcohol. — Sweet sorghum is seriously con- 
 sidered for making alcohol for cooking, heating, lighting, 
 and ])ower on the Plains, where fuel is scarce and expen- 
 sive. An acre of good sorghum would easily produce two 
 hundred gallons of pure alcohol, and the expense of manu- 
 facture is not great. Where other fuel is so costly, alcohol 
 may easily be worth thirty to fifty cents a gallon for many 
 uses. Broom Corn is now being largely grown in West 
 Texas, Oklahoma, and Kansas. Being a sorghum, it 
 
SORGHUM, KAFIR, AND MILO-MAIZE 195 
 
 stands drought well, and cures beautifully in the dry 
 climate of the West. No sheds are needed to cure the 
 brush into the best quality of product. A fair yield is 
 700 pounds an acre, worth three or four cents a pound. 
 
 QUESTIONS 
 
 What two classes of sorghum are there? Give the origin of these 
 crops. Where are they largely grown ? For what four purposes are 
 they grown ? Under what extremes of climate and soil can sorghums 
 thrive? In what ways are these crops planted? How are they 
 gathered? Why is there little loss of these grain crops on the Plains? 
 How do the people harvest and handle the grain ? What of the com- 
 parative yield of Indian corn and kafir? What of the comparative 
 feeding values of Indian corn and kafir? Tell somethhig of broom 
 corn. 
 
CHAPTER XXIX 
 
 THE VELVET AND SOY BEANS, ALFALFA, HAIRY VETCH 
 
 Velvet Bean. — This is a large tropical bean that makes 
 vines as large as a plow line, and often fifty feet long, 
 bearing seed in pods covered with a fuzz resembling 
 velvet. 
 
 This bean needs the whole season to grow in, and even 
 then does not mature seed farther north than Florida and 
 South Texas. It needs a little cultivation till it begins 
 to cover the ground, after which it makes a dense mass of 
 tangled vines and leaves, some three or four feet deep. 
 No other crop grows better on poor sandy land, makes 
 such a dense shade, or accumulates so much nitrogen from 
 the air. As before stated, an acre will contain two hun- 
 dred pounds of nitrogen, worth at commercial fertilizer 
 prices, thirty-six dollars. 
 
 The vines are seldom cut for hay, but are pastured by 
 cattle. The enrichment of the land is usually the main 
 object. In Florida, large crops of the seed are gathered 
 and ground into meal, which makes a rich food for stock. 
 
 The few seed necessary to plant an acre are not expen- 
 sive, even where they must be purchased every year. 
 
 The Soy Bean. — This is a Japanese bunch bean. It is 
 extensively cultivated in Japan and China for the oil that 
 is pressed from it. In some parts of this country it is 
 
 196 
 
VELVET AND SOY BEANS, ALFALFA, VETCH lU" 
 
 ground into meal and mixed Avith corn meal for hogs and 
 other live stock. A little soy-bean meal added to the 
 feed of live stock never fails to give an increase or gain in 
 weight. This is • 
 due to the large 
 amount of protein 
 and oil in the 
 bean. The soy- 
 bean vines, or 
 straw, do not 
 make as good 
 feed as cowpea 
 
 
 
 w 
 
 ^ 
 
 
 Ji 
 
 or peanut vines. 
 Tlie.crop has not 
 become very pop- 
 ular south and 
 east of Kansas 
 and Oklahoma. 
 
 Alfalfa: Culti- 
 vation.— No crop 
 has attracted 
 more attention, 
 and no crop has been tried oftener and has failed more 
 frequently, than alfalfa. As it needs very rich land, it 
 does remarkably well under irrigation, on the arid and the 
 semiarid land in the West. In the East it is probable 
 that the only lands rich enough for it are the lime prairies 
 and the buckshot bottoms. There are some indications 
 that it is a plant which requires large amounts of lime 
 in the soil. When young, it is extremely tender, and easily 
 
 Fig. (59. — Soy Bean 
 
198 ELEMENTS OF AGRICULTURE 
 
 killed by grass and weeds. The crab grass of the sandy 
 lands of the South will soon choke it out. 
 
 Alfalfa does best when seeded in the fall. In the Gulf 
 States, if the land is kept clean of weeds and grass in the 
 sx3ring and samraer, and plowed and harrowed until 
 planting time in September or October, the best success 
 may be expected. It is a mistake to recommend the 
 
 Fig. 70. — Stacking Alfalfa Hay 
 
 planting of alfalfa on ordinary sandy, loamy, or clay land 
 outside of the arid and semiarid sections. 
 
 In some of tlie arid sections alfalfa is known to have 
 lived and grown thirty or more years from one planting. 
 In dry, porous soils its roots have been known to grow 
 forty feet deep. In the humid sections thirty pounds of 
 seed per acre are recommended ; in arid sections half this, 
 as all crops stool and sucker more on rich arid lands. 
 Seed should be planted as carefully as turnips are planted. 
 
 Uses ; Curing and Saving Hay. — Where it does tlirive it is 
 a crop of great value, giving each year four or five cuttings 
 of the finest hay known. It also greatly improves the 
 fertilitv of the land. In the humid sections considerable 
 
VELVET AND SOY BEANS, ALFALFA, VETCIl 1U9 
 
 trouble is experienced in saving alfalfa hay. The heaviest 
 crops are in the spring, when conditions are not good for 
 curing hay. One plan practiced Avith success is to throw 
 it into cocks, or tall piles, of two or three hundred pounds 
 each when it is partially cured and cover each pile Avith 
 a cheap cap of cloth or paper and let the hay remain 
 ten days or two weeks, when it is put in barn or stack. 
 No certain rules that will fit everybody's case can be given 
 for saving hay. All hay in humid climates should be 
 stacked a month before baling. 
 
 Hairy Vetch; Habits and Uses. — In order that this 
 crop, which has already been mentioned, may not be con- 
 fused with other vetches, its scientific name, Vicia villosa, is 
 given. The seed should be sown in the fall at the rate 
 of from a half-bushel to a bushel to the acre, about as oats 
 are sown. It makes only a small growth in winter, but 
 in early spring it grows with remarkable rapidity. By 
 May, in the Gulf States, it is ready to cut for liay. It 
 dies in June, shedding its crop of seed on the ground ; 
 these seed come up in the fall again, and thus the vetch 
 becomes a wild plant, but it is never hard to get rid of. If 
 it is cut for liay before it makes seed, or if it is grazed 
 closely by stock, it disappears. Plowing it under as a 
 green manure before it seeds also kills it. 
 
 Close grazing in winter and early spring does not hurt 
 it. If stock are taken off it before it gets ready to make 
 seed, it recovers with remarkable rapidity. 
 
 The best way to start the vetch is to mix about fifteen 
 pounds of seed to two bushels of oats and sow to each acre. 
 After the first sowing the vetch will come up each fall. 
 
200 ELEMENTS OF AGRICULTURE 
 
 Sorghum may be grown between the crops of vetch. 
 The vetch is a more vigorous grower than the bur clover, 
 and enriches the land faster. It flourishes on all classes 
 of fairly well-drained land, 
 
 QUKSTIOXS 
 
 Tell something about the velvet l>eaii. What is it particularly 
 valuable for? Where is the bean made into meal? Where does the 
 soy bean come from ? What is its special value in producing a mixed 
 feed? What ingredients of feed stuff is the soy bean rich in? Where 
 in the United States has alfalfa proved a certain crop? Where has it 
 pi'oved uncertain? Does it need rich land? What lands in the South- 
 ern States have grown it well ? Can it stand weeds very well when 
 young? At what season should it be seeded? How should the land 
 be treated during the summer before seeding? Ls alfalfa likely to 
 succeed on ordinary sandy and loamy lands? Does it improve the land, 
 and if so, why? Is it very difficult to save for hay? What sort of 
 plant is the hairy vetch? When does it make its growth? Will it 
 sow its own seed and come every year after once being seeded? Is 
 it very hard to get rid of ? What crop is it easily started with ? What 
 crop may be grown on the land after the vetch dies in the spring? 
 
CHAPTER XXX 
 
 THE CLOVERS AND MINOR CROPS 
 
 Red Clover. -^ This plant tlirives in tlie northern and 
 eastern parts of the United States, and does well as far 
 south as Tennessee and as far west as Kansas and Okla- 
 homa. The crop is not a 
 reliable one for the Gulf 
 States, and is not grown 
 largely in the West, where 
 alfalfa thrives best. 
 
 This plant requires fertile 
 soil and careful preparation 
 of land. Much of the soil of 
 our Southern States is said 
 not to be good enough to 
 grow it. 
 
 Red clover is a biennial ; 
 that is, one planting makes 
 crops for two years and dies. 
 It makes big crops of hay 
 and a large growth of root 
 and stubble. As it secures nitrogen from the air, its 
 roots and stubble greatly enrich the land and make it 
 open and porous. Corn grown on clover sod always 
 makes a large yield. 
 
 201 
 
 Rkd Clover 
 
202 ELEMENTS OF AGRICULTURE 
 
 In some parts of the North red clover is used in the fol- 
 lowing rotation : two years clover, one or two years corn, 
 one year wheat or oats, and perhaps one year of Irish 
 potatoes. The fall is much the best time to start red 
 clover in the southern part of its territory. Fifteen 
 pounds of seed to an acre sown on hmd well enough 
 prepared for turnips should bring success, if the land is 
 of suitable kind. 
 
 Bur clover is an annual; that is, it comes up in the 
 fall, grows all winter and early spring, and dies, root 
 and top, after making seed that are shed off on the 
 ground. Cattle do not api)ear to relish this })lant as 
 they do some others, but they have been known to winter 
 on it and be in good condition in the spring. It is sel- 
 dom or never cut for hay. JJur clover grows on almost 
 any kind of soil. The author has seen it grow well on 
 strong lime lands and on the poorer sands of the long- 
 leaf pine region. Wherever in the South there is rain 
 enough to bring it up in the fall it will grow to advantage. 
 
 Bermuda sod is an ideal place for bur clover, because 
 the clover dies about the time the Bermuda is ready to 
 grow in the spring. The Ijermuda turf prevents the 
 cattle from bogging when they are grazing the clover in 
 the winter or spring. 
 
 Bur clover may be grown in rotation with sorghum or 
 other crops which bear late planting. The sorghum may 
 be planted in May after the clover is dead. The clover 
 seed shed in the spring will come up in the sorghum 
 stubble when the fall rains come, and enrich the land for 
 the next year's crop of sorghum. 
 
THE CLOVERS AND MINOR CROPS 
 
 203 
 
 Crimson Clover. — This is an annual clover that is 
 often planted in the fall in Maryland, Virginia, and other 
 states. It is frequently sown in corn during the last 
 working in August, and used as a winter cover crop to 
 protect the land and en- 
 rich it. It is highly 
 recommended for sowing 
 in orchards, as it com- 
 pletes its growth and 
 dies in early spring be- 
 fore the orchard begins 
 to need moisture. Crim- 
 son clover is sometimes 
 saved for hay, but is more 
 often used for grazing. 
 
 It has not generally 
 succeeded in the central 
 and western Gulf States, 
 where tlie bur clover 
 appears to be a much 
 hardier and more desir- 
 able plant. 
 
 Mammoth Clover. — 
 Tliis giant red clover is 
 a much larger, coarser plant than ordinary red clover. 
 The stems are so coarse that it does not make so good a 
 quality of hay as the smaller kind. It is grown largely 
 for green forage and for enriching the land. 
 
 Melilotus or Sweet Clover. — This plant is regarded as 
 a weed in the North. In the South it grows only on 
 
 Cri:.ison (lover 
 
204 
 
 ELEMENTS OF AGRICULTURE 
 
 rotten lime-rock land, or other land rich in lime. It will 
 grow on bare lime-rock, if it can send its roots into a 
 crack of the rock'. As it makes an enormous growth, and 
 gets nitrogen from the air, it helps to restore fertility to 
 poor land. It is a bieiniial, and makes the largest growth 
 in its second year. 
 
 While it is not relished by stock, as some plants are, 
 it is very nutritious. It is used botli for grazing and 
 
 for ha}^ When 
 once started on 
 poor, washed 
 lime land, the 
 plant keeps gro w- 
 ing as a weed 
 until killed out 
 by grazing or 
 by cultivation. 
 Seed may be 
 thrown on land 
 without prepa- 
 ration at the rate of fifteen pounds per acre. Better 
 results are secured if land is plowed or disked. 
 
 Mexican Clover. — This plant, which is not a true clover 
 at all, flourishes in the sandy, cultivated lands of South 
 Georgia, Florida, and the southern part of the other Gulf 
 States. It is an annual that comes up in the cornfields 
 after the corn is laid by, and in oatfields after the oats are 
 cut. It makes excellent hay, which is generally cut and 
 saved late in the fall. 
 
 Florida Beggar Weed. — This plant also flourishes in 
 
 Fk.. 7.> 
 
 Florida Kkggak Wkkd 
 
THE CLOVERS AND MINOR CROPS 
 
 205 
 
 sandy lands, coming up volunteer late in the season on culti- 
 vated fields. It is found mostly in Florida, South Georgia, 
 and Alabama. It is a true legume, and hence enriches 
 the land it grows on. It makes good hay and grazino-. 
 
 Fig. 74. — Rape Field 
 
 Rape. — Belonging to the same family as the collard, 
 cabbage, and turnip, rape is a fine forage plant for hogs, 
 and especially for sheep. It makes its best growth when 
 sown in the fall on rich and well-prepared land. When it 
 is large enough for good grazing, hogs and sheep are 
 turned on it and allowed to eat it down somewhat closely* 
 
20() 
 
 elemp:nts of agriculture 
 
 It sprouts out again and continues to grow. It has often 
 been found to afford food equal in value to peanuts and 
 cowpeas, although in order to fatten hogs it needs supple- 
 menting with grain feed. It is 
 sown in the same way as turnips. 
 
 Chufas, or Grass Nuts. — This is 
 a crop often grown for hogs on the 
 thin, sandy lands of the South. It 
 is greatly relished by hogs, and 
 they root up the crop of sweet, 
 juicy nuts. The chufa is not quite 
 so valuable for pork-making as pea- 
 nuts, and it is exhaustive to the 
 land. The crop keeps well in the 
 ground all winter, however, and 
 this affords good feed for hogs after 
 the Spanish peanut has rotted. 
 
 The chufa, being very sweet and 
 agreeable to the taste, is bultivated 
 and sold in Spain for human food. 
 It is planted very much as peanuts 
 are. 
 
 Jerusalem artichokes are planted 
 and cultivated somewhat like the 
 Irish potato. They make large crops 
 of fleshy, starchy tubers, fully as 
 nutritious as Irish potatoes. They are grown to afford 
 grazing for hogs, but are not relished well enough to 
 make a fattening food like sweet potatoes. They keep 
 well in the ground all winter. The artichoke and chufas 
 
 Fig. 75. — Jerusalem 
 Artichoke 
 
THE CLOVER AND MINOR CROPS 207 
 
 are good late winter pasture crops. They may be grazed 
 by hogs after peanuts and sweet potatoes are gone. 
 
 QUESTIONS 
 
 Wliere is red clover largely grown? Does it need good soil? Is 
 red clover an annual, a biennial, or a perennial? Does the red clover 
 improve the land ? Tell something of the bur clover. When is it 
 planted? When does it grow and die? Is it suitable to all kinds of 
 land? How does it do growing on Bermuda sod? What other crops 
 can be grown on the land after the bur clover dies in the spring? 
 Will it come up volunteer in the fall when once seeded? What is 
 the habit and growth of the crimson clover? Has it proved as 
 successful as the bur clover? What sort of land does melilotus, or 
 sweet clover, grow on? Is it a good crop for sotne land? Where 
 is the Mexican clover grown? Where is the Florida beggar weed 
 grcnvn, and of what use is it? Describe the rape, and tell what 
 it is grown for. Of what use are chufas, or grass nuts? On what 
 kind of land do they grow especially well? What is the Jerusalem 
 artichoke ? 
 
CHAPTER XXXI 
 OTHER HAY AND PASTURE GRASSES 
 
 The Bermuda grass is one of the best pasture grasses, if 
 not the best, for the Gulf and South Atlantic States and 
 for parts of Tennessee, Arkansas, and Oklahoma. In the 
 higher and colder parts of the Plains, it cannot compete 
 with the native buffalo grass. Although a great drought- 
 resisting grass, it probably does not equal the buffalo and 
 mesquite grasses in this respect. Where Bermuda grass 
 thrives, it is the very backbone of the entire pasture sys- 
 tem. It will pasture more stock to the acre without being 
 injured, stand more drought, and afford more months of 
 grazing in tlie year than any other one grass or plant. 
 
 Value for Pasture and Hay. — People of the Mississippi 
 Delta in Arkansas, Mississippi, and Louisiana have fre- 
 quently reported that their Bermuda pastures afford 
 grazing for five head of cattle or horses to the acre from 
 April to Christmas. Good land makes large crops of Ber- 
 muda grass hay, which is easily saved and full}' equal in 
 lvalue to timothy hay. The yield is often from two to 
 four tons an acre. As Bermuda grass does not mature 
 good seed in the United States, there is no danger of its 
 spreading like Johnson grass, when used for hay. 
 
 Bermuda grass used to be dreaded as Johnson grass is 
 now ; but people have learned to work with it, and to kill 
 it when it has served their purposes. Besides the plan 
 
 208 
 
OTHER HAY AND PASTURE GRASSES 209 
 
 already given, it may be destroyed by heavy crops of peas, 
 velvet beans, or sweet potatoes, tliat shade the land well 
 all summer. 
 
 On tlie clay, lime, and bottom lands wliite clover should 
 always be grown on Bermuda pasture. Tlie clover grows 
 when the grass is dormant, and lengthens the season of 
 good grazing about two months. This gain of two 
 months' grazing in early spring means much to the 
 Southern farmer. It means he can have his cattle almost 
 fat before lieat, flies, and ticks appear, and that he will be 
 saved two months' expensive feeding. The wJiite clover, 
 once established, will last forever. This gives a natural 
 rotation of crops ; the clover, growing in winter and 
 spring, enriches the land for the grass which grows in 
 summer and fall. Toward the northern limit of the Ber- 
 muda area the blue grass begins to thrive, and may often 
 grow on the Bermuda sod. 
 
 On the sandier and poorer lands bur clover will thrive 
 better than white clover, and should always have a place 
 on Bermuda pasture. 
 
 Carpet Grass. — In the sandier districts, particularly in 
 the southern part of the Gulf States and the pine belt of 
 the South Atlantic States, carpet grass disputes very suc- 
 cessfully the possession of the soil with Bermuda. It oc- 
 cupies the little bottoms, hollows, and firuier uplands, 
 wherever grazing is done. When the land is cultivated 
 or allowed to grow up in weeds, the carpet grass dis- 
 appears. As soon as cultivation ceases and stock begins 
 to graze and tramp down the tall weeds and brush, it 
 comes again from seed that are scattered over the coun- 
 p 
 
•210 ELEMENTS OF AGRICULTURE 
 
 try. Carpet grass stands the heaviest grazmg and tramp- 
 ing, and affords a longer period of grazing than Bermuda. 
 Japan Clover, or Lespedeza. — Beginning with East Texas 
 and extending all over the rainy sections of the South, 
 this little legume flourishes on the roadsides and in almost 
 all pastures. On good land it sometimes grows high 
 enough to make fine hay. It often grows with carpet 
 m-ass and sometimes with Bermuda. It is a summer- 
 
 o 
 
 growing annual that is late in getting large enough for 
 grazing in spring, and is killed by the first frost in fall. 
 It makes fine summer grazing, and comes up and thrives 
 without sowing. 
 
 Johnson Grass. — This grass generally comes without 
 being wanted. It is not often used for pasture, except as 
 a means of killing it. It does not stand close grazing, 
 and is easily killed out in two or three years by this treat- 
 ment. However, a few people who want to graze it and 
 preserve it, divide the pasture, grazing part at a time. 
 In this way it lasts indefinitely and affords fine grazing. 
 
 Johnson Grass Hay. — This grass is generally used for 
 hay, yielding each year three or four cuttings of hay that 
 is rather better than timothy. The hay is very likely to 
 carry some ripe seed, and the grass is often spread in this 
 way. For this reason many people will not buy the hay 
 or allow it to be brought into the community. This gives 
 it a lower price than its feeding value would justify. 
 
 Killing Johnson Grass. — After Johnson grass has 
 been closely mowed for hay two or three years, it be- 
 comes so weakened that it can be easily killed. It gives 
 most trouble when it appears in patches on cultivated 
 
OTHER HAY AND PASTURE GRASSES 
 
 211 
 
 land. The bunches should be torn up with plows and 
 the hoe hands should cut them considerably below the 
 surface of the ground. By frequent careful working 
 until late in the sum- 
 mer, the grass can be 
 killed even without 
 grazing or mowing. 
 Farmers in Missis- 
 sippi and Alabama 
 are killing it in this 
 way every year. If 
 any plant can be kept 
 cut off under the 
 ground often enough 
 to prevent any top 
 growth, the roots will 
 die. 
 
 Another way of 
 getting rid of this 
 grass is to grow no 
 crop on the land and plow it several times in the summer. 
 This treatment is expensive, but it puts the land in the 
 best possible condition for a fall crop. Again, Johnson 
 grass land may be reclaimed by sowing fall oats or wheat 
 and plowing soon after harvest in June, and then keeping 
 it clean of the grass by frequent plowings, say once ever}^ 
 three weeks, till October. Sharp, heavy disk harrows, set 
 to run at the greatest angle, will probably cut off the 
 grass at each operation after the first plowing. In sum- 
 mer Johnson grass roots (rather, underground stems) rot 
 
 Fig. 76. — Johnson Grass 
 
212 
 
 ELEMENTS OF A(;RICI:LTURE 
 
 rapidly. Unless there is a green growth of leaf to gather 
 food and produce more roots, the grass must die. This 
 is true of any plant. 
 
 Chemicals. — All chemical treatments for this, or any 
 other deep-rooted pest, are entirely too expensive. Jt is 
 
 77. — GuiNKA Gkass, 1)I].oxi, Mississippi 
 
 probable that a thousand dollars' worth of the cheapest 
 chemical obtainable would not kill the grass on an acre. 
 If it did, it would kill the land for two or three years. 
 
 The people who have had this grass longest in the 
 United States have learned to utilize it and to kill it, and 
 its presence in those sections does not reduce the value of 
 the lands on which it is found. 
 
 Guinea and Para Grass. — Guinea and Para grass, both 
 large tropical grasses growing as high as a man's head, 
 and densely thick on the ground, are becoming well 
 
OTHER HAY AND PASTURE GRASSES 213 
 
 known and jippreciated in the Gulf States. Neither of 
 these grasses propagates in the same way as Johnson 
 grass, and neither is likely to become a pest. The 
 (ruinea grass spreads from seed, and the plants sucker 
 enormously ; several hundred plants come from one stalk. 
 The l^ara grows from large trailing stems in the same 
 way that Bermuda does, but much faster. Its stems will 
 often grow thirty feet in a season, and make a new plant 
 at each joint. Both of tliese grasses remain remarkably 
 succulent and tender for grasses of such size. 
 
 They are very usefid for hay and for soilinc/, and cut- 
 ting and feeding green to stock. They are also fine for 
 grazing. The Guinea grass is the main grazing grass of 
 Cuba, and the Para (^f Soutli America. Both of these 
 plants will become of great value in the southern part 
 of the cotton belt. 
 
 Crab Grass. — Crab grass is found everywhere on culti- 
 vated land in the sandy, loamy, and clay sections of the 
 South, east of the semiarid belt. It does not flourish on 
 lime lands or on buckslujt bottoms. It is often cut for 
 hay, particularly wlien it grows with peavines. It gets 
 into cultivated lands the second year after they are cleared. 
 AVhen cultivated land is converted into pasture, cral) grass 
 makes good grazing for one year, Avhen it gives way to 
 otlier growths. 
 
 Expense of Cultivating. — Crab grass adds more to the 
 expense of cultivating llie crop than any other pest, 
 except coco (nut grass) and Johnson grass. It seems 
 to exhaust the land and liurt the crop much worse than 
 Bermuda, coco, or ev^en Johnson grass. Crab grass will 
 
214 ELEMENTS OF AGRICULTURE 
 
 always kill alfalfa, but on suitable land the latter grows 
 well with Johnson grass. Crops often grow well in the 
 midst of coco and Bermuda, but never with crab grass. 
 Any considerable growth of it will turn any crop yellow 
 and make it weak and sickly. 
 
 Late, clean cultivation of land in cotton, so as to prevent 
 crab grass from making seed, will, in a measure, eradicate 
 it and make cultivation easy the next year. But it soon 
 appears on the land again. 
 
 Coco, or Nut Grass.— We have already told how crops 
 are made in spite of this pest. It is never saved for hay, 
 and amounts to little for pasture. It is widespread in 
 parts of Louisiana, Mississippi, and other states, and is the 
 hardest of all pests to kill. As hogs root after the nuts 
 on the deep roots, small patches may be killed by pasturing 
 it lieavily with hogs. Dense shade with pea vines, velvet 
 beans, etc., weaken it. 
 
 Given extra working, as good cotton is grown Avhere 
 this grass grows as where the land is clear of it. 
 
 QUESTIONS 
 
 Describe Bermuda grass. Will it cany much stock on an acre? 
 Is it ever used for hay? Was it ever considered a pest on the farm? 
 Can it be easily killed? What clover should be grown on Bermuda 
 pasture, on clay, and loamy land? What clover would be better on 
 sandy land? Where does carpet grass thrive? Where does Japan 
 clover grow ? What are its uses ? How^ does Johnson grass generally 
 get into the farms? Is it a good hay grass and is the quality of the 
 hay good? What objection do people have to the hay? How can 
 .Johnson grass be killed? Tell something of Guinea grass and Para 
 grass. Are they likely to become valuable in the United States? 
 Would you consider crab grass a pest? AVhat is nut grass? Is it 
 easily killed ? 
 
CHAPTER XXXII 
 
 ORCHARD CROPS 
 
 Intensive and Extensive Farming. — Orchards and truck 
 farms require more capital, more skill, higher fertilizing, 
 
 ^'^ 
 
 ip J 'S iii ii 
 
 Fig. 78. — Intensive Farming 
 
 (Chinese in Hawaii grow bananas and taro on ridges, ducks and fisli in 
 canals between ridges.) 
 
 and more intensive culture than other lines of agriculture. 
 Sometimes as much as ti>1000 is spent in producing a crop 
 on a single acre, and maybe -f 2000 is expected in returns 
 
 215 
 
!lt) 
 
 ELEMENTS OF A(;KICULTUUE 
 
 on the crop. One sucli crop is celery. Cabbage and 
 onions may require an expenditnre of $75 to 1 100 an 
 acre, and may bring returns of 1 150 to $300 an acre. 
 Among the crops grown on the extensive system may 
 be mentioned wheat, whose average money returns to 
 the acre in the United States are about $10, but the aver- 
 age expenditures in making and marketing may be only 
 $8 or $9. The same business ability and effort neces- 
 
 '■ ^x-M 
 
 Fli,. 7'.!. — iKlvlvxAilNG AN OllC HARD 
 
 sary to handle 500 acres of wheat would probably not be 
 sufficient for two. acres of celery or 10 acres of cabbage or 
 onions. An extreme case of extensive farming is pastur- 
 inir beef cattle on a rang^e where one man can look after 
 thousands of heads of cattle on tens of tliousands of 
 acres, each acre bringing small returns — sometimes not 
 more than 10 cents. 
 
 Early Truck and Fruit. — Growing fruits and early vege- 
 tables in the South for sliipment to Nortliern markets has 
 grown into a very large business. Solid train loads of 
 
OKCIIAKI) CROPS 
 
 217 
 
 early truck crops are often made up at a single shipping 
 point. The cars are iced and the train is run on a special 
 scliedule to get the perishable freight to the market in good 
 condition. When there is a large amount of such produce 
 to move, the railroads handle it better and get it to the 
 market more quickly than they do small amounts. At 
 
 Fig. 80. — Well-trimmed Texas Peach Tree 
 
 the same time buyers are attracted to the places of large 
 production, and better prices are offered. As truck 
 farmers have become more and more experienced in 
 making, packing, and shipping produce, fewer k)sses 
 occur, and the business is becoming more certain of fair 
 profits. 
 
 Peaches. — Among the tree fruits grown on a com- 
 mercial scale in the South, the peach stands at the head 
 of the list. Peaches are not a certain crop ; they fail 
 
218 
 
 ELEMENTS OF AGRICULTURE 
 
 Fig. 81. — San Jose 
 Scale on Peach Trees 
 
 to produce fruit perhaps half of the seasons because the 
 fruit buds are killed by cold. The orchards are not 
 expensive to bring into bearing, however, and w^hen 
 a good crop is made, it is generally very profitable. 
 Peaches do not require rich lands. 
 , . The largest and best orchards in the 
 South are found on well-drained sandy 
 loams that require commercial fertili- 
 '^ zer to produce good cotton crops. 
 The land intended for peaches should 
 be well plowed and harrowed. Good 
 budded trees should be planted, pref- 
 erably in checks eighteen by eighteen 
 feet or even wider apart. The young 
 plant should be trimmed for setting. 
 Expenses of Orchard. — Good one-year-old budded trees 
 can often be bought in large numbers for five cents each. 
 So a sufficient number of trees for an acre — 108 — would 
 only cost 'f 5.40; and preparing the land, fertilizing, and 
 setting the trees should not cost over $ 10 more. 
 
 Growing Crops in Orchard. — For the first two or three 
 years the young orchard may grow cotton or Irish potatoes 
 between the rows of trees. Any crop that is well fer- 
 tilized and cultivated will not hurt the trees. The culti- 
 vation of the crop also cultivates the trees. Heavy crops 
 of peas grown in the orchard may draw too heavily on 
 the moisture supply in late summer. Peas also breed 
 certain root diseases that in some cases are very destruc- 
 tive to the peach. The bur clover, or crimson clover, 
 makes a fine winter cover-crop for the orchard. These 
 
ORCHARD CROPS 
 
 219 
 
 crops gather nitrogen and prevent leaching in the winter, 
 and die in the spring before the moisture supply begins to 
 run low. 
 
 Cultivation in Dry Sections. — Good clean cultivation at 
 all seasons is best for orchards in dry sections of country. 
 
 Fig. 82. — Cocoanut Plantation, as skkn in I^lokida, 
 Hawaii, and the Philippines 
 
 PoKTO Kl(C) 
 
 It is impossible to grow any two crops together without 
 their dividing moisture with each other. 
 
 Pruning. — Trees should be so pruned as to force the 
 branches to grow out within from twelve to twenty inches 
 of the ground, and these branches should be pruned each 
 year so as to prevent the tree from growing too tall 
 and to give it a symmetrical shape. Observation and ex- 
 perience will be the best guides in learning how to prune 
 trees. 
 
!>20 
 
 ELEMENTS OE AGRICULTURE 
 
 Thinning Fruit. — Tliiiuiing the fruit on the tree is very 
 important. If a hirge number of peaches remains on a 
 tree, they will be small and inferior. If some are cut off 
 when small, leaving one every six or eight inches on the 
 limbs, perhaps as many total pounds or bushels of fruit 
 will be made, and the quality will be much better. Pro- 
 
 Ax Apple Branch 
 
 ducing seed is the most exhausting part of any plant's 
 work. If a great many small peaches are matured, the 
 strain on the vital energies of the tree will be greater than 
 if fewer large peaches are allowed to come to maturity. 
 
 Apples. — Apples are not commercially important in the 
 Gulf and South Atlantic States, except in the highlands 
 of parts of Georgia and the Carolinas, and perhaps on a 
 
ORCHARD CROPS 
 
 521 
 
 little elevated land in Alabama. Tlie elevated sections of 
 Northern Arkansas grow immense quantities of fine a[)ples. 
 Texas people grow a few fine winter-keeping apples on 
 the lands having an elevation of 2000 feet and above 
 in the western part of the state. The apples grown on 
 the lowlands of the South mature in summer, when the 
 weather is too warm for them to keep. In the higher, 
 more northerly, and cooler sections apples ripen in the 
 
 Fig. 84. — Figs at the Ti.xan Lxi-i^.uimkm Siaiiois 
 
 fall, when the weather is cool enough for them to keep 
 over winter. Where apples do well, they are more cer- 
 tain to yield well than peaches, and the trees live longer. 
 Virginia, Tennessee, Kentucky, Ai-kansas, Oklalioma, Mis- 
 souri, and Kansas all have great possibilities in the way 
 of apple growing. 
 
 Figs. — In the United States the fig is one of the best and 
 surest fruits that are grown, for latitudes south of thirty- 
 one and one-half and for a considerable distance north 
 
«>.)9 
 
 ELEMENTS OF AGKICULTL'RE 
 
 of this on the Atlantic coast. They do fairly well as far 
 north as 33 degrees. The fig never fails to produce fruit 
 in abundance if it has any wood growth at all. Some- 
 times in higher latitudes the trees are killed to the ground 
 by a severe frost, but they sprout up from the roots in 
 the spring and make a small crop on the new wood. 
 
 ''A 
 
 
 ^^d^^tit' 
 
 IRwi^^i 
 
 ~'~'''^m mmm >'- i- mm 
 
 Fig. <85. — Smyrna Fig Trees, California 
 
 The next year they yield abundantly. Along the Gulf 
 Coast, from West Texas to Florida, they are seldom 
 killed by the cold, and the crops are large and very 
 profitable. Some trees along the coast are known to 
 be eighty years old. No fruit tree is easier to start, the 
 iig being propagated either by layering or simple cuttings. 
 See Figure 23 for proper depth to plant fig cuttings. 
 
ORCHAKD CROPS 223 
 
 The fig needs rich soil, or soil made rich by fertilizing. 
 Often in sections where figs are liable to be killed by a 
 hard freeze, some protection like a house, a fence, or other 
 trees will save their lives. To protect oranges in South 
 Texas or Louisiana, dirt is often piled up around the 
 trunks of the trees. If the cold kills the wood above the 
 bank of dirt, the buds protected sprout out vigorously 
 and make a profitable tree again. Figs might be treated 
 in the same way, and thus more live wood be saved. 
 
 About three hundred fig trees are planted to the acre. 
 These commence bearing by the second year, and by the 
 third or fourth year often yield a dollar's worth of fruit 
 to a tree. The fruit is so desirable for preserves that it 
 brings a very high price as compared with most fruits. 
 In South Texas contracts are being made by preserving 
 establishments to take the output of orchards being planted, 
 at three to five cents a pound for the fresh figs. 
 
 Pecans. — All fine varieties of pecans now propagated 
 by grafting came originally from sports found in the for- 
 ests, and many more are surely yet to be discovered in 
 the same way. 
 
 The best statistics available place the yield of pecans in 
 Texas at 700 carloads, worth about $ 1,500,000. 
 
 The importance of planting only budded trees of good 
 kinds has been referred to. It is recommended that 
 from 25 to 50 trees be planted to the acre. The land 
 should be worked in some crop requiring clean cultivation, 
 like cotton. Pecans come into profitable bearing in from 
 7 to 10 years, and the crops increase as the trees grow 
 older. An orchard of a fine variety of pecan is very 
 
224 
 
 ELEMENTS OF AG III CULTURE 
 
 profitable, and it will probably last 100 years or 
 
 more. 
 
 Citrus Fruits. — It is freely niaiiitaiiied that Southwest 
 
 Texas has soil and climate suitable for growing oranges, 
 
 lemons, and grape-fruit in quantities to rival the produc- 
 tions of Califor- 
 nia and Florida. 
 Fine large trees, 
 loaded with 
 magnificent 
 fruit, are to be 
 found at various 
 places in South 
 Texas and Lou- 
 isiana. Many of 
 these trees are so 
 old as to prove 
 that the climate 
 is not too cold 
 for them. Many 
 large orchards 
 are being set in 
 oranges and 
 
 (Ten pounds on one short limb.) 
 
 other citrus 
 fruits, and there is little doubt but that this will become 
 one of the big industries of the Southwest as it is now 
 in the Southeast in Florida. 
 
 Satsuma Oranges. — The variety of oranges especially 
 planted in our coast country is the Satsuma, a heavy 
 bearer of medium-sized, delicious fruit without seed. It 
 
 Fl.i, Sd. — (il; Al'K FlM IT (.i;<)\V\ AT i;i'.K\lLLK 
 
 Texas, Branch Experiment Station 
 
ORCHARD CROPS 
 
 225 
 
 is d^varfed by being budded upon a small, hardy tree, or 
 shrub of the orange family, called Citrus trifoUata. This 
 trifoliata can withstand the winter as far north as New 
 York ; but its fruit is worthless, and the plant, when not 
 used as orange stock, makes an excellent hedge plant. 
 
 Fig. 87 
 
 Texas Okaxgk Tree 
 
 Kemember this book can discuss but a few important 
 fruits. Procure a good book on horticulture suited to 
 your section, and get your station bulletins and Depart- 
 ment publications. 
 
 QUESTIONS 
 
 Explain the main difference between. extensive and intensive farm- 
 ing. Give an example of very intensive cnltnre. Of extensive cul- 
 ture. Which is more intensive, cotton or corn? Why? Which is 
 more intensive, sweet potatoes or sugar cane ? What of the growth 
 
 Q 
 
226 ELEMENTS OF AGRICULTURE 
 
 of fruit and truck raising in tlie South? What advantage does the 
 truck farmer who lives in a community of truck farmers have over 
 one being in the business alone? What fruit is more largely grown 
 than any other in the South? How would you start a peach orchard? 
 How expensive is it to start an acre of peaches? How often do 
 j^eaches make good crops? Are they profitable? What can be done 
 with an orchard when trees are young? Why are peas objected to 
 for growing in orchards? Why would bur clover or vetch be better? 
 Why should you not grow anything in an orchard in a semiarid 
 country? How should trees be pruned? What reason is there for 
 thinning fruit on the trees? Why are apples not commercially im- 
 portant in the Gulf States? What are the conditions necessary to 
 grow winter-keeping apples ? What Southern States possess these ad- 
 vantages? Why is apple-growing a good business where conditions 
 are favorable? Tell what you know of the fig. How profitable may 
 fig-raising become? What advantages have figs over all other or- 
 chard ci'ops ? What suggestion is made to save figs from winter-kill- 
 ing to some extent ? 
 
 Where in the United States are most of the oranges, lemons, and 
 citrus fruits grown ? Where are the citrus fruits beginning to be 
 planted? Tell about the Satsuma orange and how it is propagated. 
 What part of the Southwest is destined to become a great citrus- 
 growing country? Tell something of pecan growing. 
 
 Suggestion. — Practice budding pecans, oranges, etc. Cut off 
 hickory limbs and tops in winter. Send for careful directions for 
 budding pecans in these next summer. It would be a great ac- 
 complishment if you could make nearly worthless hickories bear 
 fine paper-shell pecans. 
 
 Plant out a good number of fig cuttings. Start a small orchard, 
 preferably on the south side of buildings, fences, or other trees. 
 ]\Ianure trees highly, protect them from cold if necessary by tempo- 
 i-ary wind-breaks, and you will soon see what a profitable crop it is. 
 
CHAPTER XXXIII 
 
 TRUCK CROPS 
 
 Irish Potatoes. — li'i.sh potatoes are largely grown for 
 Northern markets. They need a good rich, warm soil, as 
 well as rapid working and artificial water supply where it 
 
 V„' 
 
 Fig. 88. — Harvesting Irish Potatoes 
 
 is feasible to provide it. On a good sandy loam soil, 
 potatoes should make their largest yields of good smooth 
 tuljers. Seed sliould be cut in rather large pieces, as has 
 
 227 
 
228 ELEMENTS OE AGRICULTURE 
 
 already been explained, so as to plant about twelve l)usliels 
 of seed to an acre. 
 
 Fertilizers. — About 800 pounds of fertilizer, containing 
 200 pounds cotton-seed meal, 500 acid phosphate, and 100 
 pounds nitrate of soda will generally assure a good crop. 
 This fertilizer should be put out and the land to be 
 planted bedded on it, or it should be sprinkled in the fur- 
 row with the seed potatoes. Very few soils are dry and 
 warm enough in the humid part of the South to justify 
 planting on a level. 
 
 Enemies. — The Colorado potato beetle is sure to attack 
 the crop. Weak solutions of Paris green will easily kill 
 this pest. When blight attacks the leaves, spraying with 
 Bordeaux mixture is desirable. To prevent scab!)}' po- 
 tatoes from being produced, the seed is often soaked in 
 a solution of formalin, one part of formalin to 300 to 400 
 of water, to kill any scab spores, or seeds of fungi, that 
 may be on the seed. 
 
 Yield and Profit. — A fairly good yield of potatoes is 
 100 to 150 bushels to the acre. When they bring 75 cents 
 to ^1 a bushel at the shipping station, good profits are 
 usually made. Sometimes the markets are too low to ship 
 at a profit. In that case, if the potatoes could be put in 
 cold storage and kept a month or more, a good demand 
 could be had at home. I>y midsummer all Southern pota- 
 toes are out of the market, and Northern potatoes are 
 being shipped South. 
 
 Second Crop. — Good crops of sweet potatoes, corn, cot- 
 ton, etc., can be grown on the Irish potato land after the 
 potatoes are dug, say in June. In growing a fall crop of 
 
THICK CROPS 229 
 
 potatoes, saving moisture enough and preserving the seed 
 are the greatest difficulties. The small potatoes of the 
 first crop are spread out in a good shade and partially 
 covered with straw or leaves. They are allowed to lie till 
 sprouts appear, and are generally planted whole. Cutting 
 will make them come up quicker, but they are liable to rot 
 when cut. The fall-grown crop makes good seed the fol- 
 lowing spring. 
 
 Hotbeds. — A hotbed is made by mixing stable manure, 
 cotton seed, etc., and surrounding this with a suitable 
 
 Fig. 8i). — Small Hotbed 
 
 frame and covering with glass as shown in Figure 89. 
 The rotting manure produces heat, and the sun's rays 
 enter through the glass, which at the same time pre- 
 vents the escape of heat from the bed. Some hotbeds 
 have flues underneath and are heated by fires. By 
 either plan, plenty of w^armth can be controlled to grow 
 any plant. 
 
 Tomatoes. — Tomatoes, eggplant, peppers, etc., are 
 started in January in the Gulf States. The tomato plants 
 are taken out of the hotbed about February and trans- 
 
230 
 
 ELKMKXTS OF A(;ilK:L'LTLllI-: 
 
 planted into a cold-frame. A cold-frame lias no heatiiiL;' 
 manure, and it is covered with clotii. The object is to 
 harden the plant as much as possible and at the same 
 time protect it and keep it growing. When all danger 
 of frost is over, the plants are taken from tlie cold-frame 
 
 Fig. 90. — Gathering Tomatoks 
 
 and transplanted to a field in checks about three by four 
 feet. The plants are kept tied up to stakes, as shown in 
 Figure 90. All the suckers are kept pinched off the 
 plants, and when they have grown about three feet high, 
 and have set a good crop of fruit, they are topped. Tlie 
 object is to force them to produce a good crop of fruit 
 early. If one wishes tomatoes for liome use or for can- 
 
TRUCK CKurs 
 
 231 
 
 niiig, it would be better to let the plants grow longer 
 and branch out and continue to bear.- 
 
 Enemies. — The cotton boll worm is hard on the tomato, 
 but generally a good early crop can be gathered before 
 the worm gets very abundant. Tomato blight is a much- 
 dreaded disease. The crop should be planted on a fresh 
 piece of ground each year. 
 
 Yield. — Tomatoes often produce 500 bushels to the 
 acre, and the crop is usually profitable. It does not re- 
 
 &^^MT£M^^^Z\>^- 
 
 Fig. 91. — Cabbage Field 
 
 quire such high fertilizing as cabbage and potatoes. 
 Three or four hundred pounds of fertilizer to the acre is 
 ample on ordinary sandy loam soil. 
 
 The largest tomato-growing places in the South are 
 Jacksonville, Texas, and Crystal Springs, Mississippi. 
 
 Cabbage. — - Early cabbage are sometimes started like 
 tomatoes in hotbeds and cold-frames. They are set out 
 in the field earlier tlian tomatoes, being set in three-foot 
 rows, at the rate of 8000 plants to the acre. Farther 
 
282 ELE.MEXTS OF AGKICLLTLUE 
 
 south they are often planted in open ground in September 
 or October and trans[)lanted from November to February 
 in the fields where they are to grow. Cabbages need rich 
 land or plenty of fertilizer or both combined. A ton of 
 fertilizer is often used to the acre. They need good culti- 
 vation. In the different sections of the Gulf States, 
 cutting and shipping take place from Marcli until June. 
 A fairly good crop is 100 crates, weighing about 120 
 pounds each, but often twice this amount is ])roduced. 
 One dollar a hundred pounds at shipping station is a 
 profitable price. The crop often bi'ings much more. 
 When prices are too low" for profit, cabbage can be kept 
 in cold storage as recommended for Irish potatoes. 
 
 Every ice factory should have a cold room to store crops 
 like this. A large and profitable business could easily be 
 built up in most localities in storing perishable vegetables 
 of this kind. 
 
 Onions. — Onion growing is a large and luci-ative busi- 
 ness, especially in Southwest Texas. Yields are fre- 
 (|uently as high as 500 to 800 bushels to the acre on rich, 
 well-fertilized and irrigated lands. Probably 300 bushels 
 is nearer the average. The onion seed are planted on 
 l)eds in September and October in little rows about three 
 inches apart. From December to February they are trans- 
 planted to the fields. The plants are placed in rows about 
 15 to 18 inches apart, and set as close as four inches in 
 the rows. It has been estimated to cost #30 an acre to 
 set onions in this way. 
 
 The crop is generally ready to harvest in May, and 
 is shipped in sacks to tlie Northern markets. Tiie onion 
 
TRUCK CROPS 23a 
 
 crop seldom nets tlie grower less than To cents a bushel 
 and frequently over a dolUir. 
 
 There are many other prohtable market crops, but tliey 
 cannot be discussed in this book without making it too 
 h)ng. Peas, beans, cauliflower, lettuce, radisli, peppers, 
 asparagus, celery, melons, and numerous other crops are 
 grown for the Northern market pr()fital)ly. Throughout 
 the Plains country particularl}^, as fine cantaloupes and 
 watermelons as ever grew can be raised in greatest abun- 
 dance. Melons have been considered for sugar production 
 on the Phiins, but the sugar beet also thrives tliere. Your 
 experiment station will refer you to good books and bulle- 
 tins that will give you tlie details of the culture and 
 handling of all of them. 
 
 QIESTIONS 
 
 AVhat sort of land is best for raising Irish potatoes? Do they 
 uped much fertilizer? What fertilizer mixture is suggested? Why 
 are potatoes not often planted on a level in the Soutli ? AA^hat 
 insect and what disease attack potatoes? What are the remedies for 
 tliese troubles? I low can scabby potatoes be prevented ? Tell what 
 the yield and value of potatoes should be. What suggestion is made 
 when the Northern markets are low ? AATiat crops can be made on 
 tlie Irish potato land after the potatoes are gathered? How are fall 
 Irish potatoes grown ? How are tomatoes planted ? Describe a hot- 
 bed. AVhat is a cold-frame? Howware tomatoes worked, staked, and 
 trimmed? Do they need heavy fertilizing? AVhat insect troubles the 
 tomato? AVhat fungous disease does the tomato suffer from ? AVhat 
 is a fair yield of tomatoes? AATiere are the largest shipping points 
 in the Southern States for tomatoes? How are cabbages started in 
 different sections? When are they cut and shipped? Do they need 
 heavy fertilizing? What is a good yield of cabbage and what is a 
 profitable price? What can be done with cabbage if Northern markets 
 get low? Tell something of onion growing. AA'hat is a good yield? 
 AVhat [)rices are received? Do they need high fertilizing? 
 
CHAPTER XXXIV 
 
 THE FEEDING OF ANIMALS 
 
 Animals made of Plants. — You leiiiiKMl in the first part 
 of this book tliat animals must \k' composed of the same 
 chemical elements as plants, because tliey are built up by 
 eating plants. If all tlie blood, lean meat, brain, tendons, 
 membranes, skin, hair, hoofs, and horns of animals could 
 be separated from the rest of the body and dried, tliey 
 would contain sixteen per cent of nitrogen. The cheese, 
 or curd of milk, when dry, also contains sixteen per cent 
 of nitrogen. No animal can live unless the substances 
 in its food furnish nitrogen. Fortunately, most natural 
 foods contain this element in small or large amounts. 
 The substances in food that contain nitrogen we call 
 proteifi, and, like the nitrogenous parts of the animal 
 body, protein contains sixteen per cent of nitrogen. 
 
 Protein Feeds. — The Avhite of an tdgg is pure protein. 
 Peas, beans, peavine hay, alfalfa liay, etc., are rich in pro- 
 tein, because, as you remember, these plants feed on 
 the nitrogen of tlie air, and they make this nitrogen into 
 the compound called protein. Cotton seed and cotton- 
 seed meal are A^ery rich in protein. No animal can give 
 a good supply of milk without plenty of protein in its 
 food. 
 
 Fat-making Feeds. — Animals must also have material 
 to make fat in their l)0(lies, and to make the butter fat of 
 
 234 
 
THE FEEDING OF ANIMALS 23;") 
 
 milk. Fat, or oil, in food, such as cotton-seed oil, can do 
 this, because all fats are made of three things — carbon, 
 hydrogen, and oxygen — whether they are vegetable fats 
 or animal fats. Protein can build fat, because it con- 
 tains carbon, hydrogen, and oxygen along with its nitro- 
 gen, but it is too expensive to feed so mucli of it. The 
 sugar, starch, gums, and woody parts of plants are also 
 made of carbon, hydrogen, and oxygen, and can build fat 
 in the body. Corn is about two-thirds starch, and you 
 know how it puts fat on hogs. 
 
 Heat and Force-making Feeds. — lint most of the food 
 eaten by animals is used to Ivcep tlicir bodies warm and to 
 produce force and work. It is burned up to keep the 
 machine hot and to keep it running. Sugar, starch, 
 gums, fiber, or woody matter in the foods are used for 
 this purpose. 'Hiese substances taken together are called 
 carho -hydrates. Fats in food can also be burned to keep 
 up heat and produce energy or work. You have heard of 
 tlie Esquimaux drinking fish oil to keep warm. Protein 
 can also be burned to make heat and force, but it is usu- 
 ally too expensive to be fed for this purpose. So we 
 see protein can do its own special work, and can also take 
 the place of fats aiul carbo-hydrates if necessary. 
 
 Ash and Water. — The ash of plants contains the mate- 
 rials for making bones. But as almost all feeds contain 
 plenty of ash, we need not further consider it. All feeds 
 also contain some water, but this is not necessary, since 
 animals can get plenty of water from the creek. So can 
 animals get plenty of water in feeds sometimes. In 
 the Hawaiian Islands thousands of cattle never drink anv 
 
23G ELEMENTS OF AGRICULTURE 
 
 water. They graze on high mountain hind where tliere is 
 much rain, but the rain sinks so fast in the volcanic soil 
 that none accumulates on the surface. The grass is quite 
 green and affords plenty of water. 
 
 Digestibility. — Of course, feed stuff, in order to nourish 
 animals, must be digested. Only from one-half to two- 
 thirds of hay is generally digested, and from three-fourths 
 to seven-eighths of grains and meals. An animal of a 
 given size needs a certain amount of digestible protein^ 
 cdiho-hydrates^ and fats to accomplish a particular result. 
 These are called nutrients. 
 
 Amounts of Digestible Nutrients Needed. — A milk cow, 
 a fattening steer, or a hard-worked horse may be said to 
 need each day about two pounds of digestible protein, 
 about twelve or thirteen pounds of digestible carbo- 
 hydrates, and about a half pound of digestible fats. More 
 protein, say up to three pounds a day, certainly would do 
 no harm, if not too expensive. Of course, large animals 
 or tliose giving large quantities of milk, need more, while 
 small animals, or those giving less milk, require less. 
 Animals not expected to work, gain in weight, or give 
 milk can get along on one-fourth this amount of protein, 
 and much less of the other nutrients. 
 
 Proportions of Coarse Feed. — Cattle will generall}^ 
 utilize food most economically, if given about two-thirds, 
 by dry weight, of coarse, bulky foods, such as hay and 
 fodder, and one-third concentrated feed, or eoneenf rates, 
 such as cotton seed, corn meal, cotton-seed meal, bran, etc. 
 Cattle on full feed will need about twenty-five to thirty 
 pounds of dry feed a day. Horses, when heavily worked. 
 
THE FEEDIN(; OF ANIMALS 
 
 should have at least half tlieir food by dry weight of con- 
 centrates, and the other half of roughage^ or roughness, 
 and should have about twenty to twenty-five pounds of 
 dry feed a day. All animals will eat larger proportions 
 of concentrated feed, if allowed to have it. Sheep, in 
 fattening, seem to do best on about half concentrated 
 
 Fig. 02. — Southwest Texas Steers being lAiiKMu. i-x Cactus 
 AND Cotton-seed Meal 
 
 and the other half rough feed. Hogs, when fattening 
 rapidly, eat still more concentrated feed than sheep and 
 horses. Young animals need more protein than older 
 ones, because they must build u}) lean meat and tissue. 
 They also eat more in proportion to live weight than 
 older animals. 
 
 Calculating Nutrients. — Cliemists analyze all the food 
 stuffs and lind out how much protein, carbo-hydrates, and 
 
288 ELEMENTS OF AGRICULTIRE 
 
 fats each contains. Actual trials liav^e been made of all 
 of them to see liow digestible they are when eaten by 
 different animals. If a certain feed, for instance, has 14 
 per cent of protein, and 75 per cent of this is digestible, 
 then we have .75 of .14, equals .105 (14 per cent multi- 
 plied by 75 per cent, decimally, gives 10.5 per cent of 
 digestible protein in the feed). If you want to feed your 
 milk cow 5 pounds of this feed a day, then you will give 
 her 5 times .105, or .525, pound of digestible protein. This 
 will be about ^ of what protein she needs, but if she has 
 a good pasture to run in, she may there get the rest of 
 what she needs. But if the pasture is not good, suppose 
 you give her 4 pounds of cotton-seed meal. It will con- 
 tain about 40 per cent protein, and about 85 per cent of 
 this will be digestible. Eighty-five per cent of 40 per 
 cent will be 34 per cent. Then 4 pounds times 34 per 
 cent (.34 pound) will make 1.36 pounds. This added 
 to what the other feed contained would be nearly 2 
 pounds. The pasture would have to be very poor, if this 
 much feed did not give the cow more than enough digest- 
 ible protein. Poor pastures, dry stalk fields, rough 
 woods, ranges, etc., may easily supply the carbo-hydrates 
 necessary. 
 
 Nitrogen-free Extract and Crude Fiber. — In analyzing 
 feeds for carbo-hydrates, the chemist divides these into 
 two groups, because one group is usually more digestible 
 than the other. The sugar, starch, gums, etc., he puts 
 into one group, which he calls nitrogen free extract. The 
 fibrous, woody part of the feed he puts into anotlier group, 
 which he calls crude fiber. A feed like hay or cotton- 
 
THE FEEDIXC; OF ANIMALS 289 
 
 seed hulls or straw contains mucli crude fiber and is 
 always bulky, and is not very digestible. A feed con- 
 taining much starch, like corn and sweet potatoes, or 
 sugar, like sugar beets, is very digestible, and hence more 
 valuable in proportion to dry weight than hay, hulls, and 
 straw. Nearly all feeds that have not gone through some 
 manufacturing process contain nitrogen-free extract and 
 crude fiber, as well as protein, fat, and ash. 
 
 Calculations. — If a grass hay contains 40 per cent 
 nitrogen-free extract, and 65 per cent of this is digestible, 
 then the hay contains 26 per cent digestible nitrogen-free 
 extract. If the same batch of hay contains 25 per cent 
 crude fiber, and 40 per cent of this is digestible, then it 
 will contain 10 per cent digestible crude fiber. After 
 crude fiber and nitrogen-free extract are both digested, 
 they are counted as having equal value. Therefore, we 
 add the two digestible amounts together, 2(3 per cent 
 nitrogen-free extract and 10 per cent crude fiber, and 
 call them carbo-hydrates, and we have 36 per cent digestible 
 carbo-hydrates in this hay. If you fed a cow 20 pounds 
 of such hay a day, you would give her 20 times .36 pound 
 of digestible carbo-hydrates, or 7.20 pounds in this feed 
 alone. If you have never had money enough to take any 
 interest in percentage and decimals, you have now found 
 tliat knowledge of this kind is needed in order to calcu- 
 late rations for farm animals. 
 
 If certain seed has 19 per cent of fat (oil), and 75 per 
 cent of this oil is digestible, then this seed contains 14.25 
 per cent digestible fats. If you feed 5 pounds a day to a 
 cow, you give lier in tlie seed alone about .71 of a pound 
 
240 
 
 ELEMENTS OF AGHICrLTURE 
 
 of digestible fat. Jf you have reviewed your deciuials 
 and percentage, you now have all the mathematics you 
 need to calculate suitable rations for live stock from the 
 following tables, which contain the digestible nutrients 
 in 100 [)()unds of each of our different common feed stuffs. 
 In the table the calculations for digestible nutrients are 
 made for us. Uy means of the last column in the table 
 you can always calculate the fertilizing value of the food 
 fed animals, and can closely estimate the value of manure 
 made. Wheat bran, cotton-seed meal, and other rich 
 feeds produce enough manure to go far toward paying for 
 the feeds. 
 
 TABLE Xo. 1 
 
 !)i;y Matiki:, Digkstiule XiiniKx i s. and Fehtilizixu 
 A'alik IX 100 POUNDS OF Fi:ki> .Stufp^s 
 
 Namk of Feed 
 
 Dry 
 Matter 
 
 Protein 
 
 Cauho- 
 
 IIVDRATES 
 
 Fat 
 
 Fertilizixc; 
 
 Value ix 
 
 100 Lbs. of 
 
 Feed 
 
 Grep:n Forage — 
 
 
 
 
 
 Cents 
 
 Pasture grass . . 
 
 20.0 
 
 2..10 
 
 10.20 
 
 0.50 
 
 10 
 
 Corn fodder . . 
 
 •20.7 
 
 LIO 
 
 L2.08 
 
 0.37 
 
 8} 
 
 Bermuda grass . 
 
 33.0 
 
 2.(50 
 
 1L80 
 
 0.30 
 
 10 
 
 Johnson grass 
 
 34.0 
 
 2.40 
 
 16..50 
 
 0.50 
 
 10 
 
 Japan clover . . 
 
 30.0 
 
 2.70 
 
 14.40 
 
 0.60 
 
 13 
 
 Crab grass . . . 
 
 33.0 
 
 1.90 
 
 U.OO 
 
 0.60 
 
 9 
 
 Soigluini . . . 
 
 20.6 
 
 0.60 
 
 12.20 
 
 0.40 
 
 .)\ 
 
 Alfalfa .... 
 
 28.2 
 
 3.90 
 
 12.70 
 
 1.00 
 
 nr 
 
 Covvpea .... 
 
 20.7 
 
 LSO 
 
 S.70 
 
 0.20 
 
 13 
 
 Soy l)eau . . . 
 
 24.9 
 
 3.20 
 
 22.00 
 
 1.00 
 
 16 
 
 Oat fodder . . . 
 
 .37.8 
 
 2.69 
 
 22.66 
 
 1.04 
 
 13 
 
 Rye fodder . . 
 
 23.4 
 
 2.05 
 
 14.11 
 
 0.44 
 
 10 
 
 Barley fodder . . 
 
 2L0 
 
 LOO 
 
 10.20 
 
 0.40 
 
 12 
 
THE FEEDING OF ANIMALS 
 
 241 
 
 Dry Matter, Digestible Nutrients, and Fertilizing 
 Value in 100 Pounds of Feed Stuffs — Continued 
 
 Name of Feed 
 
 Dry 
 Matter 
 
 Protein 
 
 Carko- 
 iiydrates 
 
 Fat 
 
 FEKTILIZIN(i 
 
 . Value in 
 100 Lbs. of 
 Feed 
 
 CtReen Forage — 
 
 
 
 
 
 
 {Cont.) 
 
 
 
 
 
 Cents 
 
 Wheat fodder . 
 
 36.0 
 
 2.80 
 
 18.00 
 
 0.90 
 
 11 
 
 Orchard grass 
 
 27.0 
 
 1.91 
 
 15.91 
 
 0.58 
 
 11 
 
 Red-top grass . . 
 
 84.7 
 
 2.06 
 
 21.24 
 
 0.58 
 
 11 
 
 Kentucky bhie 
 
 
 
 
 
 
 grass . . . 
 
 34.0 
 
 3.01 
 
 19.83 
 
 0.83 
 
 
 Teosinte . . . 
 
 25.0 
 
 2.40 
 
 13.50 
 
 0.20 
 
 11 
 
 Eed clover . . . 
 
 29.2 
 
 3.07 
 
 14.82 
 
 0.69 
 
 14 
 
 Bur clover . . . 
 
 25.0 
 
 2.60 
 
 17.00 
 
 0.50 
 
 12 
 
 Crimson clover . 
 
 19.1 
 
 2.40 
 
 9.10 
 
 0.50 
 
 11 
 
 Silage from — 
 
 
 
 
 
 
 Sorghum . . . 
 
 20.9 
 
 0.60 
 
 11.90 
 
 0.20 
 
 
 Corn 
 
 20.9 
 
 0.56 
 
 11.70 
 
 0.(35 
 
 9 
 
 Hay from — 
 
 
 
 
 
 
 Bermuda grass . 
 
 8(3.0 
 
 6.90 
 
 39.00 
 
 0.80 
 
 30 
 
 Johnson grass 
 
 85.7 
 
 6.00 
 
 41.40 
 
 1.20 
 
 30 
 
 Alfalfa .... 
 
 91.6 
 
 10.58 
 
 37.33 
 
 1.38 
 
 66 
 
 Cowpea .... 
 
 89.3 
 
 10.80 
 
 38.60 
 
 1.10 
 
 60 
 
 Hahy vetch . . 
 
 83.3 
 
 14.60 
 
 30.60 
 
 2.30 
 
 70 
 
 Red clover . . . 
 
 90.3 
 
 6.58 
 
 35.35 
 
 1.66 
 
 58 
 
 Peanut .... 
 
 92.4 
 
 6.70 
 
 42.10 
 
 3.40 
 
 60 
 
 Bur clover . . . 
 
 83.3 
 
 8.80 
 
 36.50 
 
 0.50 
 
 48 
 
 Crimson clover . 
 
 91.4 
 
 10.49 
 
 38.13 
 
 1.29 
 
 60 
 
 Crab grass . . . 
 
 86.0 
 
 4.30 
 
 36.40 
 
 1.50 
 
 25 
 
 Red-top grass . . 
 
 91.1 
 
 4.82 
 
 46.83 
 
 0.95 
 
 30 
 
 Hungarian grass 
 
 92.3 
 
 4.50 
 
 51.67 
 
 1.34 
 
 33 
 
242 
 
 ELEMENTS OF AGRICULTURE 
 
 Dry Matter, Digestible Nutrients, and Fertilizing 
 Value in 100 Pounds of Feed Stuffs — Continued 
 
 Name oy Feed 
 
 Dhy 
 Matter 
 
 Protein 
 
 Carbo- 
 hydrates 
 
 Fat 
 
 Fertilizing 
 
 Value in 
 
 100 Lbs. of 
 
 Feed 
 
 rL\Y FROM (Cont.) 
 
 
 
 
 
 Cents 
 
 Orchard grass . . 
 
 90.1 
 
 4.78 
 
 41.99 
 
 1.40 
 
 30 
 
 Timothy grass . . 
 
 86.8 
 
 2.89 
 
 43.72 
 
 1.43 
 
 25 
 
 Kentucky blue grass 
 
 78.8 
 
 4.76 
 
 37.33 
 
 1.95 
 
 26 
 
 Japan clover . . . 
 
 86.0 
 
 7.80 
 
 41.40 
 
 1.80 
 
 50 
 
 Shredded corn stover 
 
 80.0 
 
 2.30 
 
 43.20 
 
 0.90 
 
 20 
 
 Corn blades (fodder) 
 Corn shucks . . . 
 
 80.0 
 80.0 
 
 4.00 
 1.30 
 
 40.80 
 49.90 
 
 o.m 
 
 0.30 
 
 35 
 20 
 
 Cotton-seed hulls . 
 
 88.9 
 
 0.30 
 
 33.10 
 
 1.70 
 
 20 
 
 AVheat straw . . . 
 
 90.4 
 
 0.40 
 
 36.30 
 
 0.40 
 
 14 
 
 Oat sti-aw .... 
 
 90.8 
 
 1.20 
 
 38.60 
 
 0.80 
 
 21 
 
 Rye straw .... 
 
 92.9 
 
 0.60 
 
 40.60 
 
 0.40 
 
 16 
 
 Barley straw . . . 
 
 85.8 
 
 0.70 
 
 41.20 
 
 0.60 
 
 29 
 
 Roots and Tubers — 
 
 
 
 
 
 
 Sweet Potato . . . 
 
 28.9 
 
 1.00 
 
 22.50 
 
 
 
 Irish Potato . . . 
 
 21.7 
 
 0.90 
 
 16.30 
 
 0.10 
 
 — 
 
 Beets 
 
 13.0 
 
 1.21 
 
 8.84 
 
 
 
 Turnips 
 
 9.5 
 
 0.81 
 
 0.46 
 
 0.11 
 
 
 
 Rutabagas .... 
 
 11.4 
 
 0.88 
 
 7.74 
 
 0.11 
 
 
 Artichoke (elerusa- 
 
 
 
 
 
 
 lem) 
 
 20.0 
 
 2.00 
 
 16.80 
 
 0.20 
 
 
 Grains and Other 
 
 
 
 
 
 
 Seeds — 
 
 
 
 
 
 
 Cotton seed . . . 
 
 89.7 
 
 12.5 
 
 30.0 
 
 17.3 
 
 75 
 
 Cotton-seed meal . 
 
 91.8 
 
 37.2 
 
 16.9 
 
 12.2 
 
 150 
 
 Cotton-seed hulls . 
 
 88.9 
 
 0.5 
 
 33.1 
 
 1.71 
 
 25 
 
 Corn, field .... 
 
 89.1 
 
 7.9 
 
 86.7 
 
 4.3 
 
 33 
 
 Corn and cob meal . 
 
 84.9 
 
 4.4 
 
 60.0 
 
 2.9 
 
 
THE FEEDING OF ANIMALS 
 
 243 
 
 Dry Matter, DniESTinLE Nutrients, and Fertilizing 
 Value in 100 PorxDs of Feed Stuffs — Continued 
 
 Namk of Feki* 
 
 Dky 
 
 iMattkh 
 
 PUOTEIN 
 
 Carho- 
 
 IIYDKATES 
 
 Fat 
 
 Fertilizing 
 
 Value in 
 
 100 Lbs. of 
 
 Feeu 
 
 (i RAINS AND Other 
 
 
 
 
 
 
 Seeds (Cont.) — 
 
 
 
 
 
 Cents 
 
 Wheat 
 
 89.5 
 
 10.2 
 
 69.2 
 
 1.7 
 
 38 
 
 Wheat bran . . . 
 
 88.1 
 
 12.2 
 
 39.2 
 
 2.7 
 
 71 
 
 AVheafc shorts . . . 
 
 88.2 
 
 12.2 
 
 50.0 
 
 3.8 
 
 
 Wheat middlings . 
 
 87.9 
 
 12.8 
 
 53.0 
 
 3.4 
 
 65 
 
 Fvice 
 
 87.6 
 
 4.8 
 
 72.2 
 
 0.3 
 
 19 
 
 Rice bran .... 
 
 90.3 
 
 5.3 
 
 4.5.1 
 
 7.3 
 
 56 
 
 Rice polish . . . 
 
 90.0 
 
 9.0 
 
 55.4 
 
 6.5 
 
 45 
 
 Oats 
 
 89.0 
 
 9.2 
 
 47.3 
 
 4.2 
 
 41 
 
 Rye 
 
 88.4 
 
 9.9 
 
 67.6 
 
 1.1 
 
 38 
 
 Barley 
 
 89.1 
 
 8.7 
 
 65.6 
 
 1.6 
 
 
 Malt sprouts (dry) . 
 
 89.8 
 
 18.6 
 
 37.1 
 
 1.7 
 
 • 92 
 
 Brewers' grains (wet) 
 
 •21.:} 
 
 3.9 
 
 9.3 
 
 1.4 
 
 19 
 
 Brewers' grains (dry) 
 
 91.1 
 
 14.7 
 
 36.6 
 
 4.8 
 
 78 
 
 Linseed meal 
 
 
 
 
 
 
 (old process) . . 
 
 90.8 
 
 28.8 
 
 32.8 
 
 7.1 
 
 119 
 
 Linseed meal 
 
 
 
 
 
 
 (new process) . . 
 
 89.9 
 
 28.2 
 
 40.1 
 
 2.8 
 
 125 
 
 Cowpea, seed . . . 
 
 85.2 
 
 18.8 
 
 54.2 
 
 1.1 
 
 68 
 
CHAPTER XXXV 
 
 THE MAKING OF A RATION 
 
 Making up Rations. — Suppose you wisli a day's feed for 
 a horse of good size that is doing heavy work, and you have 
 oats, pea vine hay, and Bermuda hay. Ten pounds of 
 grain and 7 pounds each of the two hays would give 24 
 pounds of dry, or nearly dry, feed, and not far from half 
 of it will be grain. Let us make the calculation and find 
 out if this food will afford the right amounts of nutrients. 
 You see from Table Xo. 1 what amounts of digestible 
 protein, carbo-hydrates, and fats 100 pounds of oats con- 
 tain. You are to use 10 pounds of oats. Hence 10 pounds 
 will contain 10 per cent of all that 100 pounds contain. 
 Make a little table like Table No. 2 below. Find 10 per 
 cent of the protein in the 100 pounds of oats, and put 
 down in the column headed ''Protein." Do the same for 
 the carbo-hydrates and fats. You are to feed 7 per cent 
 of 100 pounds of each of the hays. Perform the same 
 operations for these. Then add each column. 
 
 By this method you get the total of each nutrient. 
 This is perhaps near enough the right amounts of nutrients 
 for all practical purposes. If, instead of ten pounds of 
 oats, six pounds of oats and four pounds of corn were 
 given, we should have almost exactly the standard 
 amounts of nutrients first named for a heaAdly worked 
 
 244 
 
THE MAKING OF A RATION 
 
 245 
 
 horse, a milk cow, iiiul a fattening steer. You should not 
 forget that a small horse, especially if doing liglit work, 
 will not need so much feed. 
 
 Fats Strong Feeds. — You have learned that fat performs 
 the same work in the animal body that is done by carbo- 
 hydrates. But the fat is stronger. A pound of digested 
 fat will produce as much fat in tlie body and make as 
 much heat and energy as two and a (juarter pounds of 
 digested carbo-hydrates. 
 
 TABLP: No. 2 
 
 
 Protein 
 
 Cakho-iivdhates 
 
 Fat 
 
 Ten pounds of oats contain 
 Seven pounds cowpea hay 
 
 contain 
 Seven pounds Bermuda hay 
 
 contain 
 
 .92 
 
 .756 
 
 .483 
 
 4.73 
 2.70 
 2.73 
 
 .42 
 
 .077 
 .0,56 
 
 Total 
 
 2.1.59 
 
 10.16 1 .553 
 
 Nutritive Ratio. — We hear a good deal of the nutritive 
 ratio of feeds. That means the proportion of digestible 
 protein in a feed stuff or in a ration to the digestible 
 carbo-hydrates and fats combined. Multiply the total fat, 
 .553 pounds, in the ration above, as shown in Table No. 2, 
 by 2.25; add the product to the total carbo-hydrates, 
 10.16, and this gives tlie carbo-hydrates and fats com- 
 l)ined. Then we have 2.159 pounds protein to 11.40-1: 
 })ounds of carbo-hydrates and fats. Divide both amounts 
 by the amount of protein, and we have 1 to 5.2, ap- 
 proximately. 
 
246 ELEMENTS OF AGRICULTURE 
 
 Balanced Ration. — A balanced ration is one in which 
 the proportion of protein to carbo-hydrates and fats is 
 about right for best results. One to five and two-tenths 
 is generally considered well balanced. Take the single 
 feed, corn, in Table No. 1. It has 66.7 pounds digestible 
 carbo-hydrates in 100 pounds; also 4.3 pounds fat, which, 
 multiplied by 2.25, gives 9.675. Add this to 67.7, and 
 we have 77.375. Divide by the protein, 7.9, and we have 
 a ratio of 1 to 9.8. This is too wide for most purposes. 
 That means that corn Avould not give best results as the 
 entire feed of an animal. 
 
 Make the same sort of calculation for cotton-seed meal, 
 and it will show about 1 to 1.2, which is very narrow. 
 Cotton-seed meal would never do as the entire feed for 
 cattle. If cattle run on dry pastures or stalk fields and 
 gather coarse food enough to make the necessary rough- 
 age and furnish needed carbo-hydrates somewhat to bal- 
 ance the cotton-seed meal, then it may be fed alone with 
 good results by properly limiting the quantity. If cotton- 
 seed meal and corn meal are fed together, they balance 
 each other, but all concentrated feeds must be limited in 
 the quantity fed. A mixture of these two feeds and some 
 hay or cotton-seed hulls for bulky feed may be fed with 
 good results. 
 
 Hogs and Sheep eat much Concentrated Food. — Hogs 
 eat from two to three times as much digestible food in 
 proportion to live w^eight as cattle. The food for hogs 
 must be more concentrated, but the proportion, or balance, 
 should be about the same. Sheep eat more digestible 
 food in proportion to live weight than cattle, and their 
 
THE MAKING OF A RATION 
 
 24' 
 
 food should have a larger proportion of concentrates. 
 The balance, or proportions, should be about the same as 
 for otlier animals. 
 
 Suitable Rations. — As suitable daily rations for a milk 
 cow the following are suggested to be divided and given 
 in two feeds : — 
 
 No. 1. 
 
 No. 2. 
 
 No. 8. 
 
 8 lbs. (or qts.) cotton seed. 
 10 lbs. prairie hay. 
 8 lbs. cotton-seed hulls. 
 2 lbs. (3 pts.) rice bran. 
 
 4 lbs. (4 jDts.) cotton-seed meal. 
 
 5 lbs. (7 pts.) rice bran. 
 
 20 lbs. cotton-seed hulls, or sorghum hay. 
 
 2 lbs. cotton-seed meal. 
 5 lbs. cotton seed. 
 
 3 lbs. wheat bran. 
 
 16 lbs. Johnson grass, sorghum, crab-grass, or 
 Bermuda hay. 
 
 Cows giving large amounts of milk should have more, 
 especially of concentrated feeds, and cows giving small 
 amounts less, than the above rations call for. The student 
 can make up many rations, and make necessary calcula- 
 tions to see if they will be suitable. 
 
 Variety of Food. — A general truth in animal feeding 
 appears to be that two or more foods fed in combination 
 with each other, or both fed during the same day, are 
 more digestible than either fed alone. It seems generally 
 
248 ELEMENTS OF AGRICULTURE 
 
 to pay to add extra feeds to a mixture for variety, even 
 when not necessary to balance tlie ration. 
 
 Additions to Fattening Rations. — It has been found in 
 all experiments in fattening steers on cotton-seed hulls 
 and meal that a little corn meal or rice polish or cheap 
 molasses added to the ration makes the steers fatten 
 faster and finish better. In fattening cattle on corn or 
 kafir corn with stover or hay for roughage, it has been 
 found that a little cotton-seed meal or cotton seed may 
 be very profitably added to the ration. These additions 
 always make the gains more rapid and raise the value of 
 the steers when sold. 
 
 Feeding Cactus. — The prickly pear of Southwest Texas, 
 which contains about nine-tenths water, and whose dry 
 matter has a ratio of probably one to fifteen, has been 
 profitably used to fatten beef cattle by adding cotton-seed 
 meal. Dairy cattle also give good results from eating the 
 prickly pear combined with cotton-seed meal and wheat 
 bran. Tliese concentrates balance the pear feed, and the 
 latter makes up the roughage. 
 
 Mixed Feeds. — Grinding and mixing feeds is a very 
 large business. About a half million tons of such feeds 
 are sold in Texas annually. Such feeds are usually worth 
 the money paid for them. Most states now have laws re- 
 quiring inspection and analysis of all ground and mixed 
 feeds offered for sale. These laws protect the buyers 
 against dishonest mixtures, and protect the honest manu- 
 facturers and mixers of feeds against unfair competition. 
 The laws requiring inspection of feeds and fertilizers are 
 of great value to the people. 
 
THE MAKlNCr OF A RATION 249 
 
 Condition Powders. — Tlie so-called condition powders 
 and foods, claimed to have high value on account of some 
 medicine contained, and sold at high prices, have been 
 found to have no more value than so much corn meal, 
 Avheat bran, and oil meal. It has been established that 
 liealthy animals or })oultry need no medicine, and that 
 they will be harmed rather than helped by it. It has 
 been found that cooking feeds has generally been harmful 
 rather than beneficial. Soaking, and especially souring, 
 feeds has been also unprofitable. 
 
 QUESTIONS 
 
 What do you understand by nutritive ratio V Go to the blackboard 
 and select any feed-stuff in Table 1 and calculate its nutritive ratio. 
 What is a wide ratio and what is a narrow ratio? What is a bal- 
 anced ration ? Can you pick out kinds and amounts of feeds in Table 
 1 that will constitute a balanced ration for a certain animal? How 
 uould Table 1 enable you to estimate the value of animal manures? 
 Of what advantage is it to give a number of feeds to animals? 
 AMiat feeds make profitable additions to cotton-seed meal and hulls 
 for feeding cattle? AVliat feeds are profitable to add to corn or kafir 
 corn and hay or stover in fattening cattle? What curious product is 
 fed in Southwest Texas? What does this feed need to balance it? 
 Tell about the mixed feeds so largely sold. What laws are needed to 
 control this business? Are condition powders and medicated foods 
 of any value ? Is cooking feeds usually profitable? 
 
 Experiment. — Suppose you try feeding a milk cow for a few days 
 in winter on corn meal and grass hay or hulls. This will be quite a 
 narrow ratio. Then try cotton-seed meal and the same hay and note 
 the difference in milk yield. 
 
 Calculate the fertilizing value of each ration proposed on page 217. 
 
CHAPTER XXXVI 
 
 ANIMAL DISEASES 
 
 Prevention of Sickness. — Every farmer should know 
 something of veterinary seience^ or how to prevent his 
 animals from getting disease, and how to cure disease, but 
 remembering " an ounce of prevention is worth a pound of 
 cure." Careful feeding and watering a horse, and not 
 driving him too fast after a full feed, will usually keep him 
 sound and well. If he is made sick by overfeeding, fol- 
 lowed by overwork, perhaps no amount of medicine will 
 care him. If fed when thirsty, he is likely to drink too 
 mucli water after eating and make himself sick. 
 
 Contagious Diseases. — Often the carcasses of horses 
 
 that have died of diseases like glanders and charbon serve 
 
 to spread these diseases. Vultures and dogs carry the 
 
 germs from the dead animals to where they infect healthy 
 
 ones. Tlie bodies of animals dying of contagious diseases 
 
 should be burned. Thousands of dollars' worth of fine, fat 
 
 cattle often die of a disease called hlaek-leg because the 
 
 owners neglect to get a vaccine virus and inoculate the 
 
 cattle. If horses and cattle are properly inoculated, they 
 
 become immune for about a year to charbon, a deadly 
 
 disease often ravaging tlie large river delta sections of the 
 
 Gulf States. Many years ago cattle brought from the 
 
 North, or from the elevated West, to the lowlands of 
 
 the South, almost always died of Avhat people call accli- 
 
 250 
 
ANIMAL DISEASES 251 
 
 mation fever. The cattle that had never had ticks got 
 ticks on them and took the disease we now know as Texas 
 feve}% or tick fever, and died. The Southern cattle driven 
 North or West left a deadly trail that killed all Northern 
 cattle crossing it. It is now known that the Southern 
 cattle dropped ticks from their bodies, and these ticks got 
 on the native cattle, and gave them the deadly fever. 
 
 It has been found that even in South Texas, Louisiana, 
 or Georgia, cattle raised by being tied out on cultivated 
 land never have an}^ ticks, and if ticks get on them, they 
 die as readily as Northern cattle. It has also been found 
 that young calves may get the ticks on them without 
 being harmed, and they become immune. That is, they 
 are free from taking the disease, just as you are free from 
 the danger of measles after having had it once. 
 
 Inoculating against Tick Fever. ■ — It has been more 
 recently found that if Northern cattle are inoculated 
 when brought South, they have only a mild case of 
 Texas fever, and usually recover. The inoculation con- 
 sists of simply iujecting into their veins a little of 
 the blood of native cattle that have had ticks. Many 
 thousands of Northern cattle brought into South Texas 
 for breeding have been immunized in this way during the 
 last ten years. The Veterinary Department of the Texas 
 Agricultural and Mechanical College has taken a leading 
 part in the interesting scientific investigations that have 
 been so helpful in controlling the Texas fever. 
 
 Quarantine Line. — The Department of Agriculture 
 at Washington indicates the northern limit of the cattle 
 tick by a crooked line running across the country from 
 
252 ELEMENTS OF AGRICULTURE 
 
 the Atlantic coast in North Carolina to the Mexican 
 border of West Texas. This line turns south as it be- 
 gins to approach the elevated plains in Texas. The last 
 Congress made an appropriation to be used in destroying 
 the tick. Active efforts are in progress in almost all the 
 Southern States to kill out the tick in the more northerly 
 sections of the infested district. The tick's only means 
 of living is the blood which it sucks from cattle. There- 
 fore, if all cattle are removed from a pasture for two 
 or three months in summer, all the ticks in that pasture 
 Avill die of starvation. So, by merely dividing the pastures 
 and changing the cattle from one to the other, the tick 
 can be killed out. 
 
 The people have stock laws in all sections adjacent to 
 the quarantine line, so that no cattle are allowed to run 
 at large. Whenever the Department at Washington finds 
 that a county is rid of ticks, the quarantine line is moved 
 that much farther south. In this way the free zone is 
 from time to time being enlarged. 
 
 Advantage of living above Quarantine Line. — To be 
 above the quarantine line is a matter of great advantage 
 to the cattle raiser. He can ship breeding stock to or 
 from any part of the North. But his greatest advantage 
 is that he can ship cattle to any part of the North or West 
 for grazing and feeding. Tlie best grazing is found and 
 most of the feeding is done north of the quarantine line. 
 This makes a demand for cattle that enables the farmer 
 above the line to get good prices. The man south of the 
 line cannot ship his cattle north of it, except for immediate 
 slaughter. This, of course, compels him to sell at a lower 
 
ANIMAL DISEASES 258 
 
 price. Therefore all counties and districts joining the 
 line should cooperate in an effort to kill out the tick and 
 move the quarantine line south of them. 
 
 Hog Cholera. — Hog cholera is often carried by a creek 
 or stream from an infected farm to another farm below. 
 Hogs dying of disease shonld be burned to prevent dogs 
 and vultures from carrying the germs of the disease to 
 other lots or other farms. If an outbreak cannot be 
 prevented by quarantine and sanitary precautions, the 
 best tiling for the farmer to do is to divide up his herd 
 into several lots, putting them on high ground, if possible, 
 and carefully removing all sick animals. Medical treat- 
 ment is of little avail in case of hog cholera. Inoculation 
 as a preventive or cure has not yet been successful. 
 
 People used to have very many absurd ideas about 
 animal diseases and their treatment. It used to be very 
 common to see cows and oxen with a number of little 
 holes bored in their horns. This was done to cure a 
 supposed disease called hollow-horn. There is really 
 no such disease, and the cattle got well in spite of the 
 boring. Another supposed disease was hollow-tail, and 
 many cattle had their tails split open and salt and 
 pepper and other remedies put in under the skin. This, 
 too, was worse than useless. Then cows were supposed to 
 lose their "cud," and salt dish-rags were crammed down 
 their throats as a substitute for the "cud." Horses had 
 "hooks" cut out of their eyes, had their mouths burned 
 for lampers, and received other kinds of brutal treatment 
 for real or imaginary diseases. 
 
 These notions about animal diseases are only a little 
 
254 ELEMENTS OF AGRICULTURE 
 
 less foolish than those held by the old negro woman who 
 rubbed fresh milk on a cow's back to get the devil out 
 of her. See Appendix for treatment of animal diseases. 
 
 QUESTIONS 
 
 What precautions should be taken to prevent sickness of horses ? 
 AVhat should be done to prevent spread of contagious or infectious 
 aiiinial diseases? What diseases can be prevented by inoculation? 
 What causes acclimation fever? What is Texas fever and how is 
 it spread? What causes death of Northern cattle grazing on land 
 that Southern cattle pass over ? What can be done to save Northern 
 cattle when brought South? What is the quarantine line? Is this 
 line moved from time to time ? Is it more profitable to have cattle 
 north of this line or south of this line? Give reasons. How is hog- 
 cholera spread ? What are some of the foolish notions people have 
 about animal diseases ? 
 
CHAPTER XXXVII 
 
 ANIMAL HUSBANDRY 
 
 Growing Live Stock and Live-stock Products. — Prob- 
 ably very mucb more than half of the products of the 
 farms of the country is converted into animal products 
 before final consumption. People cannot eat grass 
 and hay and cotton seed as such, but when these prod- 
 ucts are converted into juicy beefsteak, tender mut- 
 ton-chop, or golden butter, who could wish anything 
 better ? All the produce of pasture and meadow lands, 
 virtually all the corn and oats produced, the by-products 
 of wheat, barley, rice, sugar-cane, sugar-beet, cotton-seed, 
 etc., pass into animal products before they are used by 
 human beings. Even some animal products, like dried 
 blood, tankage, meat-scraps, bones, skim-milk, etc., are 
 fed to poultry, hogs, or other animals, and re-converted 
 into animal products. 
 
 Animal Machines. — ^In one sense, raising live stock 
 may be considered as a manufacturing process by which 
 bulky, nearly worthless farm products may be converted 
 into valuable concentrated or refined products. A ton of 
 gold-bearing ore having i5 worth of gold in it could not 
 be easily handled or shipped ; but put the ore through the 
 great crushers and smelters and get the $b in gold out, 
 and it will not cost one per cent of its value to send it 
 to St. Petersburg or Tokyo. We might have a ton of hay 
 
 255 
 
256 ELEMENTS OF AGRICl-LTURE 
 
 on a farm ten miles from a railroad, and it would not 
 bring enough to justify baling and hauling, but we run it 
 through our condensing machine, the steer, and it turns 
 us out 100 pounds of beef and a good lot of manure to 
 enrich the land. The by-product, the manure, is of course 
 too heavy and too low in value to market, but the main 
 product is valuable enough to ship to Chicago or London. 
 Our condensing machine carries it to the railroad and 
 loads it on the cars. 
 
 Another good thing about these living machines is that 
 theyare self-oiling and gather so mucli of their oavu raw 
 material. They gather grass and weeds and brush that 
 we could not afford to cut and save, and make them into 
 goods of high value. 
 
 Improved Machine. — But we have another highly im- 
 proved condensing machine that deserves to be patented. 
 By consuming a ton of hay, or its equivalent, in suitable 
 mixtures with other food, this machine will turn out for 
 us fifty pounds of fine butter, worth seven or eight times 
 as much a pound as the beef. We can afford to ship this 
 product anywhere by express, but for fancy prices we need 
 not ship it farther than our Southern cities. 
 
 Other Machines. — The sheep and angora goat convert 
 food into wool and mohair, valuable products that will keep 
 indefinitely. 
 
 The most rapid-working four-legged machine we have 
 is the hog. It will make probably as much meat out of 
 ten pounds of feed as the steer will make out of thirty 
 pounds, but the hog cannot use as coarse raw material as 
 is used by the other animals mentioned. We would not 
 
ANIMAL HUSBANDRY 257 
 
 like to eat grasshoppers, bugs, worms, and snails, as poor 
 Chinese and Japanese children do. But Ave have a small, 
 cheap farm-machine that does not have to be run even by 
 hand, which converts all of these things into little pack- 
 ages of rich, palatable human food, sealed up into little 
 air-tight cases, or cans. Can you name this machine ? 
 
 Machines for Work. — Somewhat as we feed coal and 
 wood into a traction engine and get work, we feed hay 
 and oats and corn into our horses and mules and get work. 
 As the best corn, oat, and hay lands have increased in 
 value to ^75 and rf 150 per acre, and as horses and feed 
 stuffs have risen in value, as a necessary consequence of 
 high land values, people are casting about to see if they 
 cannot plow with traction engines more clieaply than with 
 horses. But the horse has risen in value in spite of trolley- 
 cars, automobiles, and bicycles, and we shall continue to 
 find use or sale for all o'ood horses and mules we can raise. 
 
 QUESTIONS 
 
 Ts much of the pTOcluce of the land converted into animal products? 
 What substances unfit for human food may be converted into excel- 
 lent hunum food by feeding to animals? Are any animal products 
 converted into other animal products? What comparison is made of 
 a steer to a machine ? AMiat does tlie cow use as raw materials and 
 what products does she turn out? AVhat do sheep and angora goats 
 consume and what products are given ? What machine works most 
 rapidly in proportion to size ? What machine tnrns out canned food? 
 What product does the horse return? Do high land values make 
 high-priced feed stuff? Can people plow economically with steam- 
 power ? 
 
 Experiment. — Use score cards in Appendix and practice judging 
 horses and cattle. 
 
CHAPTER XXXVIII 
 
 RAISING HORSES AND MULES 
 
 Horses on the Plains. — -Horses thrive remarkably Avell 
 on the Plains and in the dry elevated sections of the great 
 AVest. They seem to winter on the ranges even better 
 than cattle, and horses raised in that section certainly have 
 muscle, bone, and endurance equal to any horse Arabia or 
 the Barbary States ever bred. But the land on these 
 plains is rapidly getting too high-priced for exclusive graz- 
 ing purposes. The five to ten acres of land necessary for 
 keeping a grown animal a year does not yield a net in- 
 come of more than fifty cents an acre, or about enough 
 to pay a reasonable interest when the land is worth five 
 dollars an acre. But since these lands for a good distance 
 west of the 100th meridian of longitude have passed the 
 five-dollar valuation mark, ranches are being rapidly cut 
 up and sold for farms. So the horse of the future and the 
 cow of the future must be raised more and more under 
 farm conditions and less and less under range conditions. 
 
 On the Farms. — To raise horses with the most profit 
 on the farm, plenty of good home-grown feeds and good 
 rich pastures must be provided, and the mares must be 
 made to earn their living by doing farm work. Mares, 
 in order properly to nourish their young, should have rich 
 milk-producing foods, like clover, alfalfa, peanut, or pea- 
 
 258 
 
RAISlNCi HOUSES AND MULES 
 
 259 
 
 vine hay, oats, and wheat bran. A colt pushed ah)ng with 
 proper nourislnnent will not only make a larger horse, but 
 will reach a marketable size a year sooner. 
 
 Pure-bred Horses. — It is not desirable that most men 
 should undertake to raise pure-bred horses. While pure- 
 
 Fk;. <);>. Coach Type 
 
 Ijred horses, or mixed-blooded horses of special types for 
 special purposes, will find buyers at extra good prices, the 
 majority of farmers are not ready for special-purpose 
 horses. Most farmers are not so specialized in their busi- 
 ness as to want a heavy draft horse for hauling, a carriage 
 
2(33 
 
 ELEMENTS OF AGRICL'LTrilE 
 
 horse, and a fancy saddle horse. They must, for the most 
 part, use horses of general-purpose qualiiies, or mules, 
 which are hard to surpass as general-purpose animals. 
 
 &k 
 
 
 
 w, 
 
 
 f 
 
 <. ,-*"f ^ 
 
 ^wsssF3WP5^ir'-^ 
 
 
 i|2 ' 11^' '^ ^s^^n^U^I^^H 
 
 1 
 
 
 1 1 
 
 t 
 
 ^yfi^^/l^ -ti^ "*■' Jm 
 
 
 ' 
 
 1 
 
 .c; ^ •. ' "-'^;-?si^.?si 
 
 
 
 
 
 
 ^./^/■' 
 
 ■i 
 
 Fig. \U. — Draft Type: Pkuchkuox 
 
 Under present conditions raising good liorses and mules 
 ought to be very profitable. We raise a thousand-pound 
 steer, fatten him, and sell him for five cents a pound, if 
 
RAISING HORSES AND MULES 261 
 
 he is an especiiilly good one. A good mule of tlie same 
 weight would easil}^ bring fifteen cents a pound ; and if 
 the mother earns her feed on the farm, the cost of raising 
 the mule could hardly exceed the cost of raising the steer 
 by more than two or three cents a pound. We have seen 
 that horses eat no more each day than cattle, that their 
 food is not very much more expensive, and we know 
 horses and mules grow about as fast as cattle. 
 
 Classes and Breeds. — The classes of horses are the draft 
 breeds composed of heavy, large-boned, slow-moving types, 
 weighing from 1500 to 2200 pounds ; the coach, or car- 
 riage, types of stylish-looking horses, weigliing from 1200 to 
 1400 pounds, that hold their lieads high, pick up their feet 
 well, and combine streiigth with good speed and style ; 
 the light types, including the English race-horse, the 
 American trotter, the near relative of the racer, and the 
 American saddle horse, rather closely related to the last 
 two. Then there are the ponies, such as broncoes, or 
 mustangs, Indian ponies, etc., and the Shetlands. 
 
 There are many breeds of draft liorses, including the 
 Percheron, Clydesdale, Belgian Draft, French Draft, 
 English Shire, and otliers. The coach breeds are the 
 Cleveland Bay, French Coach, German Coach, and others. 
 There is much interest in the United States just now in 
 developing new breeds of horses in America that will 
 meet the needs of the country better than existing breeds, 
 nearly all of European development. The Department of 
 Agriculture at A¥ashington is undertaking this work. 
 Interest is reviving also in the Morgan horse, certainly 
 one of the best general-purpose horses ever known. 
 
262 ELEMENTS OF AGRICULTURE 
 
 See tlie Appendix for diseases of the horse and the reme- 
 dies for these diseases. 
 
 QUESTIOXS 
 
 Whei-e do horses thrive under range conditions? What is the 
 reason horses and cattle must be raised still more largely on the 
 farms? What sort of feeds must mares have properly to nourish 
 their^colts? Can farm mares work and raise good colts? Do most 
 people need pure-bred horses of some type? What kind of horse 
 suits most men, a special-purpose or a general-purpose horse? \^''hat 
 comparison is made of the costs and selling prices of steers and mules? 
 What types of liorses are named? What breeds belonging to each 
 type? What efforts are being made to develop new breeds? 
 
CHAPTER XXXIX 
 
 CATTLE 
 
 Cattle are now kept for two main purposes, for pro- 
 ducing beef and for producing dairy products. The time 
 has been that cattle, like the buffalo of the plains, were 
 slaughtered for their hides and tallow. In early times, 
 cattle were kept for work, and this is still to some extent 
 true. 
 
 Fig. 95. — Zebu, or Sacred Bull of India 
 
 Sacred Cattle. — A different species of cattle is found in 
 India, Java, Borneo, and the Soutli Sea Islands. Some of 
 these are said to be taller than our largest horses, and 
 some, the little trotting bulls of ('eylon, to be not over 
 three feet liigh. A vast number of cattle is raised in the 
 Chinese Empire, and, so far as tlie author has seen them, 
 
 263 
 
1>(U ELEMENTS OF AGRICULTURE 
 
 thej appear to be a cross between the Zebu cattle and the 
 European cattle. Some East Indian cattle have been 
 brought to Texas, Louisiana, and Mississippi. They are 
 very hardy, free from disease, arc bitten but little by 
 ticks, and they make fine work cattle and good beef. 
 
 Classes and Breeds of Cattle. — ^Our European races of 
 cattle have been bred into more or less distinct types for 
 different uses, and these types into different breeds, each 
 with' its own special characteristics. We have beef cattle, 
 general-purpose, or dual-purpose, cattle, and dairy cattle. 
 The principal l)reeds of beef cattle are tlie Shorthorns, 
 Herefords, Aberdeen Angus, and Galloways. The dual- 
 purpose cattle are natives, Devons, Red Polls, and some 
 strains of Shorthorns, or Durhams as they are sometimes 
 called. Dairy cattle include Jerseys, Guernseys, llol- 
 steins, and Ayrshires. The Jerseys and Guernseys give 
 rich milk, wdiile the Holsteins and Aj^rshires give larger 
 quantities of poorer milk. 
 
 Dual-purpose Cattle. — A large number of American 
 farmers do not wish cattle that are higldy specialized or 
 useful mainly for one purpose. They wish what some 
 term diial-pm-pose cattle; that is, cattle that are fairly 
 good for dairying and fairly good for beef. It is probably 
 not true, as some have contended, that such cattle are 
 necessarily less profitable than special-purpose cattle. 
 Neither is it true that pure-bred cattle are necessarily 
 more protitable for all people than native cattle or grades. 
 It is seldom that any good quality is secured and fixed in 
 a race of live stock without the loss of some other desir- 
 able quality. 
 
CATTLE 
 
 2t5n 
 
 Value of Breeding in Beef Animals. — First. The beef 
 breeds of cattle grow larger than native eat tie, [)artieularly 
 tlie native cattle found in the South. 
 
 Second. Beef-bred cattle always dress, out a higher 
 percentage of beef for a given live weight than native or 
 
 Fig. <)(). — Dual Purpose Cattle 
 Devon Bull above Red Polled Cow below 
 
 dairy-bred cattle equally fat, — in a large niunber of experi- 
 ments as much as two to ten per cent. 
 
 Third. The dressed carcass of a l)eef-l)red steer con- 
 tains less tallow, wliicli is a low-priced product, than the 
 carcass of a dairv-bred steer. 
 
2m ELEMENTS OF AGRICULTURE 
 
 Fourth. In a number of tests made by the experiment 
 stations, the loin steak and rib roast of the beef -bred 
 steers have been judged to have a higher value, than the 
 same cuts from steers from dairy or scrub cattle. In other 
 tests no difference in value of these cuts was made. 
 
 Fifth. It is generally held by butchers and packers 
 that beef -bred cattle produce meat with the fat and lean 
 better mixed than is the case with other cattle. There is, 
 therefore, probably a difference in value in favor of the 
 carcass of the beef-bred steer, which has not always been 
 taken into account by experimenters. 
 
 Sixth. Tlie highest grades of all products come nearer 
 bringing full values than common grades. All slaughter 
 tests made by the stations indicate that meat packers 
 make more profit out of dairy-bred and common cattle 
 than they do out of the better grades. The unifoi-m 
 colors and better appearance of the latter doubtless help 
 them to bring fuller values. 
 
 Fine Stock not Rustlers. — riie sliort-horn and Holstein 
 cattle have been fed and bred to produce large frames 
 and great weights. Yet they are the i)oorest rustlers of 
 our breeds of cattle. Many farmers, not knowing this 
 peculiarity, have expected their short-horn cattle to rustle 
 like native cattle, and have been disappointed to see their 
 fancy cattle die or become tlie poorest cattle in the neigh- 
 borhood. 
 
 The average farmer of the South, who is generally not 
 a stockman, often buys broad-backed, pure-bred hogs, and 
 turns them into the wood-lot to ''root, hog, or die." If 
 the hogs survive, they soon degenerate into thin, ugly 
 
CATTLE 
 
 -H\' 
 
 Fig. 97. — Beef Cattle 
 
 (Irade Shorthorn Steer above 
 (jrrade Hereford Steer below 
 
268 ELEMENTS OF AGRICULTURE 
 
 razor-backs. Every farmer should be impressed with the 
 fact that tine stock requires extra care, and that feed 
 counts for far more than breed. 
 
 Pure Animals gain no More for Feed eaten than Scrubs. 
 — There is at present a very prevalent but erroneous im- 
 pression that a bushel of corn will produce more growth 
 when fed to a pure-bred beef animal than wlien fed to a 
 dairy-bred animal or native. Surely, if breeding has im- 
 l)roved the appetite and digestion of beef animals, the 
 same sort of breeding must have been pursued with dair}- 
 animals, because milk cows eat and digest large amounts 
 of food. 
 
 It has been demonstrated again and again that an ani- 
 mal of no one breed or type eats any more, digests any 
 better, or gains any faster than an animal of any other 
 l)reed or type, when both are of the same size and condi- 
 tion at the time the test is made. It has also been proved 
 that animals of no fixed breed or type — natives — eat as 
 much, digest as well, and gain as fast as animals of fixed 
 types or breeds, if all are of the same age, size, and condi- 
 tion when the feeding test is made. To verify these as- 
 sertions, readers are referred to Henry's ''Feed and 
 Feeding,'' page 37-1:: Iowa Bulletins, 20 and 81; Kansas 
 liulletin. 111; INIinnesota, No. 73: Wisconsin, No. 104; 
 and Mississippi, No. 76, all of wliich bear on the subject. 
 
 Early Maturity. — It is commonly claimed that pure- 
 bred, meat-jfroducing animals mature earlier than the 
 other animals. If maturing earlier means to get grown 
 quicker, it is an erroneous claim. The truth seems to be 
 that a Jersev calf, beiuQf smaller Avlien l)orn tlian a sliort- 
 
CATTLE 2(39 
 
 horn calf, does not eat quite so mueli or grow quite so 
 fast as a shorthorn. If, then, both ealves are fed all they 
 can eat, the Jersey would probably grow larger than is 
 usual with that breed, but, being all the time a little 
 smaller than the shorthorn, eats a little less, gains a little 
 more slowly, and reaches maturity at about the same 
 time. 
 
 If early maturity is understood to mean a tendency to 
 get fat at an early age, it is certain a beef-bred steer will 
 not fatten at an earlier age than a Jersey, if both are fed 
 equall}^ well. If early maturity is understood to mean 
 that the fiesli of the beef-bred steer will be of better 
 quality, or riper, at an early age, than the flesh of the 
 dairy-bred or native steers, it is generally believed that 
 this is true. 
 
 Cattle in Texas. — The state of Texas has more cattle 
 than anv other state in the Union, somethiup^ over eieht 
 million head, or about one to ever}^ twenty acres. In cer- 
 tain rich districts of Holland, Denmark, and Belgium one 
 cow to the acre may be found, but food must be imported 
 to help feed these cattle. 
 
 Cattle enrich Land. — ^If Texas depended on feeding 
 cattle to enrich the land, as some countries do, the one 
 cow to twenty acres would hardly manure the gardens 
 and truck patches. It is said that the present dairy dis- 
 tricts of Wisconsin were formerly grown in wheat until 
 the land became so exhausted that the people, being no 
 longer able to make a living by raising wheat, turned 
 tlieir attention to dairying. They are again unable to 
 raise wheat profitably, but it is because the soil has be- 
 
'>H) 
 
 ELEMENTS OF AGKICUJ/rUKE 
 
 come so excessively rich as to cause the straw to grow 
 too tall, so that it falls down, or ''lodges." 
 
 Cattle and Rotation. — In many sections where cattle 
 and other live stock are regularly kept on farms, pastur- 
 ing has been generally introduced as a part of the rotation. 
 I>ut in the South the lands are so often irregular in 
 (piality that those which are not suited for cultivation 
 ai'c usually selected for pasture. By keeping cattle in 
 
 n 
 
 ^i 
 
 it -^"'k- 
 
 
 ^.^.: 
 
 VppPMMT ^^^^■Wb"' 
 
 b -.. :- 
 
 
 
 
 
 Fig. 98. 
 
 S MOWING Bkef Cattle at Texas Agricultural and 
 Mechanical College 
 
 barns only a very small part of the year, and allowing 
 them to run in pastures not belonging to the farm proper. 
 Southern farmers get far less value from the manure than 
 the Northern farmer, who stables and feeds his cattle for 
 six months in winter, and pastures them on a part of the 
 farm land in summer. 
 
 Poor Stock due to Poor Land. — The poorest cattle in 
 the United States, perhaps, are those raised on the pine 
 meadows of Florida. West of this, along the pine flats 
 
CATTLE 271 
 
 of Georgia, Alabama, Mississippi, and along tlie coast 
 prairies of Louisiana and East Texas, the cattle are still 
 small and inferior, and grow slowly. And the hogs in 
 these sections, when left to get their living from the woods 
 and forests, are thin, ngly little razor-backs. This gen- 
 eral inferiority of the live stock is not entirely, or mainly, 
 due to poor breeding, as most people say. The grasses 
 that grow on poor land in wet, warm countries are coarse 
 and innutritions. Tlie scanty, poor food for hogs is so 
 scattered and difficult to find, and requires so much 
 traveling and rooting, tliat no other type of hog would 
 find enough to live on. 
 
 As we go west along the coast prairies and reach the 
 rich river deposits, we find much better cattle. Still 
 farther west, we reach drier, richer land and better 
 cattle. North and northwest, we have still better cattle, 
 regardless of breeding, although the cattle are generally 
 better bred. 
 
 When the small cattle of the coast marshes of Louisi- 
 ana and Texas are given a year or two of grazing on the 
 nutritious grasses of the Panhandle, they approach the 
 well-bred Hereford grades in flesh, shape, and quality. 
 
 Rich Land, Rich Food. — It has been suggested that 
 the Texas fever tick produces in the blood of Southern 
 cattle a slow, constant poison that keeps them from grow- 
 ing and gaining fast like Northern cattle. While this is 
 probable, the difference is due more to difference in the 
 richness of land, and conse(|uently in tlie nutritive 
 qualities of the feed. It is well known that grass grown 
 on land rich in nitrogen will be generally richer in protein 
 
272 ELEMENTS OF AGRICULTURE 
 
 than grass grown on poor land; also that grass grown on 
 land rich in lime is much richer in l)()ne-making material 
 than that grown on poor, sandy land. It is well known 
 that the richer any grass is the more digestible it is. 
 Cattle living on coarse marsh grass must eat a large bulk 
 of it to get even scanty nourishment, and they grow big- 
 bellied and appear to have small quarters. With two 
 years of grazing ricli Northern and Western grasses, these 
 cattle become round-bodied, respectable-looking animals. 
 
 Again, when cattle far south are well fed on cotton- 
 seed meal and hulls, corn-meal, rice-bran and polisli, black- 
 strap molasses, and other rich foov], they gain weight 
 rapidly and become in shape and quality not greatly in- 
 ferior to Nortliern cattle, equally well fattened. 
 
 Dairy Cows. — Very few direct tests for milk and bntter 
 have been made of herds of dairy-bred cattle as compared 
 with scrub cattle. Individual cows of all breeds yar}'- 
 so much in the amount of milk and butter they give that 
 it would be exceedingly difficult to secure very definite 
 results as to the relative producing ca[)acity of the dif- 
 ferent breeds. The tests of the dairy-breeds against each 
 otlier have been very unsatisfactory. These tests have 
 not proved one breed more valuable than another. 
 
 The truth is, one breed is best for one man in one 
 location, and another breed is best for another man in 
 another location, and so on, and the differences are prob- 
 ably not great in any case. Still other men would do 
 best with a general-purpose, or dual-purpose, cow, whether 
 of a distinct breed or not. 
 
 One station in testing the best types of cows, as sliown 
 
CATTLE 278 
 
 on page 288, against beefy types of cows, found, in ex- 
 treme cases, that the butter made from the latter costs 
 fifty per cent more in food eaten than the butter made 
 from the former. It must be borne in mind that some 
 natives, dual-purpose cows, Shortliorns, and even Here- 
 fords, will be better dairy cows than some Jerseys and 
 Hoi steins, but as a rule better dairy cows will be found in 
 the dairy breeds. 
 
 There will be found good cows and poor cows in all 
 breeds. Average cows of all breeds are perhaps hardly 
 profitable as dairy animals ; yet by rigid selections profit- 
 able cows can be obtained from all breeds. Pure-bred 
 animals do not make up one per cent of all animals in the 
 South. Therefore, in selecting a dairy herd, one has so 
 many native and grade animals to choose from, that he 
 may easily gather from among these an excellent herd. 
 Grading up native and grade herds by the use of pure 
 bulls of dairy breeds is the plan followed by most success- 
 ful dairymen. 
 
 See Appendix for diseases of cattle and their treatment. 
 
 QUi:STIOXS 
 
 What purposes are cattle kept for ? Do all farmers want special- 
 purpose cattle V What are dual-purpose cattle ? Do all farmers need 
 pure-breed cattle ? What disadvantage do the larger breeds of cattle 
 have? What mistakes are made with fine hogs sometimes ? Wliat 
 sort of treatment must improved stock have? What sort of animal 
 will gain most for a given amount of food eaten? What are the real 
 advantages of beef-bred cattle? Are these advantages as large as 
 many believe? Which does the buyer make more profit on, the beef- 
 bred or the scrub steer? What other reason is given for better prices 
 paid for beef-bi'ed steers? Does there appear to be any truth in the 
 
274 ELEMENTS OF AGRICULTUKE 
 
 common claim that pure animals mature earlier than grade animals 
 when both are fed alike? What comparison is made of a .Jersey and a 
 Short-horn calf? Do beef-steers fatten at an earlier age than other 
 steers, if fed alike? What have tests of dairy cows proved? Is there 
 any best breed? Which is more important, feeding or breeding? 
 AVhat state has most cattle? Why do cattle not serve to enrich land 
 as mucli in the South as in the North? Where are small, sorry cattle 
 found in the United States? Is this inferiority owing to poor breed- 
 ing? Where are better cattle fouiui ? What makes the poor cattle 
 on the marshes and pine meadows? What change takes place when 
 these small cattle are grazed on rich land farther north? Why is the 
 range hog a razor-back ? Are grasses richer and more digestible if 
 grown on rich land? Can we make good cattle out of sorry Southern 
 cattle by feeding them well? What are some good feeds for this 
 purpose ? 
 
CHAPTER XL 
 
 HOGS, SHEEP, GOATS, POULTRY, AND BEES 
 
 Different Types of Hogs. — There are several types of 
 liogs. The Poland-China is generally spoken of as a 
 lard and side-meat hog. But the proportion of iard 
 and fat meat to other parts in these hogs does not differ 
 widely from that in other hogs if they are fed and 
 handled in the same way. The kind and amounts of 
 food eaten change the products more than differences 
 of breed. The Tamworth, which is prized as a bacon 
 hog, is supposed to produce strips of bacon with lean 
 and fat nicely mixed. This tendency, however, is seri- 
 ously interfered with when the Tamw'orth is highly 
 fed on fattening food. But when pastured and fed 
 skimmed milk, shorts, bran, etc., it produces the nice lean 
 bacon desired, and so does the Berkshire or Yorkshire. 
 Here, again, the feed has more influence than breed. The 
 finest hog-meat product'of the w^orld is the Smithfield ham, 
 cured in Virginia from razor-back hogs that run half wild 
 most of their lives in the w^oods. When they get nearly 
 two years old, their owners let them run on peanut and 
 sweet potato patches, and then feed them awhile on corn 
 before killing them. A hog so raised and handled will 
 have a larger proportion of lean meat, and the meat will 
 be better flavored than that of rapidly grown and fattened 
 
 275 
 
276 
 
 ELEMENTS OF AGRTCULTIRE 
 
 Feeding Test. — Bulletin 104 of the Wisconsin Experi- 
 ment Station gives a most interesting account of feeding 
 a large number of pigs from birth to maturity. Some of 
 these pigs were pure Texas razor-backs, some Poland- 
 
 Tam worth 
 
 
 Mk 
 
 ^^^g^l^^ 
 
 mii 
 
 
 
 1 
 
 's^^'Mif'i^'^ 
 
 ■ 
 
 
 ■ 
 
 
 K 
 
 p 
 
 WSm 
 
 1 
 
 
 I 
 
 
 1 
 
 1 
 
 
 1 
 
 ^B^W 
 
 ■ 
 
 
 ^r 
 
 J^. 
 
 
 
 Diuoc .lersey 
 Fig. i)0. — Breeds of Swine 
 
 Cliinas, and some Berkshires ; and others were crosses 
 between razor-l^acks and the pure breeds. The genuine 
 razor-backs did not make as good gains as the pure-bred 
 hogs, but they dressed out nearly as well, and actually 
 made each hundred pounds of gain on a little less food 
 than the others. This and numerous other experiments 
 
JI()(;s, SHEEP, GOATS, POULTRY, AND BEES 277 
 
 prove tliat feed amounts to more than "breeding" in 
 making a meat animal. 
 
 It is true with hogs, as with all live stock, that when 
 the animals are small and 3 oung, a given amount of gain 
 
 Poland-China 
 
 Berkshire 
 Fig. 100. — Breeds of Swine 
 
 in weight can be made with much less food. For instance, 
 with suckling pigs, one and a half pounds of dry digest- 
 il)le food in milk or other food material will produce a 
 pound of growth. In growing from thirty to one hundred 
 })ounds in weight, about two and a half pounds of digest- 
 ible food will be needed for each pound gained. In 
 growing from one hundred to two hundred weight, about 
 
278 
 
 ELKMEXTS OF AGRICULTURE 
 
 four pounds of digestible food to each pound gained will 
 be needed ; and in growing from two hundred to three 
 hundred weight, probably five or six pounds will be re- 
 quired. So it can readily be sejn tliat hogs should not 
 be grown very large, if we wisli to make most proiit. 
 
 Fig. 101. — Razor-backs for want of Feed 
 
 Pasture for Hogs. — Pasture is very necessary in order 
 to raise hogs cheaply. Many people keep hogs in a dry 
 lot and fatten them on corn. Corn has not enough pro- 
 tein, or muscle-making material, to cause young hogs to 
 grow economically or rapidly. 
 
 Pork rfijsed on high-priced corn, fed in a dry lot, cer- 
 tainly costs over ten cents a pound. One or two pounds 
 of corn will usually make, when fed to young hogs run- 
 ning on good green pasture like vetch, clover, alfalfa, or 
 rape, a pound of growth. 
 
HOGS, SHEEP, GOATS, POULTKY, AND BEES 279 
 
 With oats, vetch, bur clover, rape, and other crops for 
 winter grazing ; and with sorghum, peas, and green corn 
 
 □ 
 
 PI 
 
 UEi 
 
 Fig. 102. — Movable Fence 
 
 for summer ; and peas, peanuts, sweet 
 
 potatoes, chufas, corn, kafir, etc., to 
 
 fatten off the hogs in winter, pork can 
 
 be raised very cheaply in the South 
 
 and West. With a variety of crops 
 
 like the ones mentioned, and small amounts of corn, these 
 
 sections could raise bacon hogs enough to supply the 
 
 world. Fed in this way, almost any kind or breed would 
 
 make good bacon hogs. 
 
 To handle hogs in this way would require a good deal 
 of fence. A suitable amount of movable fencing built in 
 panels, as shown in Figure 102, would go far to meet this 
 difficulty. 
 
 Sheep and Goats: where grown. — Most of the slieep 
 and goats of the country are now raised on the dry lands 
 of the West, and on lands that are too dry and rough 
 for cattle to thrive well. The sheep of the West are 
 almost entirely of the Spanish Merino type, or fine- 
 wooled sheep, but they also bring about as high prices 
 for mutton as the mutton breeds. On the farms of the 
 
280 
 
 ELEMENTS OF AGRICULTURE 
 
 country many sheep are raised, mostly of larger types, 
 known as mutton breeds. Their wool is generally coarse, 
 and some of it is so long that it can be combed out 
 straight like hair. There is no doubt that they grow 
 heavier fleeces in the North and on the elevated, cold 
 
 Fig. lOo. — vShkep and Goats 
 o. Merino; b. Honied Dorset; c. Southdown; rf. Angoras 
 
 lands of the Rocky Mountain States than they do on 
 the lowlands of the South. Sheep, like all other animals, 
 grow heavier coats in cold countries. In the pine woods 
 of the Gulf States, a good yield of wool is three pounds 
 a head for range sheep. North and West, eight pounds 
 
IIOCjIS, SIlEEr, GOATS, POULTRY, AND 15EES 281 
 
 are more often got, and individnal sheep have frequently 
 prodnced fifty pounds in a season. 
 
 Food and Manure. — Sheep eat almost any kind of 
 Aveeds or grasses, and are useful on the farm for clean- 
 ing pastures of weeds. They eat a larger proportion 
 of concentrated feed than cattle, and produce richer 
 manure. There is an old saying that "the sheep's 
 
 Fi(i. 104. — Flock ok Angokas 
 
 foot is golden," which probably means that the sheep 
 makes money for its owner by enriching the land. It 
 was once thought in England that cattle and slieep en- 
 riched land by blowing their breath on it wlien eating 
 grass. The people no doubt saw greater improvement 
 in pasture land than the manure seemed to account 
 for. Who knows but that the manure contains colonies 
 of bacteria of highest value to land, which the cattle 
 and sheep, in tramping over the pastures, spread from 
 
282 
 
 ELEMENTS OF AGRICULTURE 
 
 place to place ? Would not that be almost as curious 
 and interesting as enriching the land with the breath? 
 
 Profits in Sheep. — Sheep make about as much growth 
 for a given amount of food eaten as do cattle, and for 
 some years have sold rather higher than good cattle and 
 much higher than average cattle. They give their wool 
 product extra, which is an item of considerable importance. 
 Sheep, then, are much more profitable than beef cattle, if 
 they can be grown without too much trouble in fencing, 
 protecting from dogs, wolves, etc. 
 
 Fig. 105. — Sheep Ranching in the West 
 
 Angora Goats. — A great deal of interest is now being 
 taken in Angora goats, not only in the semiarid I'egions, 
 but in the rainy sections east, where they are prized for 
 cleaning up briers, bushes, and rubbish, and making the 
 land easy to clear. The mohair trade of West Texas, 
 New Mexico, Kansas, and other states is becoming im- 
 portant, and prices received are profitable, but so far no 
 product has been got equal to the mohair of Turkey 
 and Persia. Whether this is due to the fact that the 
 
HOGS, SHEEP, GOATS, POULTRY, AND BEES 288 
 
 goats in this country 
 are not pure, or to 
 some deficiency in the 
 climate, we do not 
 know. The Angora 
 makes good mutton, 
 and the skins sell for 
 a good price. 
 
 Poultry. — Poultry- 
 raising is perhaps 
 about as large in total 
 returns in the United 
 
 States as wheat grow- Fig. IOG. — Plymouth Rock 
 
 ing, but it is carried on generally in a small way by nearly 
 everybody, everywhere. The Chinaman makes as much 
 
 food on a given area 
 of land covered with 
 water in the form of 
 fish ponds as he can 
 make on the best 
 garden. A certain 
 range for poultry 
 will perhaps furnish 
 bugs, worms, insects, 
 seeds, etc., enough 
 to produce meat and 
 eggs to a high value 
 as compared with the 
 crops that might be 
 
 Fui. 107. — Brown Leghorn grOWU on that range. 
 
284 
 
 ELEMENTS OF AGRICULTURE 
 
 
 M}?ff^ 
 
 ( 'hickens are kept on a comparatively small area near the 
 bouse. Turkeys and guinea fowls go long distances in 
 search of their food. They may be made of very great 
 value in destroying boll weevils. 'I'bey are both very 
 
 profitable fowls 
 t (^ grow, the 
 guinea fowl be- 
 ing the best egg- 
 producer on the 
 farm. Geese are 
 not only valu- 
 able for their 
 feathers and for 
 their meat, but 
 may be made of 
 great assistance 
 to cotton farm- 
 ers. In the dis- 
 tricts where hoe- 
 
 Fio. lOS. iJuoxzK Gobbler ^^^^ -^ expensive 
 
 on account of crab grass, it is not too much to say that a 
 goose to each acre of cotton will save half the expense 
 of hoeing. 
 
 Three types of fowls are shown in figures above. 
 
 Bees, like fowls, convert something that would be lost 
 without them into money. Sometimes an acre of land, 
 devoted to certain crops, will afford several dollars' worth 
 of honey. Certain large areas of country, partly forest, 
 have been estimated to furnish over a dollar's worth of 
 honey to every acre. 
 
HOGS, SHEEP, GOATS, l^OULTRY, AND BEES 285 
 
 Nothing is more pleasant, instructive, and profitable to 
 boys and girls than a few colonies of bees. They often 
 make #5.00 a colony a year. If 3-ou procure a little book 
 or bulletin on bees, you will learn to liandle them easily 
 and can make money on them. 
 
 QUESTIONS 
 
 What is usually understood as the lar<l and side-meat liog? Why 
 is the Tamworth called a bacon hog? Does feeding or breeding most 
 influence the proportions of fat and lean meat? Are other breeds 
 good bacon hogs? Could the Tamworth be fed into a lard hog? 
 Will the native hogs make good bacon hogs? Mas any experiment 
 indicated that native hogs are good feeders? Why should hogs not 
 be grown large? Give different amounts of dry feed needed to make 
 a pound of gain on different- sized hogs. Can hogs be raised profitably 
 on corn alone? What must be chiefly provided to grow hogs? What 
 are some different pasture crops for hogs suitable for different seasons ? 
 Where are most of the sheep of the country raised ? What sort of 
 sheep are raised on the ranges ? Do merino sheep sell well for mutton? 
 What kinds of sheep are grown more on the farms? Where will 
 sheep produce most wool, and why ? What sort of food do sheep eat? 
 Do they enrich the land? What did people once think caused stock 
 to enrich land? How about food eaten, growth made, and prices 
 received for sheep as compared with beef cattle? What extra 
 product do sheep give? Where are angora goats found mostly? 
 What special use is made of them in the East? Is the mohair as 
 fine as that of Turkey ? Tell the advantages of raising poultry. Tell 
 something of bees. 
 
 Experiment. — Suppose you put a razor-back shoat in one pen at 
 home and a pure-bred shoat of about the same size in another. Feed 
 them all they will eat and see if one eats more than the other. 
 Weigh them when you first put them up, and w^eigh them at the end 
 of a month or two of good feeding. See if their increase in size and. 
 weight is the same. 
 
CHAPTER XLI 
 
 DAIRYING 
 
 Different Products. — Siiccessfal dairying, combining as 
 it does farming and manufacturing, requires a high degree 
 of skill and plenty of industr}^ Producing milk to be 
 sold as such, cream for city trade, making butter, cheese, 
 and condensed milk, all afford means of marketing milk. 
 Milk is now being shipped by train loads as far as a hun- 
 dred miles to large cities. Cream is shipped in car loads 
 from Chicago to New Orleans. Butter and cheese, of 
 course, can be shipped almost any distance, while con- 
 densed, canned milk is largely exported to South America 
 and Oriental countries. 
 
 Silage, or ensilage (green corn cut in short lengths and 
 kept green in a big air-tight room, or silo), is coming to be 
 a standard dairy feed for winter. 
 
 Milking machines are now coming into use and promise 
 o'reat saving: in labor. So far the machines have not been 
 able to milk quite so thoroughly as the hand milker, but 
 this will doubtless soon be accomplished. 
 
 Elements of Success. — Good cows, good, rich pastures, 
 and plenty of feed of suitable kind and variety, and 
 good dairymen, are the conditions most necessary for 
 success. Pure-bred cows are by no means necessary. Most 
 of tlie good, profitable herds of dairy cows in this country 
 
 280 
 
DAIRYING 
 
 28' 
 
 are grades ; that is, crosses between native cattle and 
 pure-bred cattle of dairy breeds. Some grade cattle have 
 been crossed with pnre-l)re(ls for so many generations 
 that they are 
 practically pure. 
 A^ery much of 
 the dairy pro- 
 d u c t o f t h e 
 country is made 
 from well-se- 
 lected and well- 
 cared-for native 
 cows. 
 
 The records 
 of such herds are 
 often excellent 
 as CO m p a r e d 
 with grade and 
 pure herds. In 
 this business 
 good feeding and proper handling of the cows count for 
 more than breeding. 
 
 Dairying South and West. — People in the Southern 
 States and the far Western States have not engaged 
 extensively in dairying. The Southern people have been 
 busy with cotton, tobacco, cane, and rice ; and it is said 
 the ranchman of the plains will not milk a cow because 
 he cannot do it on horseback. 
 
 Milk for Home Use. — When only two or three cows are 
 kept simply to get milk and butter for home use, perhaps 
 
 Fig. 109. — Round Silo 
 
288 
 
 ELEMENTS OF AGRICULTUKE 
 
 tiie plan of taking ^Dart of the milk and letting the cilf 
 have the rest is not bad. Milking in a small way is ant 
 
 Fig. 110. — Cows of Dairy Breeds 
 Jersey, above ; Holstein Dehorned, belovN- 
 
DAIRYING 289 
 
 to be irregularly and more or less carelessly done. The 
 calf does good, thorough milking, and tliat keeps the cow 
 giving milk longer than if she were not properly milked. 
 If the cow runs in the woods or in a large pasture, she 
 will come home regularly to see her calf. 
 
 Commercial Dairying. — People who produce dairy prod- 
 ucts in a commercial way cannot afford the time necessary 
 to rope off calves and to wait for them to ''bring the milk 
 down." Neither can the dairyman afford to give the calf 
 the richest milk, the " strippings," which is three times as 
 rich as the first milk drawn. A commercial dairyman 
 must wean his calves when they are a day or two old, 
 and teach them to drink skimmed milk from a bucket. 
 He must also teach them to eat corn meal worth one cent 
 a pound instead of butter fat Avorth thirty cents a pound. 
 He must drive up his cows regularly, feed them well, and 
 milk them thoroughly. Many people in the South think 
 their native cows would not give milk without suckling 
 calves. If the calves are taken away young, nearly all 
 the cows will give their milk, just as Jerseys do. 
 
 Crude Methods. — People making butter for their own 
 use only often have very crude ways of handling milk 
 and making butter. The milk is set in pans, and the 
 cream continues to rise till the milk clabbers. In sum- 
 mer it clabbers perhaps before two-thirds of the cream 
 rises. In fall, winter, and spring it can stand longer, 
 and somewhat better results are obtained. If an attempt 
 is made to churn all the milk, the necessary work is 
 great; the temperature of milk will have to be so high 
 that the butter will be beaten into a sort of soup, and 
 
290 
 
 ELEMENTS OF AGRICULTURE 
 
 it will be white and so mixed with buttermilk that it 
 will not keep long. There is much of the butter 
 fat left in the buttermilk under these circumstances. 
 When cream is churned at a high temperature in sum- 
 mer, or when heated too much in winter, the same sort 
 of butter is made, and the losses are also great. With 
 
 people who like fresh butter 
 made in this way, and make 
 all they need, this plan is not 
 bad, especially if they use the 
 skimmed milk and buttermilk 
 for cooking and for drinking. 
 Making Good Butter. — Good 
 butter such as will keep well 
 cau be made with any kind of 
 churn, if only the cream is 
 kept at 60 to 70 degrees, 
 Fahrenheit, during the opera- 
 tion ; that is, at about the tem- 
 perature of fresh well water in 
 the Gulf States. Churning 
 must cease as soon as the butter appears in little par- 
 ticles the -size of sorghum seed. These should be strained 
 out, or separated from the milk in some way, and washed 
 and worked enough to get rid of the excess of water and 
 to mix the salt evenly through the product. Of course, in 
 making butter in anything like a large way, a box or barrel 
 churn becomes necessary, instead of the old dasher churn. 
 Cream Separator. — The farmer who has four or five 
 good cows and expects to sell butter will find that a hand- 
 
 FiG. 111. — Cream Separator 
 
DAIRYING 291 
 
 power cream separator is essential to the best profits. The 
 separator gets practically all the cream from fresh, sweet 
 milk. Tliis cream can be kept at a snitable temperature 
 much easier than can milk when set for cream, and it will 
 generall}' produce better butter. 
 
 A dairyman can well afford to buy ice in summer when 
 he handles only the cream. The fresh skimmed milk is 
 much better than clabber to feed to calves. If a good 
 cow produces $60.00 worth of butter a year when the 
 milk is run through a separator, she would not likely 
 make over 145.00 worth when the milk is set in the old 
 way. Then the saving in labor, in value of skimmed milk, 
 etc., may easily make a saving in profit for each cow of 
 1^20 a year. The saving on two or three cows, tlien, 
 may easily pay for a small separator. The same rules 
 alread}- given for churning apply to churning on a large 
 scale. Dairymen who make butter for sale easily learn 
 suitable Avays of packing and presenting it to the trade 
 in attractive form. 
 
 Breed, not Feed, makes Rich Milk. — It is not true, as 
 many people believe, that rich feed given a cow will 
 produce richer milk than poor food d(^es. Rich feed and 
 plenty of it will produce more milk, but it will be no 
 richer tlian that given by the same cow wlien she is 
 eating the poorest feed. Different types or breeds of 
 cattle give milk differing in richness, and different indi- 
 viduals of the same breed give milk differing in quality. 
 Generally Jerseys and Guernseys give milk rich enough 
 to make half a pound of butter from each gallon. Short- 
 horns, Holsteins, and Ayrshires give milk requiring about 
 
292 ELEMENTS OF AGRlCrLTCRE 
 
 three gallons or more to tlie pound of butter. ( 'ows give 
 poorest milk soon after bringing calves, a time when they 
 are giving most milk. As their calves grow older, they 
 give less, but richer milk. Milk rich in butter fat is 
 generally rich in casern, or cheesy matter, but not always 
 so. Milk will make twice as much cheese as it will butter. 
 Milk has about the same amount of casein as it has fat, 
 and good cheese contains the casein and tlie fat. Clieese- 
 making is more difficult in tlie South than butter-making. 
 
 D 
 
 
 o °°o ^ °o bo 
 
 Fig. 112. — Pure and Impure Milk 
 A. Fat globules B. Fat giobule.s mixed with germs 
 
 Milk also has about as much sugar as it has fat, Ijut the 
 sugar is not found in either butter or cheese. It re- 
 mains in the whey, or watery part of the milk. New 
 milk is about eighty-live to eighty-eight per cent water. 
 
 Bacteria in Milk. — Milk sours and clabbers because 
 bacteria get into it, and turn the milk sugar into an acid, 
 called lactic acid. Vinegar is acetic acid. Try pouring 
 some vinegar in sweet milk. If sweet milk is heated to 
 about 160 degrees, most of the bacteria will be killed, and 
 the milk will remain sweet longer. This mucli heat will 
 
DAIRYING 
 
 298 
 
 Fig. n: 
 
 Box Churn 
 
 not affect the taste of the milk. However, more bacteria 
 soon get into it, multiply, and cause it to sour later. 
 All vessels that milk is kept in should be scalded, and 
 allowed to sun on the inside. Heat and sunlight kill 
 germs. Dirty, poorly scalded milk vessels cause milk to 
 sour quickly, because the 
 germs are not killed, and 
 a big crop of them starts 
 to multiplying in the milk 
 at once. 
 
 Creameries or Factories. 
 — In some communities 
 men put up butter, cheese, 
 or condensing factories, 
 and buy milk. In other communities farmers unite in 
 putting up creameries. All of them take their milk to 
 the creamery, and after it is manufactured and the ex- 
 })enses are paid, each one gets his share of tlie profits. 
 Most communities in the South have thus far not pro- 
 duced milk enough for large creameries. With a hand 
 separator and some otlier simple apparatus, any farmer can 
 make good butter and be independent of creameries. 
 
 Visit a Good Dairy. — Suppose you visit some neighbor 
 who is in the dairy business and get him to tell you and 
 show you more about the business. Then if you will feed 
 tlie cows better, and learn to make good butter and more 
 of it than formerly, you can sell some and make a nice 
 little sum of money. And if you will feed the skimmed 
 milk not needed for other purposes to your pigs, with 
 other foods, they will make money for you. 
 
294 ELEMENTS OF AGUICUL'i CUE 
 
 Write your Experiment Station for bulletins on dairy- 
 ing. It would require several books the size of this one 
 to tell you all the useful things known about the subject. 
 
 QUESTIONS 
 
 What two lines of business are combined in dairying? What are 
 the elements of success in dairying? What are the different products 
 made from milk? Are pure cattle necessary for success? What are 
 grade cattle? Are native cattle used successfully? In what sections 
 are the people backward about tins line of business? How are cows 
 and calves managed where only two or three cows are milked? 
 What changes nmst be made where more cows are kept? How must 
 dairy calves be raised? How do most people handle milk and make 
 butter for their own use ? Would butter made in this way keep and 
 sell well? Give the advantages of a cream separator. What extra 
 profits can be made on each cow by means of a separator? Does rich 
 feed make rich milk ? What influences richness of milk ? What 
 breeds of cattle produce richest milk? Will a cow give riclier milk 
 when her calf is young or when it is old? How much butter M'ill a 
 gallon of milk make? How much cheese will a gallon of milk make? 
 What causes milk to sour? What effect has vinegar on sweet milk? 
 What sort of factories do people have for handling large amounts of 
 milk ? Are creameries necessary for good results? 
 
 Experiment. — Put some fresh milk in poorly cleaned pans, some 
 more in thoroughly cleaned pans, and heat some more milk to 160 
 degrees Fahrenheit, and observe how long each lot will keep before 
 clabbering. Get a dairy thermometer and practice making some 
 good butter at home. 
 
APPENDIX 
 
 IMPORTANT ECONOMIC FAMILIES OF PLANTS 
 By H. Ness, of Tkxas A. & M. College 
 
 The whole vegetable kingdom is divided into numerous 
 groups and sub-groups, and these are so related that they can 
 be arranged in a continuous series from the lowest to the 
 highest. Indeed, the relationship, as revealed by their struc- 
 ture, is so close that in a great number of cases the neighboring 
 groups pass imperceptibly into each other, their limiting char- 
 acters being, so to speak, blended. 
 
 The first and main division of the vegetable kingdom is di- 
 vided into sub-kingdoms. The lower one, or the spore-bearers, 
 reproduce themselves by spores, small one-celled particles, 
 having no embryo, as, for example, the ferns, mosses, and 
 numerous much lower plants. The second and higher are the 
 seed-bearers, which reproduce themselves by a seed that c<3n- 
 tains an embryo, or an infant plant, with enough food inclosed 
 with it to nourish it until it is strong enough to procure its 
 own nourishment. 
 
 The seed-bearers are again divided into two groups : 1st, the 
 naked seeded, or those which bear their seed inclosed between 
 scales Avhich spread apart to drop the seeds when they are 
 ripe, as in the pines ; 2d, those which have their seed in- 
 closed in a pod (cotton, peas, etc.), or fleshy coat (tomatoes, 
 grapes), or two coats, an outer fleshy, and an inner stony 
 (peach, plum, etc.), or a close-fitting, fibrous coat (corn, wheat, 
 oats, and other grasses). This second group is again divided 
 
 295 
 
290 
 
 APPENDIX 
 
 into two groups according to tlie nature of the embryo : namely, 
 those with the embryo having one leaf, or seed-leaf, as onion, 
 grasses, grains, banana, etc. ; and those having two seed-leaves, 
 as all the trees, cabbage, tomato, and most garden vegetables. 
 The following scheme shows the relationship of these prin- 
 cipal groups of plants, beginning with the lowest: — 
 
 I. Spore-bearers. One-celled living particle having no embryo. 
 
 II. Seed-bearers. -! 
 
 l^- 
 
 Naked seeded, seed inclosed between scales. 
 Vessel seeded, seed inclosed in a vessel. 
 
 One-leaved seeded, with wood and bast in united 
 strings, siuTOunded by pith, parallel- veined 
 leaves, and numerous roots of equal size from 
 the lower joints of the stem ; as in the stems 
 of corn, sorghum, and numerous grasses. 
 
 Two-leaved seeded, with true bark surrounding 
 the wood, and with the pith in the center, net- 
 ted-veined leaves, and true taproot bearing 
 lateral roots. Examples, cotton, oak trees, etc. 
 
 From the two last groups, a, called the Monocotyledons, and 
 h, called the Dicotyledons, come practically all the plants that 
 furnish us with grains, vegetables, and fruits for our living, 
 and fibers for our clothing. These groups are again subdivided 
 into orders and families. We will now proceed to name a few of 
 the most useful families and the most useful plants under each, 
 beginning with the Monocotyledons, or the one-leaved seeded. 
 
 The Grass Family. — To this belong, as the name indicates, 
 all the true grasses, which also include Indian corn, wheat, 
 rye, oats, barley, and rice, as well as sorghum and sugar cane. 
 This is by far the most important of all families of plants, 
 since it furnishes not only all breadstuffs for our own sus- 
 tenance, but also grazing and fodder for our domestic ani- 
 mals. From this family the Ja^^anese and Chinese obtain the 
 bamboo, which grows in their countries to be 80 to 100 feet 
 
APPENDIX 297 
 
 higli, and furnishes timber for most of their houses. Indian 
 corn is thought to be a native of Mexico, C-entral, and South 
 America, where its nearest relatives now grow wild, but tlie 
 Indian corn, in the highly developed form in which we to-day 
 possess it, has never been found wild by white man. Since 
 the discovery of America, its cultivation has spread among all 
 people living in the warmer parts of the temperate and tropical 
 zones, even among the savages in the interior of Africa. 
 
 Palm Family. — This family belongs to the tropics and warm, 
 very often dry, countries of the temperate zones, as ]S"orth 
 Africa and Arabia, whence we get the date fruit, which we 
 have now commenced to cultivate in the southwestern portion 
 of Texas, near the Gulf and the Mexican borders. From this 
 family we also obtain the cocoanut, which grows throughout 
 the Pacific islands, including the Philippines. 
 
 Lily Family. — From this family we get our onions and gar- 
 lics, which are natives of the Mediterranean countries, and 
 have been cultivated from the earliest antiquity. 
 
 The Asparagus Family gives us asparagus, a perennial with 
 numerous horizontal root stocks, which, when on highly fertil- 
 ized soil, send up early in the spring numerous fast-growing, 
 fleshy shoots that are cut when about six inches high, and much 
 prized as a vegetable diet. The plant, being a native of sea- 
 coasts, requires in addition to other fertilizers a bountiful 
 supply of salt. 
 
 Banana Family. — The banana is a native of the moist regions 
 of the tropics, but can also be grown in sheltered positions on 
 the Gulf coast. It includes the abaca, or Manila hemp plant, 
 which furnishes the best rope fiber in the world. 
 
 DICOTYLEDONS 
 
 Walnut Family. — The pecan, hickory, and English walnut 
 come from this family. The English walnut is a native of 
 Middle and Southern Europe, is successfully cultivated in 
 
298 APPENDIX 
 
 California, and will grow well in Texas. It is a nut of the 
 greatest commercial importance. The pecan is native of a 
 large part of the United States, but produces the finest nuts 
 in Texas, west of the meridian of Austin. Many cultivated 
 varieties with thin-shelled, very large fruit are now coming 
 into cultivation. 
 
 Mulberry Family. — This family gives us a great number of 
 useful trees. From our cultivated fig we have the well-known 
 fruit, which is a hollow head bearing its numerous small flowers 
 in the cavity. Other wild tropical figs give us rubber from 
 the juice of their trunks. 
 
 Goosefoot Family gives us the spinach which is grown in our 
 gardens for greens and salad, the common beet, the sugar 
 beet from which much of our sugar is made, and the huge 
 mangel wurzel, raised for cattle food. 
 
 Mustard Family. — To this family belong the greater number 
 of our most important vegetables, such as mustard, radish, 
 turnip, cress, and cabbage. As all of them are natives of 
 cool, damp climates, they are grown by us as early spring or 
 late fall crops. The cabbage is a native of the coast of France 
 and other neighboring coasts, where it is yet found in a wild 
 state, having the appearance of our kale. The original wild 
 plant is called Brassica oleracea by the botanists, and has by 
 "sporting" in cultivation given rise to the following forms 
 which come true from seed: the common cabbage in all its 
 forms, in which the stem and the leaves have been converted 
 into an immense bud; the cmdijiower, in which the stem has 
 been converted into a cockscomb-like body, called the "flower"; 
 the Brussels sprout, that produces several heads the size of a 
 man's fist as buds in the axils of the leaves along the stem ; 
 ruta baga, in which the root has become turnip-like; the kohl- 
 rabi, in which the short stem has become fleshy and is the 
 edible part ; and finally, the kale and coUard. 
 
 Mallow Family. — From this we get the cotton and the 
 okra. 
 
APPENDIX 299 
 
 Orange Family gives iis the oranges and the lemons. Kardy 
 varieties of these fruits are now being cultivated in our coast 
 country on a commercial scale, and still hardier ones are 
 being developed by crossing the tender orange with the hardy 
 trifoliata lemon. The resulting hybrid is called the Citrange, 
 which produces a valuable fruit, and can be grown three to 
 four hundred miles north of the present orange belt. 
 
 Grape Family gives us all the grapes, which run into nu- 
 merous forms both wild and in cultivation. The future grape 
 region of Texas is the arid region west of the Pecos, where 
 these plants will be much freer from diseases than in the 
 moister regions. 
 
 Rose Family. — This family used to include most of the 
 orchard and garden fruits. It is now divided into: Pome 
 Family, including the apple, pear, and quince ; Hose Family, 
 including blackberry, dewberry, raspberry, and strawberry ; 
 Prune Family, including peach, plum, cherry, and almond. 
 
 Pea Family includes the peas, beans, and numerous forage 
 plants having the pea-like flower, such as clovers and alfalfa. 
 
 Cucumber Family includes cucumber and the melons, all con- 
 stituting valuable commercial crops in our State. 
 
 Parsley Family. — From this we obtain several vegetables 
 more useful because of their flavor than the amount of nourish- 
 ment that they furnish. The principal ones are carrot, pars- 
 nip, parsley, caraway, and celery. The last is imported in 
 large quantities from the North, but can be raised with ease 
 in our ov/n State on rich, well-cultivated land. As young 
 plants are slow in coming up and are at first delicate, they 
 have to be started in seed beds. To insure good flavor and 
 crispness, the stems of the leaves are covered by filling up the 
 dirt around them as they grow. 
 
 Nightshade Family. — This family gives us the Irish potato, 
 the eggplant, tomato, the siveet j^^l^P^'^, Cayenne p)epper, and 
 tobacco : all American plants and unknown before the discovery 
 by Columbus. The Irish potato is the most widely used vege- 
 
800 APPENDIX 
 
 table in the world. This and the tomato form the most im- 
 2)ortant exportation of garden-truck crops from our State. 
 
 Morning Glory Family gives us the sweet potato, which is 
 a native of Jndiaj and was cultivated in very ancient times. 
 
 Olive Family gives us the olive, famous for the oil, which is 
 jjressed from the plum-like fruit. The olive is native of the 
 Mediterranean countries, but is now being cultivated in South- 
 western Texas, Arizona, and California. 
 
 TREATMENT OF PLANT DISEASES 
 By H. Ness 
 
 Eemedies against plant diseases are among the things that 
 belong to our own generation; perhaps because it is within 
 recent times that such immense plantings have been made 
 as to furnish abode for the parasites that produce the diseases 
 on the higher plants. 
 
 After trials with numerous materials for the purpose of dis- 
 covering something that would act as poison to the parasitic 
 fungi but be harmless to the host plant, there was at last 
 found in the salts of copper, especially bluestoue or copper 
 sidphate, a substance that would kill all the fungi with which 
 it came in contact without injury to the host. The method of 
 applying this was first started in France, in the district of Bor- 
 deaux, as a remedy against downy mildew on grapes. But 
 since most of the fungi live inside in the tissues of their hosts, 
 very few diseases can be cured. The action of the bluestone 
 is, therefore, rather that of a preventive than a cure. As a 
 ])reventive it is used in the well-known mixture called Bor- 
 deaux mixture, consisting of four pounds of lime mixed with 
 six pounds of bluestone, or copper sulphate, and dissolved in 
 forty -five gallons of water. 
 
 This mixture is applied to the plant with a spray pump, 
 throwing the liquid into a steam-like spray and covering the 
 
APPENDIX :]()! 
 
 entire plant, so that the spores of the fungi find no uncovered 
 spot for lodging and germinating. It is claimed that the cop- 
 per salt, instead of injuring the plant, actually stimulates its 
 growth. Spraying must be done as often as the rain washes 
 the coating off the plants. 
 
 To Bordeaux mixture may be added small quantities of Lon- 
 don purple or Paris green. 'I'hese substances contain arsenic, 
 which will kill any insect that may eat the leaves or bark 
 of the plant. Only small amounts of these materials can be 
 added, as they are also poisonous to the plant itself and easily 
 cause scorching of the leaves. Lime is used with bluestone 
 to make the mixture stick to the plant. 
 
 Another formula, not so much used, but recommended be- 
 cause it sticks well to the plant, consists of a compound of cop- 
 per and vinegar, called copper acetate, two to four ounces of 
 this being dissolved in twenty -live gallons of water and applied 
 as above. 
 
 Numerous other salts of copper are used in these spray solu- 
 tions; as, for example, copper carbonate, of which three ounces 
 are used in connection with one pound of ammonium carbonate 
 in forty to forty-five gallons of water. To all of these formulas 
 very small quantities of arsenious salts may be added to kill 
 any insects that may chance to feed on the plants. But in all 
 cases it is the copper salt that kills the fungi or prevents their 
 spores from getting a foothold. 
 
 All these spray solutions containing copper salts are used 
 for all contagious diseases affecting the parts of plants above 
 the ground, because they are all due to fungi, which propagate 
 themselves by similar spores carried by air or insects and lodge 
 and germinate on the surface of the host plant before making 
 their entrance into its tissues. 
 
302 APPENDIX 
 
 FIGHTING INSECT ENEMIES — INSECT POISONS 
 
 OR INSECTICIDES 
 
 By C. E. Sanborn, Texas Experiment Station 
 
 Below are given formula? for making seventeen of the most 
 effective insect poisons known at this time : — 
 
 I. Arsenate of Lead 
 
 Acetate of lead 11 oz. 
 
 Arsenate of soda 4 oz. 
 
 Water 50 gals. 
 
 II. Paris Greex Liquid Spray 
 
 Paris green 1 lb. 
 
 Lime (fresh unslacked) 2 to 3 lbs. 
 
 \Vater 200 to 250 gals. 
 
 III. Paris Greex Dry 
 
 Mix with 25 parts air slacked lime ; used pure to kill insects 
 crossing weed patches or feeding on other plants of no value. 
 
 IV. Lime Sulphur Wash 
 
 Lime (fresh unslacked) 20 lbs. 
 
 Sulphur 16 lbs. 
 
 Water .50 gals. 
 
 V. Kerosexe Emulsion 
 
 Hard soap -J- gal. 
 
 AVater 1 gal. 
 
 Kerosene 2 gals. 
 
 a. For a 5 % solution, dilute with 37 gals, water. 
 
 h. For a 15 % solution, dilute with 10^ gals, water. 
 
 c. For a 20 % solution, dilute with 7 gals, water. 
 
APPENDIX 
 
 303 
 
 VI. Whale Oil Soap 
 
 1 lb. to 2 srals. water. 
 
 YII. For a Winter Spray for Evergreens 
 
 Eesin, pulverized 
 
 Caustic soda, granulated, 98 % 
 
 Fish oil 
 
 Water for final bulk ...... 
 
 20 lbs. 
 
 4^ lbs. 
 
 3 pts. 
 
 150 gals. 
 
 VIII. For a Stivimer Spray 
 
 1 qt. flowers of sulphur dissolved by boiling with 10 lbs. 
 potash soap in 15 gals, of water. To use, dilute with 35 
 gals, of water. 
 
 IX. Bordeaux jNIixtltre 
 
 If this spra}^ is being used where biting insects are injurious, 
 
 its purpose may be doubled 
 
 by adding the 
 
 arsen 
 
 ical as given : — 
 
 Copper sulphate 
 
 Lime (fresh unslacked ) 
 
 W^ater 
 
 Acetate of lead . 
 
 Arsenate of soda 
 
 
 
 
 
 
 5 lbs. 
 
 9 lbs. 
 
 50 gals. 
 
 11 oz. 
 
 4 oz. 
 
 X. Carbon Bisulphide 
 
 2 to 4 lbs. to 1000 cu. ft. of space. Set in vessels and allow 
 to evaporate. Gas will sink through grain and smother weevils. 
 
 XI. Before Insects appear in the Spring 
 
 Trees should be bandaged from a few inches below surface 
 of soil to two feet above with newspapers or other convenient 
 material. Remove and burn bandages after hibernation of 
 insects. 
 
304 APPENDIX 
 
 XII. Inject kerosene into the tunnels. 
 
 XIII. Kill larvie in tunnel with a wire or in some cases cut 
 the larvae out. 
 
 XIV. a. After liarvest destroy its food plants and allow no 
 hibernating places to exist except as traps for burning. 
 
 b. Control by infecting with parasites or contagious diseases. 
 
 c. Destroy infested fruit. 
 
 d. Cultivate the soil two or three inches in depth. 
 
 XV. Sulphur as a Dry Spray 
 Apply with a dust sprayer or shake it through a canvas bag. 
 
 XVI. POISONKI) I'ait 
 
 Paris green or white arsenic . . . . . 4 oz. 
 
 P,ran 10 lbs. 
 
 Molasses or thick sugar-water 1 i>int 
 
 AVater, enough to make a soft dough. 
 
 XVII. Spray premises or dip animal in two per cent solu- 
 tion of zenolium. 
 
 LIST OF HARMFUL INSECTS AND REMEDIES 
 
 Following is a list of the worst insect pests, and the best 
 means now known of fighting them. The insecticides are 
 referred to by numbers from I up to XVII, given above. 
 
 Angular winged katydid {MicroceiHnim retii)ervis, Burm.). 
 I, II, III, or IX. 
 
 Anguniois grain moth {Sitotroga cerealella, L.). X. 
 
 Ants (different species). X (pour in their nests). 
 
 Apple curculio (Anthonomus gradrigihhus, Say). I or II. 
 
 Apple tree aphis (different green species). V, h, immediately 
 before leaves fall. 
 
 Army worms (Spring) = Leucaniauni panda, Haw. ; (Fall) = 
 Laphygriia frugiperda, A. & S. III. 
 
APPENDIX 305 
 
 Bag worm (Thyridopteryx sppJ). Hand pick bags. 
 
 Boll worm {Heliothis obsoleta, Fab.). Fall and winter plowing. 
 
 Bean and pea weevils. X. 
 "Bed bug (Klinophllos lectularia, L.). Spray with gasoline. 
 
 Blister beetles (different species). Ill, or spray colonies 
 with gasoline. 
 
 Blister beetles of plum {Pemphopoea Texana, Lee). Destroy 
 mechanically. 
 
 Cabbage aphis {Aphis bntssiccp, L.). V, a or b, VI. 
 
 Cabbage maggot {Pegomyia brassira, Bouche). Apply to- 
 bacco dust as a preventive. 
 
 Cabbage worm (Pontia rapte, L.). I, II, or III. ' 
 
 Chicken lice and mites. Spray premises with zenoliiim and 
 apply kerosene to roosts; x>i*<^^'ide dust baths for fowls. 
 
 Chinch bug {Blissus lemopterus, Say). XIV, a or b. 
 
 Citrus white fly (Aleyrodes citri, Biley & Howard). VII or 
 VIII. 
 
 Codling moth (Carpocapsa pomonella, L.). II. 
 
 Colorado potato beetle {Lepinotarsa decem-Uneatcu Say.). I 
 or III. 
 
 Corn ear-worm {Ileh'ofhus obsoleta, Fab.). Fall or winter 
 plowing. 
 
 Cut worms (many species). XA^I. 
 
 False chinch bug (Nyslas angxstatiis, Uhl.). V, a or b. 
 
 Flat headed apple tree borer {Chrysobothris femorata, Fab.). 
 XIII. 
 
 Fleas (different species). Remove all dust and rubbish; 
 clean floors and sprinkle with kerosene : keep out dogs and cats : 
 scatter pyrethrmn powder under carpets and in kennels. 
 
 Glover's scale {Lepidosaphes gloverii, Pack.). VII or VIII. 
 
 Grain beetles (different species). X. 
 
 Grasshoppers (different species). I, II, or III. 
 
 Green bug (Toxoptera graminum, Bond.). See page 155. 
 
 Harlequin cabbage bug (Murganfia histrionica, Hahn). VI 
 or Y,b. 
 
 X 
 
306 APPEXDrx 
 
 Hemispherical scale {Lecaninni hemispheric ton, Targ.). YII 
 or VIII. 
 
 Hessian fly (Mayetiola destructor, 8a j.). XV, «,, and late 
 sowing of wheat. 
 
 May beetles (Lachnosternci, several species). I, also pasture 
 infested grass land with hogs. 
 
 Melon aphis (Aphis gossypii, (ilov.). XV and V, a. 
 
 Mexican cotton boll weevil {A. grattdis, Boh.). See page 
 132. 
 
 Mosquitoes (different species). Destroy larvte by pouring 
 kerosene on water where eggs or larvtC are. Cover cisterns, 
 empty troughs, cans, and useless vessels of all kinds. Watch 
 for stagnant pools of water and drain them. Put fish in per- 
 manent pools and tanks. 
 
 Oyster shell bark louse of the apple (Lepidoseqihes pomorum, 
 Bouche). IV. 
 
 Peach scale (Aidacasjyis pentagona, Targ.). IV. 
 
 Peach tree borers (Sanninoidea e.vitiosa, 8ay, and Synanthedon 
 p)ictipes, Say). XII, XIV. 
 
 Plum curculio (Conotrachelus nenuphar, Hbst.). Jar trees 
 in early morning, collect and destroy beetles. 
 
 Purple scale {Lepidosaphes citricola. Pack.). VII, VIII, 
 winter spray on deciduous trees, IV. 
 
 Red spiders or mites (different species). XVI, XVII. 
 
 Eound headed apple tree borer {Saperda Candida, Fab.). 
 XIII, XIV, XII. 
 
 San Jose scale (Asj^idiotus perniciosus, Comst.). IV. 
 
 Scurfy scale (Chisonasj^is furfara, P.). IV. 
 
 Soft scale (Lecanium hesperidiun, L.). 
 
 Southern plum aphis (Aphis setaria', Thos.). V, b, imme- 
 diately before leaves fall or before buds open and after eggs 
 hatch. 
 
 Striped cucumber beetle (Diahrotica vittata. Fab.). 
 
 Sweet potato weevil (Cylas formicarus, Fab.). X. 
 
 Tent caterpillar. The American (Midacosouia Americana, 
 
APPENDIX 307 
 
 Fab.). When tents first appear cut off branches to which they 
 are attached and burn. 
 
 Tomato worm (Phlegethrmtius sexto, L.). Hand pick and 
 destroy. 
 
 Twig girdler (Oncideres sp.?). Burn amputated twigs. 
 
 Woolly aphis {Sddzoneura lanigera, Hausm.). V, b. 
 
 Footnote. Following are the names, with their abbreviations, as 
 used after the technical names of insects herein treated : A. & S., Abbott 
 & Smith; Boh., Boheman ; Bouche, Bouche ; Burm., Burmeister ; 
 Comst., Comstock ; F., Fitch; Fab., Fabricius ; Glov., Glover ; Harr., 
 Harris; Hausm., Hausm ann ; Halin, Hahn ; Haw., Haworth ; Hbst., 
 Herbst ; Howard, Howard ; Lee, Lecnnte ; L., Liiuiffius; Pack., Packard ; 
 Biley, Riley; Kond., liondaiii; Say, Say; Targ., Targoni ; Thos., 
 Thomas ; Uhl., Uhler ; Walsh, Walsh. 
 
308 
 
 APPENDIX 
 
 JUDGING STOCK — TEXAS A. & M. COLLEGE 
 
 Draft House — Scale ok Points — For Geldino 
 
 1. Age ......... 
 
 General Appearance : 
 
 2. Height 
 
 3. Weight, over 1500 lbs. . . . score according to age 
 
 4. Form, broad, massive, low set, proportioned 
 
 5. Quality, bone clean, yet indicating sufficient substance 
 
 tendons distinct, skin and hair fine 
 
 6. Temperament, energetic, good disposition . 
 
 Head and Neck: 
 
 7. Head, lean, medium size 
 
 8. Muzzle, fine ; nostrils large ; lips thin, even . 
 
 9. Eyes, full, bright, clear, large 
 
 10. Forehead, broad, full 
 
 11. Ears, medium size, well carried . . • . . 
 
 12. Neck, muscled ; crest high ; throatlatch fine; windpipe 
 
 large 
 
 Forequarters : 
 
 13. Shoulders, sloping, smooth, snug, extending into back 
 
 14. Arm, short, thrown forward 
 
 15. Forearm, heavily muscled, long, wide .... 
 
 16. Knees, wide, clean cut, straight, deep, strongly sup- 
 
 ported .......... 
 
 17. Cannons, short, lean, wide ; sinews large, set back 
 
 18. Fetlocks, wide, straight, strong . . 
 
 19. Pasterns, sloping, lengthy, strong 
 
 20. Feet, large, even size, straight; horn dense, dark 
 
 color ; sole concave ; bars strong ; frog large, elastic ; 
 heel wide, high, one-half length of toe ... 
 
 21. Legs, viewed in front, a perpendicular line from the 
 
 point of the shoulder should fall upon the center of the 
 knee, cannon, pastern, and foot. From the side, a per- 
 pendicular line dropping from the center of the elbow 
 joint should fall upon the center of the knee and pas- 
 tern joints and back of hoof 
 
 Total 
 
APPENDIX 
 JUDGING S1X)CK — Continued 
 
 809 
 
 
 Perfect 
 
 Dkakt Horre — Scale of Points — For Geldin<; 
 
 Score 
 
 I>i{Ou<;nT FoKWAKi) ........ 
 
 47 
 
 Body: 
 
 
 22. Chest, deep, wide, low, large girth .... 
 
 2 
 
 2;}. EiBs, long, close, sprung 
 
 2 
 
 24. Back, straight, short, broad 
 
 2 
 
 25. Loin, wide, sliort, thick, straight 
 
 2 
 
 20. Underline, flank low . 
 
 1 
 
 Hindquarters : 
 
 
 27. Hips, smooth, wide 
 
 2 
 
 28. Crolp, long, wide, muscular 
 
 2 
 
 29. Tail, attached high, well carried ..... 
 
 1 
 
 oO. Thighs, muscular ........ 
 
 2 
 
 31. Quarters, deep, heavily muscled 
 
 2 
 
 32. Gaskins or Lower Thighs, wide, muscled . 
 
 2 
 
 38. Hocks, clean cut, wide, straight 
 
 8 
 
 34. Cannons, short, wide ; sinews large, set hack 
 
 2 
 
 35. Fetlocks, wide, straight, strong 
 
 1 
 
 36. Pasterns, sloping, strong, lengthy .... 
 
 2 
 
 37. Feet, large, even size, straight; horn dense, dark color ; 
 
 
 sole concave ; bars strong ; frog large, elastic ; heel 
 
 
 wide, high, one-half length of toe .... 
 
 6 
 
 38. Legs, viewed from behind, a perpendicular line from the 
 
 
 point of the buttock should fall upon the center of the 
 
 
 hock, cannon, pastern, and foot. From the side, a 
 
 
 perpendicular line from the hip joint should fall upon 
 
 
 the center of the foot and divide the gaskin in the 
 
 
 middle ; and a perpendicular line from the point of the 
 
 
 buttock should run parallel with the line of the cannon 
 
 4 
 
 Action : 
 
 
 39. Walk, smooth, quick, long, balanced .... 
 
 6 
 
 40. Trot, rapid, straight, regular 
 
 4 
 
 Total 
 
 100 
 
310 
 
 APPENDIX 
 JUDGING STOCK — Confmued 
 
 Light Horses — Scat.e of Points — For Gei.dini 
 
 1. Age . • 
 
 General Appearance : 
 
 2. Weight ......... 
 
 3. Height 
 
 4. Form, symmetrical, smooth, stylish 
 
 5. Quality, bone clean, fine, yet indicating sufficient suli 
 
 stance; tendons defined ; hair and skin fine 
 
 6. Temperament, active, good disposition . 
 
 Head and Neck : 
 
 7. Head, lean, straight . . . 
 
 8. Muzzle, fine ; nostrils large ; lips thin, even . 
 
 9. Eves, full, bright, clear, large .... 
 
 10. Forehead, broad, full 
 
 11. Ears, medium size, pointed, well carried, and not fa 
 
 apart 
 
 12. Neck, muscled ; crest high ; throatlatch fine; windpipe 
 
 large 
 
 Forequarters : 
 
 18. Shoulders, long, smooth with nmscle, oblique, extending 
 into back and muscled at withers .... 
 
 14. Arm, short, thrown forward 
 
 15. Forearm, muscled, long, wide 
 
 16. Knees, clean, wide, straight, deep, strongly supported 
 
 17. Cannons, short, wide ; sinews large, set back 
 
 18. Fetlocks, wide, straight 
 
 19. Pasterns, strong; angle with ground, 45 degrees . 
 
 20. Feet medium, even size, straight ; horn dense ; frog 
 
 large, elastic ; bars strong ; sole concave ; heel wide, high 
 
 21. Legs, viewed in front, a perpendicular line from the 
 
 point of the .shoulder should fall upon the center of the 
 knee, cannon, pastern, and foot. From the side, a per- 
 pendicular line dropping from the center of the elbow 
 joint should fall upon the center of the knee and pas- 
 tern joints and back of hoof ..... 
 
 Tot A L 
 
APPENDIX 
 JUDGING STOC K — Continuerl 
 
 311 
 
 I.HiiiT House — Sc.vi.k or Points — For Gelding 
 
 Brought Forward ...... 
 
 Body : 
 
 22. Chest, deep, low, large girth .... 
 
 23. Ribs, long, sprung, close ... 
 
 24. Back, straight, short, broad, niusfled 
 
 25. Loin, wide, short, thick 
 
 26. Underline, long, flank let down . 
 
 Hindquarters : 
 
 27. Hips, smooth, wide, level .... 
 
 28. Croup, long, wide, muscular .... 
 
 29. Tail, attached high, well carried . 
 
 30. Thighs, long, muscular, spread, open angled . 
 
 31. Quarters, heavily muscled, deep . 
 
 32. Gaskins or Lower Thighs, long, wide, muscular 
 
 33. Hocks, clearly defined, wide, straight . 
 
 34. Cannons, short, wide ; sinews large, set back 
 
 35. Fetlocks, wide, straight .... 
 
 36. Pasterns, strong, sloping .... 
 
 37. Feet, medium, even size, straiglit ; horn dense ; frog 
 
 large ; elastic ; bars strong ; sole concave ; heel wide, 
 high 
 
 38. Legs, viewed from behind, a perpendicular line from the 
 
 point of the buttock should fall upon the center of the 
 hock, cannon, pastern, and foot. From the side, a 
 perpendicular line from the hip joint should fall upon 
 the center of the foot and divide the gaskin in the 
 middle ; and a perpendicular line from the point of 
 the buttock should run parallel with the line of the 
 cannon 
 
 Action : 
 
 39. Walk, elastic, quick, balanced 
 
 40. Trot, rapid, straight, regular, high . . . . 
 
 Total 
 
312 
 
 APrEXDIX 
 
 JUDGING Sl'OCK — Continued 
 
 ]>EKi'' Stkeh — Scale of Point.* 
 
 2. 
 
 3. 
 
 4. 
 
 low 
 
 General Appearance : 
 1. Weight, score according to age .... 
 
 Form, straight top line and underline ; deep, broad, 
 set, stylish 
 
 Qua LIT V, hair fine ; skin i)liable ; dense, clean bone ; body 
 covering to be uniform, of a mellow touch, yet suffi- 
 ciently firm to indicate a large proportion of muscle 
 
 Condition, development of flesh and fat; fat indicated by 
 spinal covering, rib covering, fullness of flank, purse and 
 tongue root 
 
 Head and Neck: 
 
 5. Muzzle, broad ; mouth large ; jaw wide ; nostrils large . 
 
 6. Eyes, large, clear, placid 
 
 7. Face, short, quiet expression 
 
 8. Forehead, broad, full ....... 
 
 Ears, medium size, fine texture ...... 
 
 Horns, fine texture, oval, medium size .... 
 
 Nkck, thick, short, throat clean ..... 
 
 9. 
 10. 
 11. 
 
 Forequarters : 
 
 V2. Smoulder Vein, full . . . . 
 
 13. Shoulder, covered with flesh, compact on top, smooth 
 
 14. Brisket, advanced, breast wide 
 
 15. Dewlap, skin not too loose, and drooping 
 
 16. Legs, straight, short ; arm full ; shank tine, smooth . 
 
 Body: 
 
 17. Chest, full, deep, wide ; girth large ; crops full 
 
 18. KiBS, long, arched, thickly fleshed 
 
 19. Back, broad, straight, smooth, even 
 
 20. Loin, thick, broad 
 
 21. Flank, full, even with underline . . . ' . 
 
 Hindquarters : 
 
 22. Hips, smoothly covered, distance apart in proportion with 
 
 other parts ......... 
 
 Total 
 
APPENDIX 
 JUDGING STOCK — Continue^/ 
 
 313 
 
 Beek Steer — Soai.k ok Points 
 
 Perfect 
 Score 
 
 Bkouoht Fokwari) 
 
 80 
 
 Hindquarters — Cont. : 
 
 
 2o. Ulmp, loiio;. wide, even, tail head smooth, not patchy 
 
 2 
 
 24. Pin Bonks, not prominent, far apart 
 
 1 
 
 25. Thighs, full, deep, wide 
 
 2 
 
 20. Twist, deep, phimp 
 
 2 
 
 27. Purse, full, indicating fleshiness 
 
 2 
 
 28. Leos, straight, short ; shank fine, smooth .... 
 
 - 
 
 Total 
 
 100 
 
 Scale of Points — Fob Dairy Cow 
 
 Perfect 
 
 Score 
 
 General Appearance : 
 
 1. Weight 
 
 2. Form, inclined to he wedge-shaped 
 
 I). Quality, hair fine, soft ; skin, mellow, loose, medium 
 
 thickness, secretion yellow ; hone, clean, fine 
 
 4. Condition, lean, though vigorous appearance when in milk 
 Head and Neck : 
 
 5. Muzzle, clean cut ; mouth large ; nostrils large 
 
 6. Eyes, large, bright, full, mild 
 
 7. Face, lean, long, quiet expression 
 
 8. Forehead, broad 
 
 0. Ears, medium size, yellow inside, fine texture . 
 
 10. Horns, fine, texture waxy 
 
 11. Neck, fine, medium length ; throat clean, light dewlap . 
 Forequarters : 
 
 12. Withers, lean, thin 
 
 18. Shoulders, light, oblique 
 
 14. Legs, straight, short ; shank fine 
 
 
 G 
 6- 
 
 1 
 
 1 
 
 1 
 
 1 
 
 1 
 
 1 _ 
 
 1 
 
 1 
 2 
 2 
 
 Total 
 
 80 
 
;14 
 
 APPENDIX 
 JUDGING >^TOCK—ron(inued 
 
 Scale of Points — For Dairy Cow 
 
 I'kkkkct 
 
 S<oni-: 
 
 Brought Fokwaud 
 
 Body: 
 
 15. Chest, deep, low ; girth large with full fore flank 
 
 Barrel, ribs broad, long, wide apart, largj stomach 
 
 Back, lean, straight, open jointed 
 
 Loin, broad 
 
 Navel, large 
 
 Hindquarters : 
 
 Hips, far apart, level 
 
 KuMP, long, wide 
 
 Pin Bones or Thurls, high, wide apart . 
 
 Tail, long, slim, fine hair in switch . 
 
 Thighs, thin, long 
 
 Escutcheon, spreading over thighs, extending high and 
 
 wide ; large thigh ovals 
 
 26. Udder, long, attached high and full behind, extending 
 far in front and full, flexible ; quarters even and free 
 from fleshiness 
 
 Teats, large, evenly placed 
 
 ^Mammary Veins, large, long, tortuous, branched with 
 double extension ; large and numerous milk wells 
 29. Legs, straight, short ; shank flne 
 
 27. 
 
 28. 
 
 Total 
 
 10 
 10 
 
 9, 
 
 20 
 
 100 
 
STOCK DISEASES AXD EEMEDIES 
 By Dr.. II. P. Marstkli.ah, Texas A. & M. College 
 
 THE HORSE 
 
 Chronic Indigestion. — The three most common causes of 
 chronic indigestion are improper food and water, bad teeth, 
 and the presence of worms in the intestines. 
 
 Food and Water. — Animals when given faulty food or water 
 do not " do well," have an unthrifty hair coat, sweat easily, 
 and cannot stand hard work. In such cases it is well to 
 change the feed supply. 
 
 Bad Teeth. — Horses have bad teeth. Many of the common 
 defects of teeth can be detected by the ordinary observer, if 
 he will take the trouble to open the animal's mouth and inves- 
 tigate. Common defects are irregular teeth, decayed teeth, 
 teeth with sharp edges. Very often a few dollars spent in 
 having the teeth attended to Avill prolong the animal's life and 
 usefulness. 
 
 Worms. — Young horses often have worms in the intestines 
 that sap their vitality. The symptoms are the same as those 
 of poor food and water. A very safe and efficient remed}^ for 
 this trouble is a drench made of two ounces of turj^eutiue and 
 one pint of linseed oil. 
 
 Acute Indigestion: Colic. — If any of the causes of chronic 
 indigestion are severe and continued, they lead to colic, the 
 symptoms of which are those of chronic indigestion augmented. 
 Horses with colic show pain by being restless, getting up and 
 down, looking around at side and pawing and stamping. An 
 ounce of chloral hydrate in one pint of water often gives relief 
 without causing any of the deleterious effects of many other 
 remedies. 
 
 315 
 
3U) APPENDIX 
 
 Bad Eyes, — The most common disease of the eyes of horses 
 is ''moon blindness." The first attack is mistaken very often 
 for a slight injury. But the animal has from time to time, at 
 more or less regular periods, subsequent attacks, each being 
 more severe and leaving more permanent effects. This is an 
 incurable trouble and results in blindness. 
 
 Beards of grains and chaff get in the eyes of animals and 
 will cause serious injuries if not removed. A fairly satisfac- 
 tory examination can be made by turning the lids outward 
 one at a time. This will in many cases bring to view the 
 foreign body. 
 
 Feet. — The old saying, " no foot, no horse," is as true as 
 ever. Bad feet are often due to neglect of the hoofs when 
 the animal was young. If the owner would take the trouble 
 to trim the hoofs this could be avoided. If this is not done 
 they grow out of shape, forcing the animal to throw too much 
 of his weight on some one joint, tendon, or ligament, with the 
 result that it becomes inflamed and is permanently injured. 
 
 Nail Prick. — Lameness due to this common trouble is often 
 not discovered at all by the layman. The most prominent 
 symptoms besides lameness are swelling of the leg, extending 
 from below upwards, loss of appetite, and fever. A careful 
 examination of the foot will bring to view the foreign body 
 that is causing the trouble. In any case of lameness, it is icell 
 to examine the foot thoroughly. 
 
 Treatment. — Remove cause of trouble, enlarge opening and 
 fill with carbolic acid or hydrogen peroxide. Keep animal in 
 clean, dry place until it goes sound. 
 
 Lung Fever. — Lung fever is characterized by hurried respira- 
 tion, high temperature (105°-107° F.), nasal discharge of 
 rusty color, "stary " eyes, and loss of appetite. The death rate 
 in this disease is high. Death results in about six or seven 
 days. 
 
 Treatment. — There are no specific remedies, and treatment 
 should not be undertaken by laymen. 
 
APPENDIX 317 
 
 Tetanus (Lockjaw). — This is a disease from which all 
 domestic animals may suffer, and most commonly seen in the 
 horse. It is due to a germ which cannot live in the presence 
 of oxygen. It gains entrance to the animal body througli 
 punctured wounds or through those in which dirt is ground 
 into the flesh. The symptoms are a protrusion of the haw 
 from the inner angle of the eye over the ball ; straddling gait, 
 marked muscular rigidity ; the tail is carried out, ears are 
 pricked, and nostrils are distended. All of these symptoms 
 become more marked if the animal is irritated in any way. 
 
 Treatment. — Keep animal (juiet and give soft feed. As a 
 preventive in suspicious wounds, Tetanus antitoxin should 
 be given. This has only a preventive and not a curative 
 power. 
 
 Blind Staggers. — Many theories are prevalent in regard to 
 the cause of the epizootic form of this disease. One of the 
 most popular is that it is due to some mold or fungus. Ex- 
 periments carried out at the Texas Experiment Station tend to 
 disprove this idea. To the careful observer, from all data 
 available at present, it seems to be due to labor diet while 
 resting, for when work stock are used regularly in the spring 
 it disappears. 
 
 Symptoms. — The animal will not lead, and refuses to come 
 out of stable. When eating it will stop suddenly with some 
 food protruding from the mouth, remain this way for some time 
 and then start to eat again. Many do not walk straight, and 
 stand with their feet crossed. Some are so badly affected that 
 they do not show any regard for obstacles, and will walk, 
 or try to walk, through fences, stall partitions, etc. A large 
 per cent of animals that have this disease die 5 some make a 
 partial recovery, and are termed " dummies." 
 
 Prevention. — Reduce feed when animal is not working. 
 Give plenty of roughage and exercise. 
 
 Glanders. — This is an insidious disease quite hard to diag- 
 nose in chronic cases without the use of mallein, a diagnostic 
 
318 APPENDIX 
 
 agent. Acute cases have blood-stained nasal discharge, star- 
 shaped scars in nose, enlargement of glands in the hollow 
 between the jaw bones, and an unthrifty condition. In the 
 cutaneous form, or farcy, chronic ulcers are formed on the skin. 
 
 Treatment. — Incurable. It is unlawful to keep animals 
 affected in this way. 
 
 Wounds. — In none of the ailments of animals is cleanliness 
 so essential as in wound treatments. If the best results are to 
 be obtained, wounds must be kept clean and unirritaied. If 
 these conditions are provided, most wounds will heal in a 
 reasonable time, but it is often impossible to prevent the 
 entrance of dirt or pus. To remove these first wash with a 
 two per cent solution of baking soda, then a two to five per 
 cent of carbolic acid, kresol, or chloro-naphtholeum, and then 
 sift over the wounds a powder consisting of one part camphor, 
 one part alum, and four parts boracic acid. 
 
 CATTLE 
 
 Diseases of the digestive organs of cattle are very common, 
 due to the fact that these organs are taxed to their limit in 
 both milk and beef production. The organs often are only 
 overworked and will soon return to their normal conditions if 
 given a rest for a few days. Some of the most common forms 
 of indigestion are : — 
 
 Bloat, or hoven, due to a distension of the paunch with gas, 
 which is caused by fermentation of food. 
 
 Treatment. — Ordinarily, baking jKjvvder given in doses of four 
 spoonfuls will often relieve the condition. In some cases it is 
 necessary to puncture the hollow of the flank on the left side, 
 but this had best be done only by those who have had 
 experience. 
 
 Scours. — In the South, dairymen have considerable trouble 
 with calf scours. This is caused by feeding milk Avhich has 
 been acted upon by certain bacteria, which are very common 
 
APPENDIX 819 
 
 and active in a warm climate. By putting formalin in the 
 niiJk (one part formalin to 5000 parts milk) this trouble can 
 be overcome with no serious injury to the stock. Older cattle 
 sometimes have diarrhea, but this can generally be overcome 
 by regulating the diet. 
 
 Constipation. — When cattle run on dry pastures for some 
 time they often become constipated, and if they are not relieved, 
 inflammation and even death will be the result. This can be 
 relieved by giving one pound of epsom salts and one ounce of 
 ginger in one quart of rain water. 
 
 Texas Fever. — The symptoms of this disease are a yellow 
 color of white of eye, red urine, rapid emaciation, and the 
 presence of many ticks. 
 
 As cattle that are very poor cannot withstand this disease, 
 it is well, if practicable, to feed them. Reduce ticks by dip- 
 ping and rotation of pasture. 
 
 Black Leg. — Symptoms. Lameness in one leg, more often 
 hind leg, accompanied by swelling which will crackle when 
 the hand is rubbed over it, high temperature, rapid respiration, 
 muscular tremors in later stage. 
 
 This is an incurable disease when once developed. It can 
 be prevented by vaccination. 
 
 Anthrax (Charbon). — While this disease has been reported 
 more often in cattle and sheep, all domestic animals and even 
 man may contract it. 
 
 The sudden appearance, the short duration of the disease, 
 the number of animals affected, cause one to detect the disease 
 early in the outbreak. Death is so sudden that in many cases 
 the clinical symptoms are not very pronounced. However, if 
 the disease runs for several days, swellings appear on the 
 various parts of the body, neck, brisket, and abdomen. These 
 swellings are painful, hot, and hard. If incised, they appear 
 to consist of a gelatin-like material. 
 
 Treatment. — Incurable; outbreaks are, however, said to be 
 controlled bv vaccination. 
 
820 APPENDIX 
 
 Actinomycosis (Lumpy Jaw). — This disease is characterized 
 generally by enlargement in the region of the lower jaw. 
 Swelling at first is hard and painful and gradually increases 
 in size. Later it breaks in several different places, discharg- 
 ing pus with yellow grain-like particles. The disease often 
 attacks the bone itself, loosening the teeth and making it 
 impossible for the animal to eat. 
 
 Seventy per cent of the cases can be cured if treatment is 
 begun early. 
 
 Treatment. — Give two drachms of potassium iodide daily for 
 ten days ; discontinue and repeat in ten days. If necessary, 
 treat a third time. Human beings may contract this disease 
 by eating meat of infected animals. 
 
 Milk Fever. — This disease is associated with calving, and is 
 characterized by unconsciousness, manifesting itself first by 
 unsteady gait and crooked neck. Then the animal falls down 
 and may lie stretched out or with head curled around to one 
 side. Pulse and respiration are normal. 
 
 This disease is very successfully treated by inflating the 
 udder with carbolized air or oxygen. Unless the person that 
 treats the animal has some knowledge of antisepsis he will 
 infect the udder and the cow will develop garget. 
 
 Garget. — The most common disease of the udder is garget, 
 which is an infection of one or more quarters of the udder. It 
 is caused by the entrance of germs. Pus forms and the milk 
 becomes stringy. 
 
 This is a very unsatisfactory disease to treat; even when 
 relieved, it shows a tendency to return. The quarters 
 affected may be irrigated with a solution consisting of one 
 part permanganate of potash to four or five hundred parts 
 water. 
 
 Swelling or Inflammation of Udder. — When the cow is fresh, 
 swelling can be controlled by. giving her a pound of salts 
 (epsom) followed by one drachm of fluid extract of belladona 
 morninar and evening until relieved. 
 
APPENDIX 3-21 
 
 Bathe the cow's udder with a liniment consisting of four 
 parts lead water and one part laudanum. 
 
 DOGS 
 
 Rabies (Madness). — Perhaps there is no disease of domestic 
 animals that is so much dreaded and feared by people as 
 rabies, or "mad dog." This is largely due to ignorance and 
 the fact that there are many misleading and ungrounded ideas 
 in regard to it, especially the length of time it takes the disease 
 to develop. All data and experiments show that the period of 
 incubation varies from ten to sixty days. Some of the most 
 prominent symptoms are change of voice, change of disposition, 
 abnormal appetite (in post mortem, sticks, old leather, dirt, etc. 
 jire often found in the stomach), rapid emaciation, paralysis, and 
 death. In the furious form the animal shows tendency to bite, 
 wdiile in the dumb form, which is the most common, the animal 
 soon becomes paralyzed and shows no tendency to bite. 
 
 The conservative thing to do is to quarantine suspicious cases 
 securely. This will give opportunity to observe the animal. 
 If it has rabies it usually dies in the course of ten days. If 
 the animal does not die within this time, it is probably not af- 
 fected with rabies, and the knowledge of this fact will always 
 give persons that may have been bitten a great content of mind. 
 As one man remarked who had had some practical experience 
 with rabies, '•' I would not take one thousand dollars for a dog 
 that had bitten me. I would keep him and see for myself 
 if he developed the disease." 
 
 Persons that have been bitten by a rabid animal should take 
 Pasteur treatment immediately. 
 
GLOSSARY 
 
 Abdomen. The belly of an animal or hindmost part of an insect. 
 
 Acid. A sour chemical compound. 
 
 Acid phosphate. A fertilizing material made by mixing sulphuric 
 
 acid with ground bone or ground phosphate rock. 
 Alkali land. Land having salts hurtful to crops. 
 Aluminum. A white metal in clay, often separated and used in the 
 
 arts. 
 Ammonia. A compound of nitrogen and hydrogen. 
 Ammonium Carbonate. A compound of ammonia and carbonic acid 
 
 gas. 
 Analyze. To separate into elements and find the composition of. 
 Annual Plant. A plant that dies root and top the first year of its life. 
 Antagonistic. Opposed. 
 
 Anthrax. An animal disease, also called charbon. 
 Available. Capable of being used. 
 
 B 
 
 Biennial Plant. A plant liAdng two years and making seed the second 
 
 year. 
 Bisulphide of Carbon. A compound of carbon and sulphur called 
 
 '• high-life," used to kill weevils in grain. 
 Blight. A withering and drying up of plant leaves. 
 Bluestone. A compound of copper and sulphuric acid. 
 Bordeaux Mixture. A mixture of bluestone, lime, and water for 
 
 spraying. 
 Botany. A science describing plants. 
 
 Calcareous. Composed largely of calcium, or lime. 
 
 Calcium. The metal which, united with oxygen, makes Hme. 
 
 Cannon. The bone of the lower leg of the horse. 
 
 Capillary. Composed of little tubes or pores. 
 
 Carabao. Filipino name for the water buffalo. 
 
 Carbon. The main constituent of coal, charcoal, diamonds, and 
 
 wood. 
 Carcass. The dead body of an animal. 
 Casein. The part of the soHds of milk containing nitrogen, and the 
 
 main part of cheese. 
 Caterpillar. A young insect. 
 
 823 
 
324 GLOSSARY 
 
 Chemical Change. A very complete change caused by elements 
 
 uniting or separating from each other. 
 Chlorine. A gas not found pure in nature, but which when united 
 
 with the metal sodium forms salt. 
 Citrus Fruits. Acid fruits like oranges, lemons, and grape fruits. 
 Commercial Fertilizer. A fertilizer bought and sold and shipped. 
 Complete Fertilizer. A fertilizer containing nitrogen, phosphoric 
 
 acid, and potash. 
 Compound. A substance made up of two or more elements. 
 Concentrated. Strong or condensed. 
 Concentrates. Rich feeds like meal, oil cakes, or grains. 
 Contagious. Liable to spread. 
 
 Copper Acetate. A compound of copper and vinegar. 
 Cretaceous. Consisting of chalk, or lime rock. 
 
 Crossing. Mixing two varieties of plants or two breeds of animals. 
 Croup. Top of a horse's hips. 
 Crystallize. To form crystals, or grains, like sugar. 
 
 Dicotyledons. Plants having two seed leaves. 
 
 Disseminated. Scattered ab )ut. 
 
 Dodder. A parasite, growing on alfalfa and other plants. 
 
 Dormant. Sleeping. 
 
 Dual-purpose. For two purposes. 
 
 Element. The simplest form of matter, as iron or gold. 
 Ensilage. Green feed kept in a silo, or air-tight room or pit. 
 Escutcheon. The back part of udder and thighs of milk cows, where 
 
 the hair turns up instead of down. 
 Evaporate. To pass off in the air. 
 Expand. To grow larger. 
 
 F 
 
 Ferment. To sour, or change on account of ferments, or bacteria. 
 
 Fertility. Being fertile or fruitful. 
 
 Fertilizing Elements. Phosphoric acid, nitrogen, and potash. 
 
 Floats. Ground phosphate rock. 
 
 Formalin. A substance used to kill spores or fungi. 
 
 Formula. A prescription or direction for making mixtures. 
 
 Fungi. Little plants that can be seen only with a microscope. 
 
 Fungicide. Something to kill fungi. 
 
 Fungous Diseases. Diseases caused by fungi. 
 
 G 
 
 Geology. The science which describes the rocks of the earth and the 
 
 changes they have gone through. 
 Germinate. To sprout. 
 Germs. Small living beings that can be seen only with a microscope. 
 
GLOSSARY 325 
 
 Glacier. A niovino; body of ice. 
 
 Glucose. A kind of sugar that will not form grains, or crystals. 
 
 Gypsura. Land-plaster, a compound of lime and sulphuric acid. 
 
 H 
 
 Hibernate. To live over winter. 
 
 Hock. Part of the hind leg of a horse. 
 
 Host. Plant another plant or insect feeds on. 
 
 Humid. Having natural supply of water. 
 
 Humus. The partly rotted leaves, roots, and stems of plants existing 
 
 in the soil. 
 Hybridizing, The mixing or crossing of plants or animals of different 
 
 species. 
 Hydrogen. The lightest gas known, and one of the elements of 
 
 water. 
 Hygroscopic. A term used to describe the water existing in substances 
 
 supposed to be dry. 
 
 I 
 
 Infected. A plant or animal is infected when germs or spores of dis- 
 ease enter it. 
 
 Inoculation. The act of inoculating or vaccinating with germs. 
 
 Insect. An animal having six legs and having its body divided into 
 three parts. 
 
 Insecticide. Insect poisons. 
 
 Inverted. Changed, as from crystal sugar to sticky, gummy sugar. 
 
 Irrigation. Artificially supplying water to land. 
 
 Isolate. To separate from others. 
 
 K 
 
 Kerosene Emulsion. A spraying mixture of soap, water, and kerosene 
 oil. 
 
 Lactic Acid. Acid formed from milk sugar. 
 
 Larva. The grub of insects. 
 
 Layering. Making limbs of plants take root, and then transplanting. 
 
 Legumes. Plants bearing pods. 
 
 Lespedeza. Japan clover. 
 
 Lichens. Low moss-like plants growing on rocks or wood. 
 
 Lister. A plow having a double moldboard and throwing dirt both 
 
 ways. 
 Loam. A mixture of sand and clay. 
 
 M 
 
 Magnesium. A chemical element existing in all soils in combination 
 with other elements. 
 
 Magnify. To make large in appearance by means of a micro- 
 scope. 
 
326 GLOSSARY 
 
 Mammary Veins. Milk veins of a cow just forward from the udder. 
 Manganese. A metal somewhat like iron — an element. 
 Mechanical Change. Any change in a substance not as complete 
 
 as a chemical change. 
 Membranes. Thin walls or divisions. 
 
 Microscope. An instrument for making things look large. 
 Monocotyledons. Plants having one seed leaf. 
 Mulch. A cover of leaves, straw, or fine earth for the land. 
 Muriate of Potash. A compound of potash and chlorine containing 
 
 50 per cent of potash, and used as a fertilizer. 
 
 N 
 
 Nitrate of Soda. A readily soluble compound containing nitrogen. 
 Nitrogen. A chemical element composing about four-fifths of the 
 
 air. 
 Nodule. See Tubercle. 
 Nutrients. The parts of feed stuff that may nourish the animal. 
 
 O 
 
 Organic Matter. Any material that was formed from living beings, 
 such as plants and animals. 
 
 Osmosis. The mixing of liquids of different strengths through mem- 
 branes, or cell walls. 
 
 Oxygen. The gas composing about one-fifth of the air and necessar}- 
 for breathing. 
 
 P 
 
 Parasite. A plant or animal living on another plant or animal. 
 Pasterns. Part of a horse's fore leg between the hoof and the joint 
 
 above. 
 Perennial Plant. A plant living more than two years. 
 Phosphorus. The metal which forms phosphoric acid when combined 
 
 with oxygen. 
 Physical Change. See Mechanical Change. 
 Pistil. The part of the flower making the seed. 
 Pollen. The dust on the stamens of a flower that fertilizes the 
 
 seed. 
 Pollenized. Fertilized with pollen. 
 Porous. Having pores; being open. 
 Potassium. The metal which, combined with oxygen, makes 
 
 potash . 
 Prolificness. Bearing abundantly. 
 
 Propagate. To multiply by planting, transplanting, etc. 
 Protein. The constituent of food containing nitrogen. 
 Pruning. Cutting trees back, or trimming. 
 Pulverize. To crumble and make fino, 
 
 Q 
 
 Quarantine. To keep within certain limits. 
 
GLOSSARY 32T 
 
 R 
 Rabies. Madness, as in dog-. 
 Reservoir. A storage pond for water. 
 
 Rotation. A certain round, or order, for instance of crops. 
 Roughage. Coarse feed such as hay, straw, or cotton-seed hulls ; also 
 called " roughness." 
 
 S 
 
 Sanitary. Cleanly; conducive to health. 
 
 Scion. The part of a plant inserted in a stock in grafting. 
 
 Sedentary. Remaining in place. 
 
 Shredding. Tearing into fine particles. 
 
 Silicon. The metal largely composing sand. 
 
 Silo. A pit or building for preserving green feed. 
 
 Sodium. The metal forming soda when combined with oxygen. 
 
 Soiling. Growing green crops and cutting and feeding to animals. 
 
 Soluble. Dissolving in water. 
 
 Special-purpose. For one purpose. 
 
 Species. A group of plants or animals rather closely related. 
 
 Spores. Seeds of fungi. 
 
 Sport. A plant or animal quite different from its ancestors. 
 
 Spraying. Sprinkling or forcing liquids in a fine spray over plants. 
 
 Stamens. The parts of flowers furnishing pollen to fertilize the 
 pistils. 
 
 Sterilize. To kill germs, generally by heat. 
 
 Stock. Plant into which another plant is grafted or budded. 
 
 Stomata. Pores or holes in plant leaves that take in air and give off 
 water. 
 
 Stover. Dried corn stalks after the grain has been removed. 
 
 Subsoil. Part of soil under the top soil. 
 
 Succulent. Green; containing nuich water. 
 
 Sucrose. Grain or crystal sugar. 
 
 Sulphate of Potash. A compound of potash and sulphuric acid con- 
 taining 50 per cent of potash. 
 
 Superphosphate. Acid phosphate. 
 
 Terracing. Leveling land in a Avay to prevent washing. 
 
 Tetanus. A disease called lockjaw. 
 
 Thermometer. Instrument for measuring temperature. 
 
 Thorax. That part between the head and abdomen. 
 
 Tillage. Working the land. 
 
 Transplanting. Taking up and setting out plants again. 
 
 Transported. Moved from original place. 
 
 Trifolium. Having three little leaves on one stem. 
 
 Tubercle. A wart or knot or nodule on roots of leguminous plants. 
 
 U 
 Udder. The milk organs to which the teats are attached. 
 
328 GLOSSARY 
 
 Veterinary Science. The science teaching the prevention and cure 
 
 of diseases of animals. 
 Vitality. Strength to germinate and grow. 
 Vulture. A buzzard, or carrion crow. 
 
 W 
 
 Water Table. The level of standing water in the soil. 
 Withers. The high point above the shoulders of a horse. 
 
 Z 
 
 Zebu. The sacred cattle of India. 
 
INDEX 
 
 Acclimation fever, 250, 251. 
 
 Acid phosphate, 88, 89, 93, 94, 95, 
 
 97, 98. 
 Actinomj'-cosis, or lumpy jaw of 
 
 cattle, 320. 
 Alabama Experiment Station, 
 
 Depth of plowing, 107. 
 
 Experience with fertilizers, 103. 
 
 Restorative crops for oats, 159. 
 Alfalfa, 197, 198. 
 Alkali land, 17. 
 
 Angora goats, 279, 280, 282, 283. 
 Animal diseases, 250-254 ; Appendix. 
 Animal husbandry, 255-257. 
 Animal manures, 3, 95. 
 •Aimual plants, 53. 
 Anthrax or charbon of stock, 319. 
 Arkansas fruit land, 221. 
 Arkansas rice land, 163, 164. 
 Arsenate of lead, 302. 
 Artichoke, Jerusalem, 206. 
 Ash, 235. 
 Asparagus, Appendix, 295. 
 
 Bacteria, 46-51. 
 
 Effects on soils and manures, 47. 
 
 On legvimes, 48. 
 Bad teeth of horse, 315. 
 Bagasse, 175. 
 Balanced ration, 246. 
 Banana family, 297. 
 Barley, 155. 
 l^arnyard manure, 95. 
 Beans, velvet, sov, 196, 197. 
 Bees, 284, 285. 
 Beets, 298. 
 
 Beggar weed, 204, 205. 
 Bennett, Professor R. L., experiments 
 in raising early cotton, 141, 
 142, 143. 
 Bermuda grass, 208, 209. 
 Biennial plants, 53. 
 
 Birds, 133. 
 Blackberry, 66, 299. 
 Blackleg, 250, 319. 
 Black prairie, 20, 21. 
 Blight, 49. 
 
 Blind staggers of horse, 317. 
 Boll weevil, 128-134. 
 Bordeaux mixture, 303. 
 Borer, Peach, 306. 
 Budding, 62, 63. 
 Bur clover, 202. 
 Burbank, Luther, 76. 
 Butter making, 289-293. 
 
 Cabbage, 229, 230, 231, 299. 
 Cactus, feeding, 248. 
 Campbell, H. W., 108, 157. 
 Capillary attraction, 39. 
 Carbo-hydrates, 235. 
 Carbonic acid gas, 2, 6. 
 Carpet grass, 209. 
 Cattle, 263-273. 
 Celery, 216, 233, 299. 
 Chemistry of soil and products, 31-35. 
 Cherries, 62. 
 Chickens, 283, 284. 
 Chinch bug, 305. 
 Chinese, plowing land wet, 116. 
 Methods of groM'ing rice, 162. 
 Chloro-naphtholium, 318. 
 Chufa, or grass nut, 206. 
 Churn, 290. 
 
 Citrus Fruits, 224, 225. 
 Clay and clay-loam soils, 15. 
 Clover, red, mammoth, crimson, 201- 
 
 204. 
 Coast prairies, 18. 
 Coco, or nut-grass, 240. 
 Cold-frames, 230, 231. 
 Commercial fertilizers, 98-105, 
 Complete fertilizer, 93. 
 Composts and guanos, 92. 
 
 329 
 
330 
 
 INDEX 
 
 Compounding rations, 244-249. 
 
 Concentrates, 236. 
 
 Constipation of cattle, 319. 
 
 Copper acetate, 301. 
 
 Corn, 149-153. 
 
 Corn stover, 152, 153. 
 
 Shredded, 152. 
 Cotton, wliere grown, 135. 
 
 Baling, wrapping,and handling, 145. 
 
 Earliness and yield, 143. 
 
 Jvidging, 146. 
 
 Planting and cultivating, 138-141. 
 
 Size of crop, 135. 
 
 Thickness of planting, 144. 
 
 Types to plant for, 143. 
 Cotton seed, yield of products, 146- 
 147. 
 
 For feeding, 146. 
 
 For fertilizing, 95. 
 Cowpeas and peanuts, 181-185. 
 Crab grass, 213, 214. 
 Cream separator, 290, 291. 
 Crop rotation, 86-90. 
 Cross timbers, east and west, 23. 
 Crossing and hybridizing, 59, 60. 
 Crude fiber, 238, 239. 
 Cucumber family, 299. 
 Cultivating to save moisture, 43, 110. 
 Cuttings, 65, 66. 
 
 Dairv-bred steers for beef, 205, 
 
 268. 
 Dairying, 286-294. 
 Diseases of aniinals, 250-254, 315- 
 
 321. 
 Of plants, 49, 50, 300, .301. 
 Ditch, proper shape, 82, 83. 
 Dixon, David, 92. 
 Dog, 321. 
 Doura corn, 190. 
 Drainage, 82. 83. 84 
 Draining marsh and creek land, 
 
 83. 
 Dry farming, 108. 
 Dry matter, digestible nutrients, and 
 
 fertilizing matter in 100 lb. 
 
 feed stuffs, 240-243. 
 
 Earthworms, 80. 
 Eggplant, 299. 
 
 Elements, 30-35. 
 
 Elevation and productions, 28, 29. 
 
 Evaporation from earth, 42, 43. 
 
 From leaves, 41. 
 
 Produces cold, 42, 43. 
 Extensive farming, 215, 216. 
 
 Families, economic, of plants, 295- 
 
 300. 
 Fats, 234, 235. 
 Feeding animals, 234-249. 
 Feet of horses, 316. 
 Fertilizer, stimulating effects, 101, 
 
 102. 
 Fertilizer mixtures, 99, 100. 
 
 Manures and, 92-97. 
 Fertilizers, commercial, 98-105. 
 Fibrous roots, 56. 
 Figs, 221, 222, 223, 298. 
 Flies, 127, 128. 
 
 Florida beggar weed, 204, 205. 
 Florida cattle, 270, 271., 
 Flowers, 58, 59, 60. 
 FormaUn, 228, 319. 
 Fowls, poultry, 283, 284. 
 Fruits, 215-225. 
 Fungicides, 300, 301. 
 Fungous diseases, 49, 50. 
 
 Gardening, Truck, 227-233. 
 
 Geese, 284. 
 
 Georgia Experiment Station, 
 
 Experience witli rotation, 89. 
 
 Rotation subsoiling, 106. 
 Germs, Bacteria or, 46-50. 
 
 Effects on industries, 47. 
 
 Effects on soils and manures, 47. 
 Girdler, Twig, 307. 
 Glacier, 10, 11. 
 Glanders of horses, 317, 318. 
 Goosefoot family, 298. 
 Grade stock, 286, 287. 
 Grafting, 64, 65. 
 Grape, 299. 
 Grape fruit, 224. 
 Grass family, 296, 297. 
 Grasses and other forage crops, 208- 
 
 214. 
 Great plains, 22, 23. 
 Guanos and composts, 92. 
 
INDEX 
 
 3^1 
 
 Guinea and Para grasses, 212, 213. 
 
 Hairy vetch, 199. 
 
 Hams, Smithfield, 275. 
 
 Hawaii, yields of cane, 170. 
 
 Henry's feeds and feeding, 268. 
 
 Hog cholera, 253. 
 
 Hog raising, 275-279. 
 
 Horses and mules, raising, 258-262. 
 
 Host, 300. 
 
 Hotbed, 229. 
 
 Hunter, Dr. W. D., 129. 
 
 Hybrid, 60. 
 
 Improving the land, 78, 84. 
 
 Insect friends and enemies, 125- 
 
 134. 
 Insecticides, 302-304. 
 Insects, harmful, and remedies, 304- 
 
 307. 
 Indigestion, of horses, 315. 
 
 Of cattle, 318, 319. 
 Intensive farming, 215, 216. 
 Iowa Experiment Station, 268. 
 Irish potatoes, 227-229, 299. 
 Irrigation, 119-124. 
 
 Amovint of water for success, 
 
 123. 
 Arid sections, 120. 
 For rice, 119. 
 
 In humid sections, 120, 121, 
 122. 
 
 Japan clover, 210. 
 Japanese rice culture, 162. 
 Japanese persimmon, 63. 
 Jerusalem artichoke, 206. 
 Johnson grass, 210, 211, 212. 
 Judging, Cotton, 146. 
 
 Beef cattle, 312, 313. 
 
 Dairy cows, 313, 314. 
 
 Draft horses, 308, 309. 
 
 Light horses, 310, 311. 
 
 Live stock, 308-314. 
 
 Kafir corn, 190-195. 
 
 Kainit, 93. 
 
 Kansas Experiment Station, 
 
 Experiment with cattle, 268. 
 
 Subsoihng, 106. 
 
 Kerosene emulsion, 302. 
 Kinds of soil, 15-26. 
 
 Larva, I^oll weevil, 128. 
 
 Layering, 65, 66. 
 
 Legumes, bacteria on, 48. 
 
 Lily family, 297. 
 
 Lime, 33. 
 
 Lime soil, 19, 20, 21. 
 
 Lime sulphur wash, 302. 
 
 Liquid manure, 96. 
 
 Loam soil, 15. 
 
 Louisiana Experiment Station, 
 
 Depth for fertilizer, 103. 
 
 Rotation, 89. 
 Lung fever of horses, 316. 
 
 Mallein, 317. 
 
 Malley, Professor F. W., 129. 
 
 Mallow family, 298. 
 
 Mammoth clover, 203. 
 
 Manures and fertilizers, 92-96. 
 
 Materials of commercial fertilizer. 
 
 93. 
 Melilotus, 203, 204. 
 Melon wilt, 50. 
 Mexican clover, 204. 
 Milk fever of cows, 320. 
 Milo-maize, 190-195. 
 Minnesota Bulletins on beef cattle, 
 
 268. 
 Mississippi Experiment Station, 
 
 Beef cattle, 268. 
 
 Subsoihng, 106-108. 
 Mixing fertihzer, 98-101. 
 Moisture, soil, 37-41. 
 Mosquitoes, 128. 
 Muck land, need of potash, 101. 
 Mulberrv, 298. 
 Mulch, i08. 
 Mustard family, 298. 
 
 Nail prick of horse, 316. 
 Nightshade family, 299. 
 Nitrate of soda, 99. 
 Nitrogen, 33. 
 
 Nitrogen-free extract, 238, 239. 
 Nitrogen-gathering crops, 4S, 49. 
 Nodules, or tubercles, 48, 49. 
 Nutrients, 236. 
 
832 
 
 INDEX 
 
 Oats, 158. 
 
 And vetch, 159. 
 Olive familv, 300. 
 Onion, 232, 233. 
 Orange famih% 299. 
 Orcliard crops, 215-225. 
 Osmosis, 56, 57. 
 
 Palm family. 297. 
 
 Para and Guinea grass, 212, 213. 
 
 Paris green, 302. 
 
 Parsley, 299. 
 
 Pasture grasses, 208-214. 
 
 Pea family, 299. 
 
 Peach, 217-220. 
 
 Peanuts, Cowpeas and, 181-185. 
 
 Pears, 64. 
 
 Peas, 181-185. 
 
 Pecans, 223, 224. 
 
 Budding, 63. 
 Peppers, 299. 
 Perennial plants, 53. 
 Phosphoric acid, 34, 35. 
 Physics of soil, 37-44. 
 Pistil, 58. 
 
 Plant diseases, 49, 50. 
 Plant food, proportions from air, 
 
 earth, and water, 1-4, 6. 
 Plowing, Deep, 106-108. 
 
 Flat or in beds, 112. 
 
 In the fall, 113, 114. 
 
 To save moisture, 114, 115. 
 Plows, sandy land, black land, 109. 
 Plum. 62. 
 Poisoned bait, 304. 
 Pollen, 58. 
 
 PoUination, 58, 59, 60. 
 Poor land, unprofitable, 78. 
 Potash, 35. 
 
 Potassium sulphate, 99. 
 Potato, Irish, 227-229, 299. 
 
 Sweet, 176^180, 228. 
 Poultry, 283, 284. 
 Prickly pear, feeding, 248. 
 Proportions of plant food, 100. 101. 
 Protein, 234. 
 Pruning, 219. 
 Pulling fodder, 152, 153. 
 
 Quarantine Une, 251, 252. 
 
 Rape, 204. 
 Ration, 244-249. 
 
 Balanced, 246. 
 Razor-backs, 275. 
 Red lands, 20, 21. 
 Restorative crops, 88, 89 
 Rice, 162-168. 
 
 Oriental methods, 162, 163. 
 
 Products in sack of, 167, 168. 
 Rock, how made into soil, 8, 9, 10. 
 Root tubercles, 48, 49. 
 Roots, 55, 56. 
 Rotation of crops, 86-91. 
 Round bales of cotton, 142, 145. 
 Rye, 155. 
 
 Saceharimeter 172. 
 
 San Jose scale, 218, 306. 
 
 Satsuma orange, 63. 
 
 Scab, potato, 228. 
 
 Scion, 65. 
 
 Scours of calves, 318. 
 
 Seed selection, 68-77. 
 
 Semiarid soils, Arid and, 15, 16. 
 
 Sheep and goats, 279, 280. 
 
 Sirup making, 171-173. 
 
 Soil, 8. 
 
 How formed, 8, 9, 10, 11. 
 
 Light and heavy, 26. 
 Sorghums, 190-195. 
 Sport, 71, 72. 
 Spraying, 300, 301 . 
 Stamens, 58. 
 Stimulating effect of fertilizers, 101, 
 
 102. 
 Stock, 63. 
 
 Strawberries, 59, 299. 
 Subsoil, 8. 
 
 Subsoihng, 106, 107. 
 Sugar cane, 169-175. 
 
 Making sirup and sugar, 171-175. 
 Sulphur spray, 304. 
 Svmshine, its work, 33, 34. 
 Sweet potato, 176-180, 228. 
 
 Terracing, 80-82. 
 
 Texas Experiment Station, 71, 129. 
 
 Texas fever, 250, 251. 
 
 Tick, cattle, 127, 128. 
 
 Tile draining. 83, 84. 
 
INDEX 
 
 383 
 
 Tillage, 113-117. 
 Toad, 134. 
 Tobacco, 186-189. 
 
 Shade-grown, 187, 188. 
 Tomato, 229-231. 
 Turkeys, 284. 
 
 Udder of cows, Disease of, 320, 321. 
 
 Vetfh,- 159. 
 
 Vetch, hairy, see Hairy vetcli. 
 
 Vitality of seed, 70, 71. 
 
 Walnut family, 297, 298. 
 Water, forming soil, 11, 12. 
 
 Water, evaporated from soil, 42, 43. 
 
 Of soils, 37-42. 
 
 Required by crops, 37. 
 Weeds, 71. 
 Weevil, Cotton boll, 128-134. 
 
 Grain, 127. 
 Whale-oil soap, 303. 
 AVheat, 154-161. 
 
 In a barrel of flour, 157, 158. 
 Wind-blown soils, 12. 
 Wisconsin Experiment Station, 
 
 Experiment with hogs, 276. 
 Worms of horses, 315. 
 Wounds of horse, 318. 
 
 Zebu, or sacred cattle, 263, 264. 
 
MAY 38 1308 
 
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