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 ■.HffW"fl^»*r»w»>«"*** 
 

 DETERMINATIONS OF NITROGEN IN THE SOILS 
 
 OF SOME OP THE 
 
 EXPERIMENTAL FIELDS AT ROTHAMSTED, 
 
 AND THE 
 
 BEARING OF THE RESULTS ON THE QUESTION OF 
 THE SOURCES OF THE NITROGEN OF OUR CROPS. 
 
 BY 
 
 Sir JOHN BENNET LAWES, Bart., LL.D., F.R.S., F.C.S., 
 
 AND 
 
 JOSEPH HENRY GILBERT, Ph.D., F.R.S., F.C.S., F.L.S. 
 
 Bead in the Chemical Section, at the Meeting of the American Association 
 for the Advancement of Science, held at Montreal, in Augrust, 1882. 
 
 {^Reprinted, with corrections, from an uncorrected copy issued hy the Government 
 Department of Agriculture, WashingtonJ] 
 
 LONDON: 
 HARRISON AND SONS, ST. MARTIN'S LANE, 
 
 JPrinte« in ©rbinHrg ia fa pajestg. 
 
 1883. 
 
555! 
 
 <.t^ 
 
 k' 
 
 ^4 
 
 i 
 
J 
 
 CONTENTS. 
 
 Introduction 
 
 Yield op Nitrogen in different Crops 
 Yield of nitrogen in wheat and barley 
 Yield of nitrogen in root-crops 
 Yield of nitrogen in leguminous crops 
 Yield of nitrogen by a rotation of crops 
 Yield of nitrogen in the mixed herbage of grass land 
 Yield of nitrogen in MeUlotus leucantha 
 
 Summary op yield of Nitrogen in Crops.. 
 
 Sources op the Nitrogen in Crops . . 
 
 Combiiied nitrogen in rain, etc. 
 
 Other supposed sources of combined nitrogen 
 
 Do plants assimilate free nitrogen ? . . 
 Recapitulation 
 
 page 
 5 
 
 7 
 9 
 9 
 11 
 13 
 14 
 16 
 17 
 
 17 
 18 
 21 
 22 
 29 
 
 The Nitrogen op the Soil as a source op the Nitrogen of Crops £0 
 
 Nitrogen in the soils of the experimental wheat plots . . . . . . 32 
 
 Nitrogen in the soils of the experimental barley plots . . . . , . 39 
 
 Nitrogen in the soils of the experimental root-crop plots . . . . . . 40 
 
 Is THE Soil a source op the Nitrogen op the Lbguminos^ ? . . 41 
 
 Nitrogen in the soils of the experimental clover plots . . . . . 42 
 
 The soils of the MeUlotus leucantha and white clover plots . . . . 45 
 
 Nitrogen as nitric acid in the Melilotus and white clover soils . . . . 40 
 
 Nitrogen as nitric acid in other soilu and subsoils . . . . . . . . 48 
 
 Nitrogen in some of the soils of the experimental mixed herbago ])lo(8 . . 51 
 
 Source of the nitrogen of clover grown on rich garden soil . . 55 
 
 Q-ENERAL Conclusions .. ., .. .. .. - . 57 
 
 k 2 
 
 -*li..' 
 
J ,-ff' Jff-JiFJg 
 
 !■■ 
 

 DETERMINATIONS OF NITROGEN IN THE SOILS OP 
 SOME OP THE EXPERIMENTAL PIELDS AT ROTHAM- 
 STBD, AND THE BEARING OP THE RESULTS ON THE 
 QUESTION OP THE SOURCES OP THE NITROGEN OP 
 OUR CROPS. 
 
 By Sir John Bennet Lawes, Bart., LL.D., P.R.S., P.C.S., and Joseph 
 Henry Gilbert, Ph.D., P.R.S., P.C.S., P.L.S. 
 
 Introduction. 
 
 It is just about a century since the question of the sources of the 
 nitrogen of vegetation became a subject of experimental inquiry, and 
 also of conflicting opinion. It is nearly half a century since Bous- 
 singault was led by a study of the chemistry of agricultural produc- 
 tion to see the importance of determining the sources of the nitrogen 
 periodically available to vegetation over a given area of land. Some- 
 what later the Rothamsted experiments, now in their fortieth year, 
 were commenced, and in their progress many facts have been elicited 
 bearing upon the same subject. Still, almost from the date of Bous- 
 singault's first investigations, the question has been one of contro- 
 versy, and at the present time very conflicting views are entertained 
 respecting it. 
 
 Por ourselves, we have pointed out how entirely inadequate is the 
 amount of combined nitrogen coming down in the measureable 
 aqueous deposits from the atmosphere to supply the nitrogen of the 
 vegetation of a given area. Other possible supplies of combined 
 nitrogen from the atmosphere have also been considered, and pro- 
 nounced inadequate. Again, the question whether or not plants 
 assimilate the free or uncombined nitrogen of the atmosphere has 
 been the subject of laborious experimental inquiry, and also of critical 
 discussion, at Rothamsted. Finally, the question whether the stores 
 of the soil itself are an important source of the nitrogen of our crops 
 has frequently been considered. 
 
 It may at the outset be frankly admitted that so long as the facts 
 of production alone are studied, without knowledge of, or reference 
 to, the changes in the stock of the nitrogen in the soil, it would seem 
 essential to assume that a large proportion of the nitrogen of crops 
 
B 
 
 growing without any direct supply of it by manure, must be derived, 
 in some way or other, from atmospheric sources. 
 
 The assumption which is most in favour with some prominent 
 writers is, that whilst some plants derive most or all of their nitrogen 
 from the stores of the soil itself, or from manure applied to it, others 
 derive a large proportion from the free nitrogen of the atmosphere. 
 We, on the other hand, whilst freely admitting that the facts of 
 production are not conclusively explained thereby, have maintained 
 that such collateral evidence as the determinations of nitrogen in our 
 soils afford, is in favour of the supposition that the soil may be the 
 source of the otherwise unexplained supply of nitrogen. This latter 
 conclusion we have frequently stated in general terms ; but we have 
 not hitherto published the numerical results upon which it is based. 
 Fairly enough, it has been objected that such an important conclusion 
 cannot be accepted without the numerical evidence to support it. 
 Further, erroneously interpreting our statements, calculations have 
 been made to show that it is quite beyond the reach of present 
 methods of determination of nitrogen in soils to afford results 
 justifying the conclusions we have drawn. 
 
 Since this subject of the sources of the nitrogen of our crops 
 has been much discussed in America, it has been thought that it 
 would not be inappropriate tO answer the challenge by bringing for- 
 ward some of the numerical evidence we have accumulated before 
 this meeting of the American Association for the Advancement of 
 Science, and to do this is the object of the present communication. 
 
 Before calling attention to the special results in question, it will 
 be necessary, in order to convey a clear idea of the problem to be 
 solved, to recapitulate some of the important facts which have been 
 established as to the amount of nitrogen yielded over a given area by 
 different crops. 
 
 In his original inquiries, Boussingault estimated the amounts of 
 nitrogen supplied by manure, and removed in the crops, in ordinary 
 agricultural practice. This mode of estimate is also the one generally 
 adopted by others, and we have ourselves not neglected it. But it is 
 obvious that the results of experiments in which different crops have 
 been grown for very many years in succession on the same land, both 
 separately and in an actual course of rotation, and both without nitro- 
 genous manure and with known quantities of such manure, must 
 afford very important data as to the amounts of nitrogen available to 
 vegetation, from soil and atmosphere, over a given area. The 
 Biothamsted field experiments are pre-eminently adapted to provide 
 such data. Thus, wheat has now been grown for thirty-nine years 
 
in succession on the same land ; barley for thirty-one years ; wheat in 
 alternation with fallow thirty-one years ; beans for nearly thirty 
 years ; clover for many years ; turnips, sugar-beet, or mangels, nearly 
 forty years ; whilst experiments on the mixed herbage of grass land 
 have been continued for twenty-seven years, and on an actual course 
 of rotation for thirty-five years. "We have, from time to time, pub- 
 lished what we may call the nitrogen statistics of the crops so grown ; 
 and we have compared these facts of production with what is known 
 of the sources of nitrogen available to the crops. 
 
 Yield op Nitrogen in Different Crops. 
 
 The following table (I) shows the yield of nitrogen per acre per 
 annum, in wheat, barley, root-crops, beans, clover, and in ordinary 
 rotation, in each case without any nitrogenous manure. It will be 
 observed that only in the case of the root-crops is the record brought 
 down to a later date than 1875. Independently of the fact that the 
 requisite nitrogen determinations are not yet completed for the subse- 
 quent period, it has been decided that, owing to the number of very 
 exceptionally unfavourable seasons for corn crops which have occurred 
 since 1875, it would be fallacious to bring the result'' for those crops 
 in the later seasons as illustrating the falling off of yield due to soil 
 exhaustion. 
 
 n-- 
 
8 
 
 Table I. 
 
 Yield of Nitrogen per acre per anyiuin in various Crops grown at Bothani- 
 sted, without Nitrogenoiis Manure. 
 
 Crups, &c. 
 
 Wheat.. 
 
 Barley .... - 
 
 L 
 
 Boot-crops •< 
 
 Beans . . 
 
 L 
 
 Clover 
 
 ••••{ 
 
 Barley .... "I 
 Clover . . . . / 
 
 Barley. 
 
 Botation . . < 
 7 courses. ■ 
 
 Condition of Manuring, &c, 
 
 Unmanured 
 
 r 
 
 I 
 
 Complex mineral manure. 
 
 Unmanured 
 
 Complex mineral manure. 
 
 Complex mineral 
 
 Duration of Experi- 
 ment. 
 
 8 years, 1844-51 
 12 years, 1852 -'63 
 12 years, 1864-75 
 24 years, 1852-75 
 32 years, 1844-75 
 
 12 years, 1852-'63 
 12 years, 1864-75 
 24 years, 1852-75 
 
 12 years, 1852-'63 
 12 years, 1864-75 
 24 years, 1852-75 
 
 12 years, 1852-'63 
 12 years, 1864-75 
 24 years, 1852-75 
 
 'Turnips 8 years, 1845-'52 
 
 (Barley) 3 years, 1853-'55 
 
 Turnips 15 years, 1856-70* 
 
 manure "j Sugar beet ... 5 years, 1871-75 
 
 I Mangels 5 years, 1876-'80 
 
 (.Total 36 years, 1845-'80 
 
 Unmanured 
 
 Complex mineral manure , 
 
 Unmanured 
 
 Complex mineral manui'e , 
 
 Unmanured . 
 
 Unmanured . 
 
 Barley after 
 after barley . 
 
 { 
 
 f After barley . . 
 '" \ After clover . . 
 clover more than 
 
 } 
 
 1. Turnips ' 
 
 2. Barley 
 
 3. Clover or beans 
 
 4. Wheat 
 
 Unmanured . 
 
 Superphos- "I 
 
 phate .. J 
 
 12 years, 1847-'58 
 12 years, 1859-70t 
 24 years, 1847-70 
 
 12 years, 1847 -'58 
 12 years, 1859-'70t 
 24 years, 1847-'70 
 
 22 years, 1849-'70t 
 22 years, 1849-'7o| 
 
 1 year, 1873 
 1 year, 1873 
 
 1 year, 1874 
 1 year, 1874 
 
 28 years, 1848-75 
 28 years, 1847-75 
 
 Average 
 
 Nitrogen per 
 
 Acre per 
 
 annum. 
 
 lbs. 
 25-2 
 22-6 
 159 
 19 
 20' 
 
 •3 
 
 •7 
 
 27 
 17 
 22 
 
 22-0 
 14-6 
 18-3 
 
 26-0 
 18-8 
 22-4 
 
 42-0 
 (24-3) 
 18-5 
 13 1 
 15-5 
 25-2 
 
 48-1 
 14-6 
 31-3 
 
 61-5 
 29 5 
 45-5 
 
 30-5 
 39-8 
 
 37 3 
 151-3 
 
 39-1 
 69-4 
 
 30-3 
 
 36-8 
 45-2 
 
 * Thirteen years' crop, two years failed. 
 
 t Nine years' beans, one year wheat, two years' fallow. 
 
 X Six years' clover, one year wheat, three years' barley, twelve years' fallow. 
 
Yield of Nitrogen in Wheat and Barley. 
 
 The first series of results relates to the yield of nitrogen in wheat 
 grown thirty-two years in succession on the same land without 
 manure. It is seen that, over the first eight years, the yield was 
 25*2 pounds of nitrogen per acre per annum, over the next twelve 
 years 22'6 pounds, and over the last twelve of the thirty-two years 
 only 15-9. There has thus been a considerable reduction in the 
 annual yield of nitrogen over each succeeding period; and for the 
 third period of twelve years the average is less than two-thirds as 
 much as for the first period of eigh u years. 
 
 Excluding the first eight years of the growth of wheat, the 
 average annual yield of nitrogen over the next twenty-four years 
 was 19'3 pounds per acre per annum ; and the table shows that over 
 the same twenty-four years, barley without man ire yielded 18"3 
 pounds ; and whilst with the wheat the decline in yield was from 
 22'6 pounds over the first twelve of the twenty-four years to 15'9 
 over the second twelve, it was with the barley from 220 to 14'6 
 pounds, or almost in the same proportion 
 
 It might be objected that here the evidence is not conclusive that 
 the falling off is due to the gradual reduction in the amount of 
 nitrogen annually available from the soil. But the results with the 
 two crops, where there is a liberal supply of mineral constituents 
 every year, exclude the supposition that the decline is due to the 
 exhaustion of mineral constituents. Thus, over the same twenty- 
 four years, with a complex mineral manure, such as is very effective 
 in conjunction vrith artificial supply of nitrogen to the soil, the yield 
 of nitrogen in the wheat falls off from 270 pounds per acre per 
 annum over the first twelve years, to 17'2 pounds over the second 
 twelve yeara ; and in the barley, over the same two periods, it declines 
 from 26"0 to 18'8 pounds. 
 
 The similarity in the actual yield, and in the rate of decline 
 of yield, of nitrogen over the same periods in these two closely allied 
 crops, though growing in different fields, and with somewhat different 
 previous manurial history, is very striking. The slightly higher 
 yield in both cases with than without the mineral manure is doubtless 
 due to more complete utilisation of the previous accumulations 
 within the soil, and not to increased assimilation from atmospheric 
 sources. 
 
 Yield of Nitrogen in Boot-crops. 
 
 We now come to the yield of nitrogen by plants of other natural 
 families, and the first of such results relate to the so-called " root- 
 
10 
 
 crops" — turnips of the natural order Cruciferce, and sugar-beet, and 
 mangel-wurzel of the order Chenopodiaceoe. The table records the 
 results for thirty-six years in succession, 1845-18S0 ; but it should be 
 stated that during three of those years barley was interposed without 
 any manure, in order, as far as possible, to equalise the condition of 
 the land before re-arranging the manurir.g; and during two other 
 years the turnips failed, and there was no crop. It should be further 
 explained that, without manure of any kind, root-crops, after a few 
 years, give scarcely any produce at all, and hence the results selected, 
 and recorded in the table, are those obtained by the use of mineral 
 manures, but without any supply of nitrogen. 
 
 During the first eight years (four years Norfolk whites and four 
 years Swedes), the turnips gave an average of 42 pounds of nitrogen 
 per acre per annum, or very much moi'e than either of the cereal 
 crops. During the next three years barley (without manure) yielded 
 243 pounds, or even somewhat less than the yield in wheat or barley 
 with mineral manures in the earlier years of their continuous growth. 
 During the next fifteen years (thirteen with Swedish turnips and two 
 without any crop), the yield was reduced to 18*5 pounds ; during the 
 next five years, with sugar-beet, to 13"1 pounds ; and during the last 
 five years, to 1880 inclusive (with mangel-wurzel), to 15'4 pounds. 
 Lastly, over the whole thirty-six years, the average annual yield of 
 nitrogen was 25"2 pounds. 
 
 Here, then, compared with wheat or barley, we have with the 
 root-crops, the growth of which extends much further into the 
 autumn months, a much higher annual yield of nitrogen in the earlier 
 y?ars, and with this a much more rapid rate of decline subsequently, 
 the annual yield over the last ten years being only about one-third as 
 much as over the first eight years ; whilst the yield in the later years 
 is actually less than in either wheat or barley with the same complex 
 mineral manure. Here, again, the marked decline in the yield of 
 nitrogen, with liberal mineral manuring, points to a deficiency in the 
 available supply of nitrogen itself as the cause of the deficient assimi- 
 lation of it by the crop. 
 
 It may here be observed, that those who maintain that the atmo- 
 sphere is an important source of the nitrogen of our crops assume 
 that the root-crops, if provided with a small quantity of nitro^Tenous 
 manure to favour the early development of the plant, will obtain the 
 remainder from the atmosphere. How far this is the case may be 
 illustrated by the following results, which are the average of five 
 years' successive growth of mangel-wurzel on the same plots, and in 
 each case with the same manure year after year. 
 
d 
 
 le 
 
 11 
 
 Table II. 
 Averacje produce oj Mangel-wurzel Jive years, 1876 — 1880. 
 
 1. Superphosphate of lime, and sulphate potassium . 
 
 2. As 1, and 36^ lbs. ammonium salts (= 7"8 lbs. N) 
 
 3. As 1, and 400 lbs. ammonium salts (=86 lbs. N) 
 
 Boots. 
 
 Tons. 
 
 Cwt. 
 
 4 
 
 10 
 
 6 
 
 
 
 14 
 
 
 
 Leaves. 
 
 Tons. Cwt. 
 
 1 
 
 1 6 
 
 2 16 
 
 Thus, the annual application of about 7" 8 pounds of nitrogen, as 
 ammonium salts, has increased the crop of roots by only 30 cwts. per 
 acre per annum ; and the increased yield of nitrogen in the crop was 
 even somewhat less than the amount supplied in the manure. An 
 application of 86 pounds of nitrogen has, however, increased the crop by 
 160 cwts. more. It is obvious from these facts, that the small application 
 of nitrogen did not enable the plant to take up any from atmospheric 
 sources, and that it required further direct supply of nitrogen to 
 obtain further increase of crop. These results obviously aiford con- 
 firmation of the view that it was a reduction of the available supply 
 of nitrogen within the soil that was the cause of the decline in the 
 annual yield of the crop, and of the amount of nitrogen contained 
 in it. 
 
 JiJ 
 
 ^ 
 
 Yield of Nitrogen in Leguminous Crops. 
 
 We next come to the consideration of the yield of nitrogen in 
 crops of the leguminous family, when these are grown separately, 
 year after year, on the same land. Plants of this family are said to 
 rely almost exclusively on atmospheric sources for their nitrogen. 
 
 Table I shews that, without manure, beans gave over the first 
 twelve years an annual yield of 48-1 pounds of nitrogen, but over the 
 second twelve only 14-6 pounds. Over the first period, therefore, the 
 yield was about twice as much as in either wheat or barley, and more 
 even than with the roots. But with this greater yield in the earlier 
 years, the reduction is proportionally much greater over the second 
 period ; the yield then coming down to less than one-third, and to 
 much the same as in the later periods with the other crops. Over 
 the whole period of twenty-four years, however, there was an annual 
 yield of 31-8 pounds of nitrogen, or more than one and a half time as 
 much as in either wheat or barley, and more than in the roots. 
 
 It was seen that in the case of the cereal crops the mixed mineral 
 
 I 
 
12 
 
 manure increased tlie yield of nitrogen but little. Not so in tLo case 
 of the leguminous crop, beans. During the first twelve years, the 
 complex mineral manure (containing a large amount of potash) 
 yielded 61'5 pounds of nitrogen per acre per annum, against 48'1 
 pounds without manure. During the next twelve years, the mineral 
 manure gave 29"5 pounds, against only 146 pounds without manure. 
 Daring the whole period of twenty-four years, the potash manure 
 yielded 45 "5 pounds of nitrogen per acre per annum, against 
 31"3 pounds without manure. Lastly, with the mixed mineral manure 
 beaui. have yielded over a period of twenty-four years more than 
 twice as much nitrogen per ncre as either whaat or barley. 
 
 But notwithstanding that the beans have for a long series of years 
 yielded so very much more nitrogen over a given area than either of 
 the gramineous crops, and much more also than the root-crops, the 
 significant fact cannot fail to be observed that this crop of the legu- 
 minous family, which is supposed to rely almost exclusively on the 
 atmosphere for its nitrogen, has declined in yield as strikingly as the 
 other crops, even when grown by a complex mineral manure, con- 
 taining a large amount of potash. Why should this be so if the 
 supply of nitrogen is from the atmosphere and not from the soil ? 
 
 The results next recorded relate to red clover, and the period of 
 experiment was twenty-two years. It is well known that on most 
 soils a good crop of clover cannot be relied upon oftener than once in 
 about eight years, and on mauy soils not so frequently. It will not 
 excite surprise, therefore, that in the course of the twenty-two years 
 of experiment, in only six was any crop of clover obtained, and in 
 some of those only poor ones. Indeed, the plant failed nine times out 
 of ten during the winter and spring succeeding the sowing of the 
 seed. In one year a crop of wheat, and in three years barley, was 
 taken instead ; whilst in the remaining twelve years the land was left 
 fallow after the failure of the clover. Still the annual yield of 
 nitrogen over the twenty-two years was 30'5 pounds without any 
 manure, and 39"8 pounds by a complex mineral manure containing 
 potash. Unfavourable as is this result in an aj^ricultural point of 
 view, it is still seen that the interpolation of this leguminous crop has 
 greatly increased the yield of nitrogen compared with that in either 
 wheat or barley grown continuously ; and here again, as with beans, a 
 potash manure has considerable increased the yield. 
 
 The next experiment afforus a still more striking illustration of the 
 large amount of nitrogen that may be taken up in a clover crop ; and 
 it further illustrates the fact, well known in agriculture, that the 
 removal of this highly nitrogenous leguminous crop is one of the best 
 
13 
 
 possible preparations for the growth of a cereal crop, which charac- 
 teristically requires nitrogenous manuring. A field which had grown 
 six corn crops in succession, by artificial manures alone, was then 
 divided, and (in 1873) on one half barley, and on the other half 
 clover, vras grown. The barley yielded 37-3 pounds of nitrogen per 
 acre; but the three cuttings of clover yielded 151-3 pounds. In the 
 next year (1874) barley was grown on both portions of the field. 
 Where barley had previously been grown, and had yielded 37-3 pounds 
 of nitrogen per acre, it now yielded 391 pounds; but where the 
 clover had previously been grown, and had yielded 151-3 pounds of 
 nitrogen, the barley succeeding it gave 69-4 pounds, or 80-3 pounds 
 more nitrogen after the removal " 151-3 pounds in clover than after 
 the removal of only 37-3 pounds in barley. It will be seen further on 
 that this result was not in any way accidental. 
 
 Yield of Nitrogen hy a Rotation of Crops. 
 
 The last results recorded in the table relate to the yield of nitrogen 
 in an ordinary four-course rotation of — turnips, barley, clover or 
 beans, and wheat. The average yield per annum is given for seven 
 courses, or for a period of twenty-eight years ; in one case without any 
 manure during the whole of that time, and in the other with super- 
 phosphate of lime alone, applied once every four years, that is, for the 
 turnips commencing each course. 
 
 Here, with a turnip crop, and a leguminous crop, interpolated with 
 two cereal crops, we have, without manure of any kind, an average of 
 36-8 pounds of nitrogen per acre per annum, or very much more than 
 was obtained in either of the cereal crops grown consecutively. With 
 superphosphate of lime alone, which much increased the yield of 
 nitrogen in the turnips, reduced it in the succeeding barley, increased 
 it greatly in the leguminous crops, and slightly in the wheat suc- 
 ceeding them, the average annual yield of nitrogen is increased to 
 45-2 pounds, or to about double that obtained in either wheat or 
 barley grown consecutively by a complete mineral manure. On this 
 point it may be further remarked that in adjoining experiments, in 
 which, instead of a leguminous crop, the land was fallowed in the 
 third year of each course, the total yield of nitrogen in the rotation 
 was very much less. In other words, the removal of the most highly 
 nitrogenous crops of the rotation — clover or beans — was succeeded by 
 a growth of wheat, and an assimilation of nitrogen by it, almost as 
 great as when it succeeded a year of fallow ; that is, a period of some 
 accumulation by rain, &c., and of no removal by crops. 
 
14 
 
 Yield of Nitrogen in the Mixed Herbage of Grass Land. 
 
 Another illustration of the amounts of nitrogen removed from a 
 given area of land by different descriptions of crop will be found in 
 Table III, which shows the results obtained when plants of the 
 gramineous, the leguminous, and other families, are grown together, 
 in the mixed herbage of grass land. 
 
 Table III. 
 
 Yield of Nitrogen on the Mixed Herbage of Permanent Grass Land 
 
 at Rothamsted. 
 
 
 Conditions 
 
 of 
 Manuring. 
 
 Average Produce per acre 
 per annum, 20 years, 
 1856-1875, according to 
 mean per cent., at six 
 
 Average Nitrogen 
 
 per Acre 
 
 per annum. 
 
 Plots. 
 
 periods, 1862, '67, '71, 
 '72, '74, '75. 
 
 Ten 
 years 
 1856- 
 1865. 
 
 Ten 
 years 
 1866- 
 1875. 
 
 Twenty 
 
 
 Grami- 
 netB. 
 
 Legumi- 
 nosse. 
 
 Other 
 Orders. 
 
 years 
 1856- 
 1875. 
 
 3 
 4-1 
 
 8 
 7 
 
 Unmanured 
 
 Superphosphate*. . . . 
 Comp ex Min. Man.f 
 Complex Min. Man. J 
 
 lbs. 
 1635 
 1671 
 2442 
 2579 
 
 lbs. 
 219 
 149 
 296 
 
 806 
 
 lbs. 
 529 
 673 
 639 
 573 
 
 lbs. 
 35 1 
 35-7 
 54-4 
 55-2 
 
 lbs. 
 30-9 
 31-5 
 38-1 
 56 
 
 lbs. 
 33-0 
 33-6 
 46 3 
 55-6 
 
 Before referring to the figures, attention should be called to the 
 fact that gramineous crops grown separately on arable land, such as 
 wheat, barley, or oats, contain a comparatively low percentage of 
 nitrogen, and assimilate a comparatively small amount of it over a 
 given area. Yet nitrogenous manures have generally a very striking 
 effect in increasing the growth of such crops. The highly nitro- 
 genous leguminous crops, on the other hand, such as beans and 
 clover, yield, as has been seen, very much more nitrogen over a 
 given area : yet they are by no means characteristically benefited by 
 nitrogenous manuring, but their growth is considerably increased, 
 and they yield considerably more nitrogen over a given area, under 
 the influence of purely mineral manures, and especially of potash 
 
 * Mean of four separations only, namely, 1862, 1867, 1872, and 1875. 
 
 t Including potash, six years, 1856-1861 ; without potash, 14 years, 1802- 
 
 1875. 
 
 X Including potash, 20 years, 1856-1875. 
 
 ^./> 
 
15 
 
 manures. Bearing these facts in mind, the results given in the table 
 will be seen to be quite consistent. 
 
 The first three columns in the table show, approximately, how 
 the mixed herbage was made up under the four different conditions 
 of manuring. It will be observed that, without manure, and with 
 superphosphate of lime alone, both the proportion and the amount of 
 the different descriptions of herbage are much the same. Plot 8, 
 with a complex mineral manure, including potash the first six years, 
 but excluding it the next fourteen years, gave a considerable increase 
 of both gramineous and leguminous herbage ; whilst plot 7, with a 
 complex mineral manure, including potash every year of the twenty, 
 there is a still further increase of gramineous herbage, but a very 
 much greater proportional increase of leguminous herbage. 
 
 It will be observed how much greater is the increase of gramineous 
 produce by the application of purely mineral manures to this mixed 
 herbage than in tie case of gramineous crops grown separately. It 
 is a question how far this is due to the mineral manures enabling 
 the grasses to form much more stem and seed, that is, the better 
 to mature, which in fact they do ; how far to their favouring more 
 active nitrification in the more highly nitrogenous permanent mixed 
 herbage soil ; or how far to an increased amount of combined nitrogen 
 in a condition available for the grasses in the upper layers of the 
 soil, as the result of the increased growth of the Leguminos89 in the 
 first instance, induced by the potash manure, as in the case of the 
 alternation of clover and barley, and as in the actual course of 
 rotation ? 
 
 To turn to the yield of nitrogen on the different plots of the 
 mixed herbage, it will be seen that the amounts are almost identical 
 without manure, and with superphosphate of lime alone, about 
 33 pounds per acre per annum. On plot 8, where a co/nplex mineral 
 manure, including potash six years, but excluding potash fourteen 
 years, was employed, the amount is raised to 46*3 pounds ; and on 
 plot 7, which received the mixed mineral manure, including potash 
 every year of the twenty, the yield is 55'6 pounds per acre per annum. 
 Further, without manure, and with superphosphate of lime alone, 
 there was a decline in the yield of nitrogen in the later, compared 
 with the earlier years. With the mineral manure, including potash 
 in the first six yea:'S only, there was a much more marked decline. 
 With the miners nanure, including potash every year, there was, 
 on the other hand, even a slight tendency to an increased yield of 
 nitrogen in the later years. 
 
 m 
 
16 
 
 Yield of Nitrogen in Melilotus Lencantha. 
 
 One more striking illustration of high yield of nitrogen by a 
 plant of the leguminous family, this time on soil which had not 
 received any nitrogenous manure for nearly thirty years, must be 
 given. In 1878, the land upon which attempts had been made to 
 grow red clover in frequent succession since 1849, was devoted to 
 experiments with fourteen different descriptions of leguminous plants ; 
 so that the present season, 1882, is the fifth year of the experiments. 
 The object was to ascertain whether, among a selection of plants, all of 
 the leguminous family, but of different habits of growth, and especially 
 of different character and range of roots, some could be grown success- 
 fully for a longer time, and would yield more produce, containing 
 more nitrogen as well as other constituents, than others; all being 
 supplied with the same descriptions and quantities of manuring sub- 
 stances, applied to the surface soil. Further, whether the success in 
 some cases and the failure in others, would afford additional evidence 
 as to the source of the nitrogen of the Leguminosas generally, and as 
 to the causes of the failure of red clover in particular, when it is 
 grown too frequently on the same land. Fourteen different descrip- 
 tions of plants were jelected, and, after two or three immaterial 
 changes, the list at the present time includes eight species or varieties 
 of Trifoliurn, two of Medicago, Melilotus leucantha, Lotus corniculattis, 
 Vicia sativa, and Onohrychis sativa. 
 
 Of the numei'ous species or varieties of Trifoliwn, all gave but 
 meagre produce, excepting T. incarnatum. The Lotus corniculatus 
 also gave very small produce. The two species of Medicago, the black 
 Medick, and the purple MedicJc or Lucerne, and the OnohrycJiis, or 
 common Sainfoin, gave much more ; the Vicia sativa or common 
 vetch, more still. But of all, the Melilotus leucantha, or Bokhara 
 clover, has yielded the most. It is estimated that, taking the average 
 of four years, 1878-81, it yielded about 70 pounds of nitrogen per 
 acre per annum, on plots which have received no nitrogenous manure 
 for more than thirty years; whilst the produce of the fifth season, 
 1882, is heavier than in either of the preceding years ; and it is esti- 
 mated to contain about 150 pounds of nitrogen. In fact, in the 
 second, as well as in the fifth year, the melilotus yielded considerably 
 more than 100 pounds of nitrogen per acre ; and on the average of 
 the five years it has yielded between 80 and 90 pounds per acre on 
 this nitrogen-exhausted soil. 
 
 How long this very luxuriant growth,- and this very high yield of 
 nitrogen per acre, will continue, is a question of very great interest. 
 
 F 
 
 f 
 
 ^ibi> 
 
17 
 
 a 
 
 lot 
 be 
 to 
 to 
 
 its; 
 
 iits. 
 
 of 
 
 On tliis point it may be observed that, in parts of the continent of 
 Europe where some of the very free-growing and deep-rooted Legn- 
 minosaj are cultivated, it is usual to let them grow for several years, 
 after which they cannot be repeated for twenty years or more. We 
 shall recur to the result? above quoted further on. 
 
 Summary of Yield of Nitrogen in Crops. 
 
 The foregoing facts of production, showing the yield of nitrogen 
 in different crops grown without nitrogenous manure, generally for 
 very many years in succession on the same land, may be briefly 
 summed up as follows : 
 
 The average yield of nitrogen per acre per annum, was, with 
 wheat, thirty-two years without manure, 207 pounds, and twenty-four 
 years with a complex mineral manure, 22 "1 pounds ; with barley, 
 twenty-four years without manure, 18"3 pounds, and twenty-four years 
 with a complex mineral manure, 22"4 pounds ; with root-crops, thirty- 
 six years (including three of barley), with a complex mineral manure, 
 25*2 pounds; with beans, twenty-four years without manure, 31*3 
 pounds, and twenty-four years with a complex mineral manure, 45'5 ; 
 with clover, six crops in twenty- two years, with one crop of wheat, three 
 crops barley, and twelve years fallow, without manure, 30'5 pounds ; 
 with complex mineral manure, 39"8 pounds ; with clover, on land which 
 had not grown the crop for very many years, one year, 151*3 pounds ; 
 with a rotation of crops, seven courses, twenty-eight years, without 
 manure, 36'8 pounds, and with superphosphate of lime, 45'2 pounds ; 
 with the mixed herbage of grass land, twenty years without manure, 
 33 pounds, and with complex mineral manure, including potash, 55'6 ; 
 lastly, with Bokhara clover, five years, with mineral manure, between 
 80 and 90 pounds of nitrogen per acre per annum. 
 
 The root-crops yielded more nitrogen than the cereal crops, and 
 the leguminous crops very much more still. 
 
 In all the cases of the experiments on ordinary arable land — 
 whether with cereal crops, root-crops, leguminous crops, or a rota- 
 tion of crops (excepting as yet the Bokhara clover) — the decline in 
 the annual yield of nitrogen, none being supplied by manure, was very 
 great. 
 
 Sources of the Nitrogen of Crops. 
 
 We must next consider whence comes the nitrogen of the crops, 
 and especially whence comes the much larger amount taken up by 
 plants of the leguminous, and some other families, than by the 
 
 h 
 
18 
 
 Gramineae. Lastly, what is the significance of the great decline in the 
 yield of nitrogen in all the crops grown on arable land when none is 
 supplied in the manure ? 
 
 Combined Nitrogen in Bain, 8fc. 
 
 It has been assumed by some that the amount of combined nitrogen 
 annually coming down in the measured aqueous deposits from the 
 atmosphere is sufficient for all the requirements of annual growth. In 
 Liebig's earlier writings he assumed the probability of a very much 
 larger quantity of ammonia coming down in rain than he did subse- 
 quently ; but even in his more recent work, " The Natural Laws of 
 Husbandry," published in 1863, he supposes that as much as 24 
 pounds of nitrogen per acre may be annually available to vegetation 
 from that source. Such an amount would, it is obvious, do much 
 towards meeting the requirements of many of the crops the nitrogen 
 statistics of which have been given. 
 
 The earliest considerable series of determinations of the amount of 
 ammonia coming down in rain in the open countiy were by Boussin- 
 gault, in Alsace. He gives the amount of ammonia per million of 
 rain-water in each fall for a period of between five and six months, 
 May-October, 1852 ; but he does not calculate the amount so coming- 
 down over a given area of land. His average amount per million 
 was, however, somewhat less than that found at Rothamsted in 1853 
 and 1854, and found by Mr. Way in Rothamsted rain-water collected 
 in 1855 and 1856 ; which, calculated according to the rain-fall of the 
 periods, give the following amounts of nitrogen so coming down per 
 acre. The amounts of nitrogen as nitric acid, as determined by 
 Mr. Way, and the amount of total combined nitrogen as ammonia 
 and nitric acid together, are also given. 
 
 Table IV. 
 
 Nitrogen, as Ammonia and Nitric Acid, in the Rainfall 
 Year's, at Rothamsted, in Pounds per Acre 
 
 of Three 
 
 
 Rainfall. 
 
 Nitrogen per Acre, as — 
 
 Years. 
 
 Ammonia. 
 
 Nitric 
 Acid. 
 
 Total 
 Nitrogen. 
 
 1853-54 
 
 Indies. 
 29-014 
 29 166 
 27-215 
 
 lbs. 
 5-20 
 
 E-82 
 7-28 
 
 lbs. 
 (0-74) 
 0-72 
 0-76 
 
 lbs. 
 5-04 
 
 1855 
 
 6 -.18 
 
 1856 
 
 8*00 
 
 
 
 Mean 
 
 28 -465 
 
 6-10 
 
 0-74 
 
 6-84 
 
 ^ 
 
19 
 
 IS 
 
 It will be seen that, according to these results, an average of 6'84 
 pounds was contributed per acre per annum in the rain in the form 
 of ammonia and nitric acid. More recently, however. Dr. Frankland 
 has determined the amount of ammonia and nitric acid in numerous 
 samples of rain and snow water, dew, hoar-frost, &c., collected at 
 Rothamsted from April, 18G0, to ^lay, 1870, inclusive : and the average 
 amount of ammonia per million of water found by him is considerably 
 lower than the earlier determinations show. More recently .;till the 
 ammonia has been determined in the Rothamsted laboratory, in the 
 rain of each day separately (if any), for a period of six months, July- 
 December, 1881 ; also in the proportionally mixed rain for each 
 month, for a period o" thirteen months, June, 1881, to June, 1882. 
 The average proportion of ammonia in these most recent determina- 
 tions accords with the results of Dr. Frankland, and points to a 
 smaller amount of total combined nitrogen supplied per acre in the 
 average annual rainfall at Rothamsted than that recorded in the 
 table ; probably, indeed, to not more than four or five pounds of total 
 combined nitrogen per acre per annum. 
 
 Dr. R. Angus Smith, in his work entitled " Air and Rain, the 
 Beginnings of a Chemical Climatology," 1872, gives the results of 
 numerous analyses of rain-water collected both in country and 
 town districts in the United Kingdom. The amounts of ammonia 
 and nitric acid in the rain vary exceedingly, according to 1 xlity ; 
 b\it the amounts in the rain of country places accord generally with 
 those found in the Rothamsted rainfall. 
 
 The following table summarises the results of numerous determi- 
 nations made at various stations on the continent of Europe, in each 
 case extending over a whole year : — 
 
 B 2 
 
20 
 
 Table V. 
 
 Nitrogen as Ammonia and Nitric Acid in the Rain of various 
 
 Localities in Europe. 
 
 [Quantities in Pounds per Aero per Annum.] 
 
 Localities. 
 
 Euschen 
 
 Kuschen 
 
 Insterburg 
 
 Tnsterburg 
 
 Dahme 
 
 Regenwalde 
 
 Regenwalde 
 
 Regenwalde 
 
 Ida - Marienhiitte ; mean 
 
 six years 
 
 Proskaw 
 
 Florence 
 
 riorence 
 
 Florence 
 
 Vallombrosa 
 
 Montsouris, Paris 
 
 Montsouris, Paris 
 
 Montsouris, Paris 
 
 Mean, 22 years 
 
 Years. 
 
 1864-'65 
 
 1865-'66 
 
 1864-'65 
 
 1865-'66 
 
 1865 
 
 1864r-'65 
 
 1865-'66 
 
 1866-'67 
 
 1865-'70 
 1864-'65 
 1870 
 1871 
 
 1872 
 
 1872 
 
 1877-'78 
 
 1878-'79 
 
 1879-80 
 
 Rainfall. 
 
 Inches. 
 
 11 85 
 
 17-70 
 
 27-55 
 
 23-79 
 
 17 09 
 
 23-48 
 
 19-31 
 
 25-37 
 
 22-65 
 17-81 
 36-55 
 
 42 -48 
 50-82 
 79-83 
 23-62 
 25-79 
 15-70 
 
 27-03 
 
 Nitrogen as — 
 
 
 Nitric 
 
 Ammonia. 
 
 Acid. 
 
 lbs. 
 
 lbs. 
 
 1-44 
 
 0-42 
 
 1-83 
 
 0-67 
 
 3-55 
 
 1-94 
 
 4-14 
 
 2-67 
 
 5-50 
 
 1-16 
 
 10-82 
 
 4-27 
 
 8-27 
 
 2-11 
 
 13-20 
 
 3-24 
 
 13-58 
 
 7-33 
 
 9-71 
 
 3-65 
 
 7-78 
 
 2 11 
 
 9-50 
 
 3 01 
 
 7-65 
 
 2-73 
 
 10-25 
 
 1-29 
 
 7 05 
 
 4-11 
 
 4 83 
 
 5-69 
 
 •• 
 
 • • 
 
 Total. 
 
 lbs. 
 
 86 
 50 
 49 
 
 81 
 
 6-66 
 15 -09 
 10-38 
 16-44 
 
 9-92 
 20-91 
 13-36 
 
 9-89 
 12-51 
 10-38 
 
 11 
 11 
 
 54 
 16 
 
 10-52 
 10-23 
 
 It is seen that the numerous very widely varying determinations, 
 some made in the vicinity of towns and some in the open country, give 
 a mean of 10-23 pounds of combined nitrogen annually supplied per 
 acre by rain with a mean rainfall of 27-03 inches. Making all allow- 
 ance for far inland open country positions on the one hand, and for 
 proximity to towns on the other, the very small amounts of combined 
 nitrogen so supplied per acre in some of the cases, and the compara- 
 tively large quantities in others, seem difficult to explain, or to recon- 
 cile, either with one another or with the results of Boussingault and of 
 Rothamsted. When, however, the comparatively limited and uniform 
 total amounts recorded for Montsouris, within the walls of Paris, are 
 considered, 11*54 pounds, 11-16 pounds, and 10-52 pounds per acre per 
 annum, it will not excite surpi-ise that we should estimate the amount 
 of combined nitrogen coming down in the measured aqueous deposits 
 
21 
 
 from the atmosphere at probably not more than, if as much as, 
 5 pounds per aero per annum in the open country at Rothamsted. 
 
 With records of the amounts of combined nitrogen contributed to 
 a given area in rain, we come to an end of all quantitative evidence 
 as to the amount of combined nitrogen available to the vegetation of 
 a given area from atmospheric sources. It will be seen how entirely 
 inadequate is the amount probably so available to supply the quanti- 
 ties yielded in different crops grown without nitrogenous manure, as 
 recorded in Tables I and III (pp. 8 and 14). 
 
 It is true that the minor aqueous deposits from the atmosphere are 
 much richer in combined nitrogen than rain, and there can be no 
 doubt that there would bo more deposited within the pores of a given 
 area of soil than on an equal area of the non-porous even surface of a 
 rain-gauge. How much, however, of this might be available beyond 
 that determined in the collected aqueous deposits, existing evidence 
 does not afford the means of estimating with certainty. 
 
 Other Supposed Sources of Combined Nitrogen. 
 
 Further, it has been argued that, in the last stages of the decom- 
 position of organic matter in the soil, hydrogen is evolved, and that 
 this nascent hydrogen combines with the free nitrogen of the atmo- 
 sphere, and so forms ammonia. Again, it has been suggested that 
 ozone may be evolved in the oxidation of organic matter in the 
 soil, and that, uniting with free nitrogen, nitric acid would be pro- 
 duced. 
 
 We have discussed these various possible supplies of combined 
 nitrogen to the soil from atmospheric sources on more than one occa- 
 sion ; and we have given our reasons for concluding that none of them 
 can be taken as accounting for the facts of growth. Incidentally, some 
 evidence will be given further on, confirming the conclusion that any 
 such supplies are limited and inadequate. 
 
 But, if the supplies from the atmosphere to the soil itself are 
 inadequate, how about the direct supplies from the atmosphere to the 
 
 plant ? 
 
 One view which has been advocated is, that broad-leaved plants 
 have the power of taking up combined nitrogen from the atmosphere, 
 in a manner, or in a degree, not possessed by the narrow-leaved 
 gramineous plants. The only experiments that we are aware of, made 
 to determine whether plants can take up nitrogen by their leaves 
 from ammonia supplied to them in the ambient atmosphere, are those 
 of Adolph Mayer in Germany, and of Schlosing in France. Both 
 
22 
 
 found that very small qnantitics of nitrogen wcro so taken up ; but 
 both concluded that the action takes place in very immaterial degree 
 in natnral vegetation. 
 
 We have elsewhere shown that a consideration of the chemistry 
 and the physics of the subject would lead to the conclusion that the 
 plants which assimila'^e more nitrofjfen over a given area than others 
 do not do so by virtue of a greater power of absorbing already com- 
 bined nitrogen from the atmosphere by their leaves. But, apart from 
 such considerations, our statistics of nitrogen production seem to pre- 
 elude the idea tliat the broad-leaved root-crops, turnips and the like, 
 to which the function has with the most confidence been attributed, 
 take up any material proportion of their nitrogen by their leaves from 
 combined nitrogen in the atmosphere. We need only here recall atten- 
 tion to the fact that the yield of nitrogen in these crops, even with 
 the aid of a complex mineral manure, was in the later years reduced 
 to as low a point as in the cas^ of the narrow-leaved cereals. 
 
 :i 
 
 Do Plants Assimilate Free Nitrogen? 
 
 The question still remains to consider — whether plants assimilate 
 the free nitrogen of the atmo.sphero, and whether some descrijitions 
 do so in a much greatc ' degi'ee than others ? It is freely admitted 
 that if this were establisued many of our difficulties would vanish. 
 
 This question has been the subject of a great deal of experimental 
 inquiry, since the time that Boussingault entered upon it about the 
 year 1837 ; and more than twenty years ago it was elaborately investi- 
 gated at Rothamsted. 
 
 We will here give a snmmary of the very conflicting results which 
 have been published in reference to this subject, of the assimilation of 
 the free nitrogen of the atmosphere by plants, contining attention, for 
 want of space, to the three most comprehensive series of experiments 
 which have been undertaken relating to it. 
 
 Though not the first in point of date, we will first refer to the 
 experiments of M. G. Ville, the results of which led him to conclude 
 that plants do assimilate the free nitrogen of the air — a view of 
 which he has been the arch-apostle for many years, and upon which 
 ho may be said to have founded a system, in his work on " Artificial 
 Manures." 
 
 From 1849 to 1856, M. G. Ville made numerous experiments on 
 this subject. The following table (VI) gives a summary of his results, 
 and shows the special conditions of each separate series of experi- 
 ments: — 
 
23 
 
 ■bat 
 free 
 
 itrj 
 
 % 
 
 r 
 
 Table VI. 
 
 Eestilts o/M, G. Villk's Expentneiits, to determine whether Plants 
 
 assimilatii free Nitro'jen. 
 
 Plants 
 
 Nitrogen, grama. 
 
 In Seed, 
 and Ail' ; 
 
 and 
 
 Manuro, 
 
 if any. 
 
 Nitrogen 
 
 in 
 Products 
 
 tol 
 Supplied. 
 
 1849 : Car -. 
 
 •■>t of unwashed air aapphjing 0*001 
 
 gram N. as 
 
 Ammonia.* 
 
 Cress 
 
 -0260 
 0-0610 
 -0640 
 
 1470 
 0-0610 
 0470 
 
 0-1210 
 
 -0000 
 
 - -0170 
 
 5-6 
 
 Large Lupins 
 Small Lupins 
 
 
 1-0 
 
 
 0-7 
 
 
 
 
 -1550 
 
 -2580 
 
 -1030 
 
 1-7 
 
 1850: Current of unwashed air supplying 0-0017 gram N. as Ammonia. 
 
 Colza (plants) 
 Wheat 
 
 Rye 
 
 Maize 
 
 -0260 
 -0160 
 0-0130 
 
 o-02yo 
 
 -OS.-)? 
 
 1 -0700 
 0-0310 
 0370 
 0-1280 
 
 1-2660 
 
 1 0440 
 -0150 
 -0240 
 
 -0990 
 
 1 -1803 
 
 41-1 
 1-9 
 2-8 
 4-4 
 
 14-8 
 
 1851 : Current of washed air.* 
 
 Sunflower 
 
 -0050 
 -00 10 
 -0040 
 
 -1570 
 0-1750 
 0-1620 
 
 -1520 
 0-1710 
 -1580 
 
 31-4 
 
 Tobacco 
 
 43-7 
 
 Tobacco 
 
 40-5 
 
 
 
 1852 : Current of washed air.* 
 
 Autumn Colza . , 
 Spring Wheat . . 
 
 Sunflower , 
 
 Summer Colza . , 
 Summer Colza . , 
 
 0480 
 -0290 
 0-0160 
 -1730 
 -1050 j 
 
 -2260 
 0650 
 0-4080 
 -5950 
 -7010 
 
 0-1780 
 -0360 
 0-3920 
 0-4220 
 0-5960 
 
 4-7 
 2-2 
 25-5 
 3-4 
 6-7 
 
 1854 : Current of washed air (under superintendence of a C 
 
 ommission) . 
 
 Cress 
 
 -0099 
 0-0038 
 -0039 
 
 0-0097 
 -0530 
 -0110 
 
 -0-0002 
 -0492 
 0-0071 
 
 10 
 
 Cress 
 
 13-9 
 
 Cress 
 
 2-8 
 
 
 
 * Recherches Experimentales sur la Vegetation, par M. Georges Villa, Paris, 
 1853. 
 
u 
 
 Table VI. — continued. 
 
 Plants. 
 
 Nitrogen, grams. 
 
 In Seed, 
 and Air j 
 
 and 
 
 Manure, 
 
 if any. 
 
 In 
 Products. 
 
 Gain 
 
 or 
 Loss. 
 
 Nitrogen 
 
 in 
 Products 
 
 tol 
 Supplied. 
 
 1854: Current of washed air {closed, superintended by a Commission) * 
 
 Cress , 
 
 -O063 
 
 -0350 
 
 -0287 
 
 5*6 
 
 
 
 1855 and 1856 : In pure air, icith 0*5 <jra7n Nitre = 0'ub9 Nitrogen.f 
 
 Colza 
 
 0-0700 
 -0700 
 -0700 
 
 -0700]: 
 0-0660+ 
 -0680]: 
 
 -0000 
 -0-0040 
 -0-0020 
 
 1 -0 
 
 Colza 
 
 0-9 
 
 Colza 
 
 1 -0 
 
 
 
 1855 and 1856 : In free air, ivith 1 gram Nitre = 0-138 Nitrogen.f 
 
 Colza . 
 Colza . 
 Colza . 
 Colza . 
 
 0-1400 
 0-1400 
 -1400 
 0-1400 
 
 -19701 
 -3740f 
 -21601 
 -2500^ 
 
 -0570 
 -2340 
 -0760 
 -1100 
 
 1-41 
 2-67 
 1-54 
 1-79 
 
 1856: 
 
 In free air, with 0'792 gram Nitre 
 
 = 0-110 Nitrogen.f 
 
 Wheat 
 
 0-1260 
 0-1260 
 
 -2180t 
 -22401 
 
 -0920 
 0980 
 
 1-7 
 
 Wheat 
 
 1-8 
 
 
 
 1855: 
 
 In free air, with 1'72 grams Nitre - 
 
 = 0-238 Nitrogen.f 
 
 Wheat 
 
 -2590 
 
 -30801 
 
 0490 
 
 1-2 
 
 
 
 1856: 
 
 In free ai"', witS 1-765 grams Nitre 
 
 = 0-244 Nitrogeyi.f 
 
 Wheat 
 
 -2650 
 -2650 
 
 -21701 
 -3500J 
 
 -00480 
 + 0-0850 
 
 0-8 
 
 Wheat 
 
 1-3 
 
 
 
 These results, as well as those of others, we have fully discussed 
 elsewhere {Phil. Trans., 1859, aud Jour. Chem. Soc, vol. xvi, 1863), and 
 we can only very briefly refer to them in this place. 
 
 The column of actual gain or loss shows in one case, with colza, 
 a gain of more than 1 gram nitrogen ; and the amount in the products 
 is more than forty-one times as much as that supplied as combined 
 
 * Compt. rend., 1855. 
 
 t Recherches Experimcntales sur la Vegetation, 1857. 
 
 X In plants only. 
 
 1 
 
 mmmm 
 
25 
 
 3d 
 id 
 
 a, 
 ts 
 jd 
 
 nitrogen in the seed and air. The results with wheat, rye, or maize, 
 showed very much less of both actual and proportional gain. Experi- 
 ments with sunflower showed in one case thirty-fold, and with tobacco 
 in two cases more than forty-fold, as much in the products as was 
 supplied. It will be observed, however, that upon the whole M. G. 
 Ville's later experiments showed considerably less both actual and 
 proportional gain than his earlier ones. 
 
 M. G. Ville in some cases attributed the gain to the large leaf 
 surface. In explanation of the assimilation of free nitrogen by plants, 
 he calls attention to the fact that nascent hydrogen is said to give 
 ammonia, and nascent oxygen nitric acid, with free nitrogen, and he 
 asks : Why should not the nitrogen in the juices of the plant combine 
 with the nascent carbon and oxygen in the leaves ? He refers to the 
 supposition of M. De Luca, that the nitrogen of the air combines with 
 the nascent oxygen given off by the leaves of plants, and to the fact 
 that the juice of some plants (mushrooms) has been observed to 
 ozonise the oxygen of the air, and he asks : Is it not probable, then, 
 that the nitrogen dissolved in the juices will submit to the action of 
 the ozonised oxygen with which it is mixed, when we bear in mind 
 that the juices contain alkalies, and penetrate tissues, the porosity of 
 which exceeds that of spongy platinum ? 
 
 The following table (VII) summarises the results of M. Boussin- 
 ganlt. His experiments on the subject commenced in 1837, and were 
 continued at intervals up to 1858. The conditions of each set of ex- 
 periments as to soil, air, or application of manurial substances, are 
 given in the table. 
 
 Table VII. 
 
 Results of M. Boussingault's Experiments to determine whether Plants 
 
 assimilate free Nitrogen. 
 
 Plants. 
 
 Nitrogen, grams. 
 
 In Seed, 
 
 or Plants ; 
 
 and 
 
 Manure, 
 
 if any. 
 
 In 
 Products. 
 
 Gain 
 
 or 
 Loss. 
 
 Nitrogen 
 
 in 
 Produets 
 
 to 1 
 Supplied. 
 
 1837 : Burnt soil, distilled water, free air, in closed summer-house. 
 
 Trefoil 
 Trefoil 
 Wheat 
 Wlieat 
 
 0-1100 
 0-1140 
 0130 
 0-0570 
 
 0-1200 
 0-1560 
 -0400 
 -0600 
 
 + 0100 
 + 0-0420 
 -0 0030 
 + 0-0030 
 
 1-09 
 1-37 
 0-93 
 105 
 
 * Ann. Ch. Phys. [2], Ixvii. (1838). 
 
26 
 
 Table Yl\.— continued. 
 
 Plants. 
 
 Nitrogen, grams. 
 
 In Seed, 
 
 or Plants ; 
 
 and 
 
 Miinure, 
 
 if anj. 
 
 In 
 Products. 
 
 Gain 
 
 or 
 Loss. 
 
 Nitrogen 
 
 in 
 Products 
 
 tol 
 Supplied. 
 
 1838 : Conditions as in 1837.* 
 
 Peas 
 
 -0 IfJO 
 -0330 
 -0590 
 
 -1010 
 -OoGO 
 -0530 
 
 + -OooO 
 + -0230 
 -0-0060 
 
 2-20 
 
 Trefoil (Plants) 
 
 Oats (Plants') 
 
 1-70 
 0-90 
 
 
 
 1851 and '52 : Washed and iijnited lonmice with ashes, distilled ivater, 
 limited air, under glass shade, tvith Carbonic Acid.f 
 
 Haricot, 1851 
 Oats, 1851.. . 
 Haricot, 1852 
 Haricot, 1852 
 Oats, 1852... 
 
 0-0319 
 0-0078 
 0-0210 
 0-0215 
 -0031 
 
 -0340 
 0-0067 
 -0189 
 -0226 
 -0030 
 
 -0-0009 
 ■O-OOll 
 ■0-0021 
 -0-0019 
 -0-0001 
 
 0-97 
 0-86 
 0-90 
 0-92 
 0-97 
 
 1803 : Prepared pumice, or burnt brick, tvith ashes, distilled water, 
 limited air, in glass globe, ivith Carbonic Acid.i 
 
 White Lupin 
 White Lupin 
 White Lupin 
 White Lupin 
 White Lupin 
 Dwarf Haricot 
 Dwarf Haricot 
 Garden Cress 
 White Lupin 
 
 04S0 
 1282 
 0319 
 0200 
 0399 
 0354 
 0298 
 0013 
 ■1827 
 
 -04S3 
 1246 
 -0339 
 -0204 
 -0397 
 0360 
 0-0277 
 0013 
 0-1697 
 
 -H 0-0003 
 
 1- 
 
 -0-0036 
 
 0- 
 
 -0-00 10 
 
 0- 
 
 + -0004 
 
 1- 
 
 -0-0002 
 
 1- 
 
 + -0006 
 
 1- 
 
 - -0021 
 
 0- 
 
 -OOOO 
 
 1- 
 
 -0-0130 
 
 0- 
 
 -01 
 
 1-97 
 •97 
 •02 
 -00 
 •02 
 
 • •93 
 •00 
 
 193 
 
 1854: Prepared pumice with ashes, distilled, water, current of washed 
 air, and Carbonic Acid, in glazed casc.'l 
 
 Lupin 
 
 Dwarf Harir-ot 
 Dwarf Haricot 
 Dwarf Haricot 
 Dwarf Haricot 
 
 Lupin 
 
 Lupin 
 
 Cress 
 
 0196 
 0322 
 0«35 
 0339 
 0676 
 -0180 
 •0175 
 -0O16 
 
 0-0187 
 
 -0-0009 
 
 0-95 
 
 -0325 
 
 + ^0003 
 
 1-01 
 
 0:541 
 
 -f- ^0006 
 
 1-02 
 
 •0329 
 
 -0-0010 
 
 0-97 
 
 ^0666 
 
 -0-0010 
 
 0-99 
 
 1 0^0334 
 -0052 
 
 -0-0021 
 
 0-94 
 
 + 0-0006 
 
 113 
 
 * Ann. Ch. Pliys. [2], Ixix. (1838). 
 
 t Ann. Cli. Phys. [3], xli. (1854). 
 
 I Ann. Ch. Phjs., Sor. [3], xliii. (1855). 
 
 
27 
 
 Table VII. — continued. 
 
 Plants. 
 
 iV'itrogen, gram 3. 
 
 In Si!0(l, 
 
 or Plants ; 
 
 and 
 
 Manuro, 
 
 if any. 
 
 Tn 
 
 Products. 
 
 Gain 
 
 or 
 Loss. 
 
 Nitrogen 
 
 in 
 Product.s 
 
 to I 
 Supplied. 
 
 1851, '52, '53, a7id '54;: Prej^ctred soil, or pumice ivith ashes ; distilled 
 water, free air, under glazed case.* 
 
 Haricot (dwarf), 1851. 
 
 Haricot, 1852 
 
 Haricot, 1853 
 
 Haricot ( ' 
 Lupin (w ' 
 
 Lupin, I80 1 
 
 Lupin, 1851 
 
 Gars, 1852 
 
 VV'lieat, 1853 
 
 Garden Cress, 185 1. 
 
 ), 185A. ... 
 1853 .... 
 
 -0.3 19 
 0213 
 0293 
 -0318 
 0214 
 0109 
 -OSfi? 
 0031 
 -OOfi l 
 -0259 
 
 -0380 
 0-0238 
 0-0270 
 -0350 
 0256 
 -0229 
 -0387 
 0-00 it 
 -0075 
 0272 
 
 + 0-0031 
 + 0025 
 -0-0023 
 + 0-0032 
 + 0-0042 
 + 0030 
 + 0-0020 
 + 0-0010 
 + 0-0011 
 + 0.0013 
 
 •09 
 -12 
 •92 
 -10 
 -20 
 -15 
 •05 
 •32 
 •17 
 •05 
 
 1858 : Nitrate of Potassium as Ma^mre.f 
 
 Heliantlius 
 
 1 
 
 0^01 11 J 
 -025 j; 
 
 0130 
 0-0245 
 
 -0-0014 
 ■ 0^0010 
 
 0^90 
 96 
 
 The last two columns of the table (VII) show the actual and pro- 
 portional gain or loss of nitrogen in M. Boussingault's experiments. 
 It will be seen that in his earlier experiments, those in free air in a 
 summer house, the leguminous plants, trefoil and peas, did indicate a 
 notable gain of nitrogen: but, in all his subsequent experiments, there 
 was generally either a slight loss, or, if a gain, it was represented in only 
 fractions, or low units, of milligrams. After 20 years of varied and 
 laborious investigation of the subject, M. Boussingault concluded that 
 plants have not the power of assimilating the free nitrogen of the atmo- 
 sphere. And in a letter received from him as recently as 1876, after 
 discussing several aspects of the question, he says : — 
 
 " If there is one fact perfectly demonstrated in physiology, it is 
 this of the non-assimilation of free nitrogen by plants ; and I may 
 add by plants of an inferior order, such as my^oderms and mush- 
 rooms." — (Translation.) 
 
 Our own experiments on this sub'oct were commenced in 1857, 
 and a young American chemist, the late Dr. Pugh, of the Pennsylvania 
 
 * Ann. Ch. Phys., S6r. [3], xliii. (1855). 
 t Compt. rend., xlvii. (1858). 
 X Nitrogen in Seed and Nitrate. 
 
28 
 
 Table VIII. 
 
 Jlesalts of Experiments made at Bothamsted to determine whether Plants 
 
 assimilate free Nitrogen. 
 
 Nitrogen, grams. 
 
 In Seed, 
 
 and 
 Maniu-e, 
 if any. 
 
 In 
 
 Plants, 
 
 Pot, and 
 
 Soil. 
 
 Gain 
 
 or 
 Loss. 
 
 Nitrogen 
 
 in 
 Products 
 
 to 1 
 Supplied. 
 
 With NO combined Nitrogen supplied beyond that in the seed sown. 
 
 
 p 1857 
 
 f Wheat.... 
 ■< Barley .... 
 [ Barley .... 
 
 0-0080 
 -0056 
 -0056 
 
 0-0072 
 0072 
 0082 
 
 -0-0008 
 + 0-0016 
 + 0-0026 
 
 0-90 
 1-11 
 1-46 
 
 Gramineae . . . . ■ 
 
 1858 
 
 ["Wheat.... 
 •< Barley .... 
 [Oats 
 
 -0078 
 -0057 
 0-0063 
 
 0-0081 
 -0058 
 0-0056 
 
 + 0-0003 
 + 0001 
 -0-0007 
 
 1-04 
 102 
 0-89 
 
 
 1858 
 
 r Wheat .... 
 X Oats 
 
 -0078 
 0-0064 
 
 0-0078 
 0-0063 
 
 0-0000 
 -0-0001 
 
 1-00 
 0-98 
 
 
 P 1857 
 
 Beans .... 
 
 -0796 
 
 -0791 
 
 -0-0005 
 
 0-99 
 
 Leguminosee . . ■ 
 
 lt')8 
 
 f Beans .... 
 LPeas 
 
 0-0750 
 0-0188 
 
 -0757 
 -0167 
 
 + 0-0007 
 -0-0021 
 
 I'Ol 
 0-89 
 
 Other Plants . . 
 
 1858 
 
 r Buck- l 
 L wheat . . J 
 
 '0200 
 
 -0182 
 
 -0-0018 
 
 0-91 
 
 With combined Nitrogen supplied beijond that in the seed sown. 
 
 Graminese 
 
 rWheat . 
 
 l_Barley . 
 
 f Wheat. 
 
 1858 < Barley . 
 
 [ Oats . . . 
 
 1858 
 A* 
 
 Leguminossc 
 
 I 
 
 1858 
 
 1858 
 
 r Wheal. 
 < Barley . 
 L Oats . 
 
 / Peas. . . 
 \ Clover . 
 
 3ean8 . 
 
 Other Plants.. 1858 {^£; _ } 
 
 0-0329 
 0-0329 
 0326 
 -0268 
 
 -0548 
 -0496 
 0-0312 
 
 -0268 
 -0257 
 -0260 
 
 -0227 
 0712 
 
 0711 
 
 0308 
 
 0383 
 0331 
 0328 
 0337 
 
 0536 
 04G4 
 0216 
 
 0274 
 0242 
 0193 
 
 0211 
 0065 
 
 -0655 
 
 0-0292 
 
 + 0-0054 
 + 0-0002 
 + -0002 
 + -0069 
 
 -0 -0012 
 -0-0032 
 -0-0096 
 
 + 0-0006 
 -0-0015 
 -0-0062 
 
 -0-0016 
 -0 0047 
 
 -0-0056 
 
 -0-0016 
 
 16 
 01 
 01 
 25 
 
 98 
 94 
 69 
 
 02 
 94. 
 76 
 
 93 
 93 
 
 0-92 
 
 0-95 
 
 * Those experiments were conducted in the apparatus of M. G. Villa. 
 
29 
 
 State Agricultural College, devoted between two and three years to 
 the investigation at Rothamsted. The conditions of the experiments, 
 and the results obtained up to that date, are fully described in the 
 papers in the Fhilosopldcal Transactions for 1859, and in the Journal 
 of the Chemical Society in 1863, already referred to. Table VIII 
 (p. 28) summarises the results obtained. 
 
 The upper part of the table shows the results obtained in the experi- 
 ments in which no combined nitrogen was supplied beyond that con- 
 tained in the seed sown. The growth was in all cases extremely re- 
 stricted ; and the figures show that there was in no case, whether of 
 Graminese, Leguminosse, or buckwheat, % gain indicated by as much as 
 3 milligrams of nitrogen. There was in most cases much less gain, or 
 a slight loss. 
 
 The lower part of the table shows the results obtained when the 
 plants were supplied with known quantities of combined nitrogen, in 
 the form of a solution of ammonium sulphate applied to the soil. The 
 actual gains or losses rauge a little higher in these experiments, with 
 larger quantities of nitrogen involvtid ; but they are always represented 
 by units of milligrams only, and the losses are higher than the gains. 
 Further, the gains, such as they are, are all in the experiments with 
 the Gramineae, whilst there is in each case a loss with the Leguminosee 
 and the buckwheat. 
 
 It should be stated that the growth was far more healthy with the 
 Gramineae than with the Leguminosse, which are even in the open field 
 very susceptible to vicissitudes of heat and moisture, and were espe- 
 cially so when inclosed under glass sliades. It might be objected, 
 therefore, that the negative results with the Leguminosse are not so 
 conclusive as those with the Graminese. Nevertheless, we do not hesi- 
 tate to conclude from our own experiments, as Boussingault did from 
 his, that the evidence is strongly against the supposition that either 
 the Graminese or the Leguminosse assimilate the free nitrogen of the 
 atmosphere. 
 
 Recapitdlation. 
 
 In the foregoing re'smne of mostly previously recorded facts, we 
 have shown the amount of nitrogen assimilated by various crops over 
 a given area, wlien grown for many years in succession on the same 
 land without any nitrogenous manure ; that is, under conditions in 
 which the source of the nitrogen is as little as possible obscured by 
 the influence of indefinite amounts available from manure. 
 
 It has been shown that tlie determined amounts of combined nitrogen 
 annually coming down in the measured aqueous deposits from the 
 
 ^.i 
 
30 
 
 atmosphere in the open country are entirely insufficient to do more 
 than supply a small proportion of the nitrogen assimilated by crops so 
 grown. 
 
 With regar '^'^her possible supplies of already combined nitrogen 
 from the atmoH^ e to the soil, it has been pointed out that there is 
 no direct quantitative evidence at command, and that such evidence 
 as docs exist leads to the conclusion that such supplies are very limited 
 and inadequate. 
 
 The same may be said, even in a greater degree, of the supposed 
 combination of the free nitrogen of the air within the soil ; also of 
 the supposition that plants take up any material jjroportion of their 
 nitrogen from combined nitrogen in the atmosphere by their leaves. 
 
 Finally, it has been concluded that the balance of direct experi- 
 mental evidence is decidedly against the supposition that plants 
 assimilate the free nitrogen of the atmosphere. Indeed, the strongest 
 argument that we know of in favour of such a supposition is that, in 
 defect of other conclusive evidence, some such explanation of the 
 facts of production would seem to be needed. 
 
 W'i 
 
 The Nitrogen of the Soil as a Soukce of the Nitrogen of 
 
 Crops. 
 
 We now turn to that part of the subject which it is the special 
 object of this communication to bring furward, namely, the determi- 
 nations of nitrogen in the soils of some of the experimental fields at 
 Rothamsted, the yield of nitrogen in which has been given, and to 
 show the bearing of the results on the question of the sources of the 
 nitrogen of the crops. 
 
 We have no wish or intention to ignore the difficulties inherent in 
 the treatment of the subject from this point of vicAv. The difficulty 
 of the problem will at once be recognised when it is borne in mind 
 that a difference of 0"001 in the percentago of nitrogen in the dry soil 
 may represent a difference of from 20 to 25 pounds of nitrogen per 
 acre in a layer of 9 inches in depth. Again, it is farther to be borne 
 in mind that, in the case of the Rothamsted arable soils with which 
 we have to deal, the percentage of nitrogen in the first 9 inches of 
 depth is sometimes only about 0"1, and seldom exceeds 0'14 or 0'15 ; 
 that in the second 9 inches it ranges from under 0'07 to little over 
 0-08; in the third 9 inches from under 006 to about 0'07; and that 
 in the lower depths is rather lower still. 
 
 It will be seen, therefore, that if any quantitative estimates are to be 
 based on the percentage amounts of nitrogen determined in samples 
 
31 
 
 I 
 
 of soil from different depths, the greatest care must be taken to insure 
 that the samples truly represent the exact depth supposed. The mode 
 usually adopted of taking samples of an indefinite area, perhaps not 
 to a definite depth, and ahncsfc certainly not of uniform breadth or 
 width to the depth taken, is obviously quite inapplicable for the 
 purposes of any such inquiry as tliat here supposed. 
 
 Another difficulty is that, in the case of subsoils, with a low actual 
 percentage of nitrogen, the variations in the amount in different 
 samples are often proportionally great, and obviously unconnected 
 with the special history of the plot. 
 
 Unfortunately, the few samples of soil that were collected in the 
 early years of the Rothamsted field experiments were not taken in 
 such a manner as to afford results applicable to our purpose. Com- 
 mencing in 1856, however, the mode adopted has been, after carefully 
 levelling the soil, to drive down a square frame, made of strong sheet- 
 iron, open at top and bottom, and of an exact area, and of an exact 
 depth, to the level of the surface. The inclosed soil is then carefully 
 taken out, and its weight determined. The soil around the frame is 
 then removed to the level of its lower edge, aiid it is again driven 
 down, and the inclosed soil removed ; and this process is repeated 
 until the desired depth of sampling is reached. 
 
 Of surface soils, samples are taken from three, four, or as many as 
 eight places on the same plot. A portion of each such sample is kept 
 separate, as a means of testing the range of variation, and, if need be, 
 of correction in case of any abnormal results due to accidental animal 
 droppings, or other causes. Another portion of each separate sample 
 of the surface soil is used to make a mixture of all. In the case of the 
 subsoils, the separate samples of corresponding depth from the same plot 
 are, as a rule, at once mixed. Surface soils are sometimes taken of an 
 area of 12 by 12 inches, but frequently of only 6 by G inches, and 
 subsoils almost invariably of the smaller area. The depth of each 
 sample is generally 9 inches ; but in some special cases it has been 
 only 3 inches, and in some 6 inchcF. It is perhaps to be regretted 
 that the depth originally fixed upon did not more nearly represent that 
 to which the soil is more directly affected by the mechanical operations, 
 and by the application of manure, say G inches. But having originally 
 adopted 9 inches, it has been necessary to adhere to this depth sub- 
 sequently, in order, as far as possible, to obtain comparable results at 
 different dates. 
 
 The soils when brought to the laboratory are first broken up, and 
 then partially dried in a stove-room at a temperature of about 130° F., 
 to arrest nitrification, which would be liable to take place if the soils 
 
Ill 
 
 I: I 
 
 32 
 
 were moist. Next, the stones are removed ; first those retained by a 
 sieve of 1-inch mesh, next by a sieve of one. half-inch mesh, and then 
 by a one-foarth-inch sieve. All that passes the ono-fourth-inch sieve 
 is termed the mould. Portions of this are very finely powdered and 
 sifted for analysis ; and the weights being recorded at each stage of 
 preparation, and the water lost on drying at 100° C. being determined 
 on the finely-powdered mould, all results of analysis are calculated 
 into percentage on the so-determined dry mould. From the same data 
 the amount of dry mould per acre is calculated, and upon this the 
 amount of nitrogen per acre. It will be seen further on, that not- 
 withstanding the means adopted to secure uniformity, the amounts of 
 dry mould per acre calculated for a given depth, from the samples 
 taken, vary considerably for the same field at diffc'rent times, accord- 
 ing to the dryness or wetness of the season, the condition of the land 
 as affected by the crop, the mechanical operations, and other circum- 
 stances. The amounts also vary very considerably for the soils of 
 adjoining fields. 
 
 Nitrogen in the Soils of the Experimental Wheat Plots. 
 
 The first series of determinations of nitrogen to which attention 
 will be called relates to those made in the soils of some of the plots of 
 Broadbalk field, which has now grown wheat for thirty-nine years in 
 succession, and the yield of nitrogen in which, on the plots receiving 
 no nitrogen in manure, has been given in Table I. It will be remem- 
 bered that, under those conditions, there was a very marked decline 
 in the annual yield of nitrogen in the crop, both without any manure, 
 and with a mixed mineral manure used alone. 
 
 The first wheat crop of the series was harvested in 1844, and 
 although isolated samples of the soil were taken in the early years, it 
 was not until 1856 that any were collected on the plan now followed. 
 At that date only four plots were sampled, and only to the depth of 
 the first 9 inches. Eight samples were, however, taken from each 
 plot, each 12 by 12 inches area, and the eight were mixed together. 
 In 1865, samples were taken from eleven plots, from eight places on 
 each plot, each sample 12 by 12 inches area, and this time to a depth 
 three times 9 inches, or to a total depth of 27 inches. Lastly, in 1881, 
 twenty plots were sampled ; six samples, each 6 by 6 inches area, 
 were taken from each plot, and in each case to three depths of 9 inches 
 each, or in all to 27 inches. 
 
 Thus, it is only in 1865 and 1881 that we have any considerable 
 series of samples, and the nitrogen determined in them ; that is, in 
 1865 after the twenty-second, and in 1881 after the thirty-eighth 
 
 M/' 
 
83 
 
 a 
 m 
 
 re 
 
 id 
 
 of 
 ed 
 
 crop had been removed. It is obvious that, if tho results at these 
 two periods are to be compared, we must first determine whether the 
 samples taken represent layers of equal depth and weight in the two 
 cases. Confining attention on the present occasion to the results 
 relating to the first 9 inches of depth, the following figures show the 
 average weight of dry mould per acre ; that is, of soil excluding 
 stones and moisture, calculated from the weight of the samples taken, 
 and from the results of the mechanical separation, and of the deter- 
 mination of moisture in the soils. For 18G5, tho calculations are 
 based on the results afforded by 80 samples, eight from each of ten 
 of the eleven plots, the eleventh being the one annually receiving 
 farmyard manure ; and for 1881 they are based on the results relating 
 to 114 samples, that is, six samples each from 19 plots, again 
 excluding the one with farmyard manure. 
 
 Number of Samples. 
 
 1865, 10 plots, 8 samples from eacli 
 1881, 19 plots, 6 samples from each 
 
 Calculated 
 
 dry Mould 
 
 per Acre. 
 
 lbs. 
 2,299,038 
 2,552,202 
 
 ITU 
 
 s 
 
 Tho importance of taking samples of definite area and depth, and 
 of determining the weights, is here strikingly illustrated. Thus, it is 
 obvious that the samples analysed in 1881 represented, on the average, 
 almost exactly one-ninth more soil per acre than those analysed in 
 1865. In other words, if the samples of 1865 fairly represented 
 9 inches of depth in the average condition of consolidation of the soil, 
 those of 1881 represented 10 inches of soil in the same condition : 
 that is, they included 1 inch more of subsoil, with its much lower 
 percentage of nitrogen than the 9 inches above it. It may, of course, 
 be a question whether the condition of consolidation of the soil was 
 the more normal at the one period or at the other. It would, how- 
 ever, make scarcely any difFerence in the relation of the results to one 
 another at the two periods, whether the actually determined per- 
 centas-es of nitroeren in the 1865 samples were lowered, on the 
 assumption that they should have included 1 inch more of subsoil, or 
 whether the determined percentages in the 1881 samples are raised, 
 on the assumption that they contained 1 inch too much of subsoil. 
 We have concluded, from a consideration of all the facts afc command, 
 that the latter alternative is upon the whole the best. We adopt, 
 
 c 
 
 m/ 
 
34 
 
 therefore, the percentages of nitrogen as actually determined in the 
 166;') samples, and we assume the weight of dry mould (9 inches deep) 
 represented by the samples to be 2,300,000 pounds per acre. But, in 
 the case of the 1881 samples, we assume that one-tenth of the heavier 
 weight had the composition determined iu the second 9 inches (it 
 would be very slightly higher), and the percentage in the remaining 
 nine-tenths, representing 2,300,000 pounds of surface soil, is raised by 
 calculation accordingly. 
 
 The following table (IX, p. 35) gives for the surface soils (9 inches 
 deep), of the unmanured plot, and the nine artificially manured plots, 
 sampled in 1805, the actually determined percentages of nitrogen in 
 the dry mould ; and for the 1881 samples from the same plots, it gives 
 both the actually determined percentages, and the corrected percentages 
 calculated as above described. The table also shows the amount of 
 nitrogen per acre, reckoning 2,300,000 pounds of dry mould, calculated 
 for 1805 according to the actually determined percentages, and for 
 1881 according to the corrected percentages. The quantities per acre 
 more ( + ), or less ( — ), in 1881 than in 1805 are also given. Lastly, 
 for each period, there are given the quantities more or less on each of 
 the other plots than on plot 5a, which received the mineral manure 
 alone. 
 
 As already said, in 1865 the land had grown twenty-two crops of 
 wheat in succession, and in 1881 thirty-eight crops. Plot 3 had been 
 unmanured from the commencement. Plot lOci received mineral 
 manure in the first year, but the ammonium salts alone each year 
 since. The remaining plots were somewhat variously manured during 
 the first eight of the thirty-eight years ; but (excepting plot 16) each 
 has been manured every year for the last thirty of the thirty-eight 
 years, as described in the table. 
 
 It will be observed that, for every plot, the actual determinations 
 show a lower percentage of nitrogen in 1881 than in 1865, The cor- 
 rected percentages for 1881 are, of course, all rather higher than the 
 actual determinations ; and they, in some cases, show a higher, and in 
 others a lower, percentage than in 1865. Nevertheless, it cannot fail 
 to be noted that the relation of plot to plot is essentially accordant at 
 the two periods. 
 
 The significance of the results will, however, be rendered the more 
 appai'ent on an examination of the calculated quantities per acre. It 
 is obvious that absolute accuracy cannot be claimed for such figures, 
 but the general accordance of the indications at the two periods is 
 such as to leave no doubt of their import. 
 
 Keeping in view the special object of this communication, which 
 
35 
 
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36 
 
 is to show tho bearing of what may bo called the nitrogen statistics of 
 the soils, on tho question of the sources of tho nitrogen in the crops, it 
 will be seen that, during tho sixteen years from 180-5 to 1881, both 
 the unraanured plot (;J),aiul tho mineral manured plot (5a), tho yield 
 of nitrogen in tho crops of which declined so sti-ikingly, show a groat 
 reduction in tho stock of nitrogen in the surface soil. The reduction 
 in these later years is considerably greater in tho surface soil of tho 
 mineral manured than in that of tho entirely unmanured plot, tho 
 previous accu.nulation in which had been many more years subject to 
 exhaustion. Taking tho results, however, for the first, second, and 
 third 9 inches, tlie calcnlatcd loss to the depth of 27 inches is approxi- 
 mately the same for tho two plots. The figures recorded for tho first 
 9 inches only are, however, sufficient to show that tho decline in tho 
 yield of nitrogen in the crop, where none has been supplied in manure, 
 is accompanied by a decline in the stock of nitrogen in the soil. 
 
 A further illustration on this point is afforded by tho results for 
 plot lOa. For tho thixteen years, 1852 — 1864, plot 16 received, 
 besides the mixed mineral manure, twice as much ammonium salts as 
 any of the other plots, tho results for which arc given in the table ; 
 and it gave on the average of those years 30| bushels of grain ^er 
 acre per annum. Since 18G4, however, the plot has been left un- 
 raanured, and during the seventeen years, 1865 — 1881, it has yielded an 
 average of only 14f bushels of grain; and in recent years the produce 
 has been very little more than witliout manure, or with purely 
 mineral manure. The table shows that in 1865, that is, after one 
 crop had been removed since the application of the excess of ammo- 
 nium salts, the surface soil still contained considerably more nitrogen 
 than any other plot in the series. In 1881, however, after sixteen 
 years more of cropping without manure, the stock of nitrogen on tho 
 plot was reduced by a greater amount than on any other plot, and to 
 a lower point than on any other of the ammonium plots, excepting 
 plot 10 with the ammonium salts alone. 
 
 Let us now refer to the last three columns in the table, which 
 show, for each of the plots receiving ammonium salts, the amount of 
 nitrogen per acre in the surface soil, more or less than in that of plot 
 5a, with mineral manure alone. All the plots, 7 to 14 inclusive, 
 received the same quantity of nitrogen, namely 86 pounds per 
 acre per annum. But it will be seen that the excess of nitrogen in 
 the surface soils compared with the mineral manured plot 5, varies 
 exceedingly. In fact, it is obvious that the amounts have no direct 
 relation to the amount of nitrogen supplied in the manure. 
 
 The following table (X) will afford some explanation of the diffei'- 
 
 M4^ 
 
of 
 
 37 
 
 ences. Tho plots under considoration, all of which received the same 
 amount of nitrogen in manure, are there given in tlie order of their 
 average annual increased yield of nitrogen in the crops over plot 5. 
 The first column shows the estimated average annual increased yield of 
 nitrogen per acre in the crops ; the second, the estimated annual loss 
 of nitrogen as nitric acid by drainage ; the tliird, the estimated pnnual 
 excess of nitrogen in the surt'ace soil over that on plot 5 with tho 
 mineral manure alone ; and the last column shows the relation which 
 that excess in tho soil bears to 100 increased yield of nitrogen in the 
 crops 
 
 Tahlk X. 
 .Estimated Nitrojen j)er Aero per Annum, 
 
 
 
 
 
 In 
 
 Excess 
 
 
 
 In 
 
 Loss by 
 
 Surface 
 
 in Sur- 
 
 PlotB. 
 
 
 Crops 
 
 Drainage 
 
 Soil 
 
 face Soil 
 
 
 over 
 
 over 
 
 9 inches 
 
 to 100 
 
 
 
 Plot 5. 
 
 Plot 5. 
 
 deep, over 
 
 increase 
 
 
 
 
 
 Plot 5. 
 
 in Crop. 
 
 
 
 lbs. 
 
 lbs. 
 
 lbs. 
 
 lbs. 
 
 10 
 
 Ammonia salts = 8G lbs. nitrogen 
 
 
 
 
 
 
 (1845 and since) 
 
 12-4 
 
 31-2 
 
 4-8 
 
 38-7 
 
 11 
 
 Ammonia salts = 8G lbs. nitrogen 
 
 
 
 
 
 
 and suporpliosphato 
 
 17-7 
 
 28-5 
 
 11 -G 
 
 G5-5 
 
 12 
 
 Ammonia salts = 80 lbs. nitrogen 
 
 
 
 
 
 
 superphosphate and soda 
 
 22-2 
 
 24 -5 
 
 14-0 
 
 G5-8 
 
 13 
 
 Ammonia salts = 80 lbs. nitrogen 
 
 
 
 
 
 
 siiporpliospliate and potash .... 
 
 23-4 
 
 25-0 
 
 17-8 
 
 76-1 
 
 14 
 
 Ammonia salts = 80 bs. nitrogen 
 
 
 
 
 
 
 superphosphate and magnesia . . 
 
 24-1 
 
 27-5 
 
 15-5 
 
 G4-3 
 
 7 
 
 Ammonia salts = 80 lbs. nitrogen 
 
 
 
 
 
 
 and mixed mineral manure .... 
 
 25-9 
 
 19 
 
 19-3 
 
 74-5 
 
 9 
 
 Nitrate soda = 80 lbs. nitrogen 
 
 
 
 
 
 
 and mixed mineral manure .... 
 
 26-5 
 
 23-7 
 
 18 -5 
 
 71-2 
 
 It is seen that tho increased yield of nitrogen in the crops also 
 varied exceedingly with the same amount supphed in manure, accord- 
 ing to the condition as to supply of mineral constituents. Plot 10, 
 with the ammonium salts alone, gives the smallest increased yield of 
 nitrogen in the crop ; and plots 7 and 9, with the most complete 
 mineral manure, each more than twice as much; the other plots 
 giving intermediate amounts. 
 
 The order of the estimated loss of nitrogen by drainage is almost 
 the converse of that of the increased yield in the crops. Plot 10, 
 which gives the least increased yield in the crop, shows the greatest 
 
 <c 
 
38 
 
 loss by drainage ; and plots 7 and 9, which yield the greatest 
 increase in the crop, show the least loss by drainage. 
 
 The excess in the soils (over plot 6) is obviously much more in 
 the order of the increased yield in the crops. Plot 10, with the 
 least in the increase of crop and the most in the drainage, shows the 
 least excess in the soil ; whilst plots 7 and 9, with, the greatest 
 increased yield in the crop, and the least loss by drainage, show the 
 greatest excess in the soil. 
 
 It is clear, therefore, that whilst the excess in the soil has no 
 direct relation to the amount supplied in the manure, it has a very 
 obvious relation to the increased yield in the crop ; in other words, to 
 the amount of growth. The last column of the table brings this 
 out more clearly. Excepting in the case of plot 10, with the ammo- 
 nium salts alone, there is a general uniformity in the proportion 
 of the excess in the soil over plot 5 to the increased yield in the 
 crop over plot 5 ; and the variations, such as they are, have an 
 obvious connection with the conditions of growth. Thus, plots 11, 
 12, and 14, all with a deficient supply of potash, show approximately 
 equal proportions retained in the soil for 100 of increase in the crop. 
 Plots 13, 7, and 9, again, all with liberal supplies of potash, show 
 higher, but approximately equal, proportions retained in the surface 
 soil for 100 of increased yield in the crop. 
 
 Upon the whole, it is obvious that the relative excess of nitrogen 
 in the soils of the different plots is little, if at all, due to the direct 
 retention by the soil of the nitrogen of the manure, but is almost 
 exclusively dependent on the dift'erence in amount of the residue of 
 the crops — of the stubble and roots, and perhaps of weeds. 
 
 Recurring to the main point which it is our object to elucidate, 
 there can be no doubt that the determinations of nitrogen in the sur- 
 face soils of the plots of the experimental wheat field, at different 
 dates, establish the fact that the decline in the yield of nitrogen in 
 the crops, when none is supplied in manure, is accompanied by a 
 decline in the stock of nitrogen in the soil. 
 
 It will be well to consider, as far as the data at command will 
 allow, what relation the yield of the nitrogen in the crops bears to 
 the loss of nitrogen by the soil ? 
 
 On this point it may be stated that, taking the average of thirty 
 years, 1852 — 1881, it is estimated that the nnmanured plot yielded 
 18'6 pounds of nitrogen in the crops, and lost 10"3 pounds in the 
 drainage, or in all 289 pounds per acre per annum over that period. 
 In like manner, it is estimated that plot 6, which received nitro- 
 genous as well as mineral manure during the preceding eight yeais. 
 
39 
 
 in 
 ho 
 he 
 
 est 
 ihe 
 
 bat mineral manure alone during the thirty years, yielded an average 
 of 20*3 pounds of nitrogen in the crops, and 12 pounds in the drain- 
 age, or in all 32 "3 pounds per acre per annum. It would thus 
 appear that, without nitrogenous manure, about 30 pounds of nitrogen 
 has been contributed per acre per annum, from some source, to crop 
 and drainage together. The determinations of nitrogen in the soils of 
 the two plots indicate that they have lost an average of about two- 
 thirds of this amount annually to the depth of 27 inches. There 
 would, therefore, according to this reckoning, i-emain about one-third 
 — say 10 pounds more or less — to be contributed by seed, by rain and 
 condensation from the atmosphere, and by all the other supplies of 
 combined nitrogen which have been supposed to be available, whether 
 by the combination of free nitrogen within the soil, or its assimilation 
 by the plant. Of this amount about 2 pounds will be due to seed, 
 and if we suppose, say, only 5 pounds to be annually supplied by rain 
 and the minor aqueous deposits from the atmosphere, there is but 
 little left to be provided by all the other sources assumed. 
 
 Nitrogen in the Soils of the Experimental Barley Plots. 
 
 Unfortunately we have not so complete a series of determinations 
 of nitrogen in the soils of the experimental barley plots as of those in 
 the experimental wheat field. In 1868 four of the barley plots were 
 sampled. Four samples, each 6 by 6 inches area, by 9 inches deep, 
 were taken from each plot, and the four mixed together. In March, 
 1882, 26 plots were sampled, four samples being taken from each plot, 
 each 6 by 6 inches area, and to the depth of three times 9, or 27 
 inches. Of the plots sampled in 1868 only one had received no nitro- 
 genous manure, but we are able to give the percentage of nitrogen in 
 the surface soil of this plot at the two dates. 
 
 Table XI. — Hoosfield Barley Land. 
 
 Nitrogen^ per cent, in the dry Mo^dd, first 9 inches. 
 
 [Barley, 31 years in succession, 1852-1882 inclusive.] 
 
 Description of Manure. 
 
 1868. 
 
 1882. 
 
 
 Per cent. 
 1202 
 
 Per cent. 
 1124 
 
 
 
 The calculated average weights of dry mould per acre, to the depth 
 of 9 inches, were not very different at the two dates. The 1882 samples 
 
 ■ l iv _ 
 
40 
 
 were, however, slightly the heavier, which vrould indicate that, for 
 comparison, the percentage of nitrogen given for the latter date is 
 perhaps somewhat too low. Still, it is obvious that, as in the case of 
 the "wheat land, so also in that of the barley land, there is, with the 
 decline in the yield of nitrogen in the crop at the same time a decline 
 in the stock of the nitrogen in the soil. 
 
 Nitrogen in the Soils of the Experimental Boot-crop Plots. 
 
 The next results relate to the land upon which root-crops — com- 
 mon turnips, swedes, sugar-beet, and mangel-wurzel (with the 
 exception of the interpolation of three years of barley without 
 manure) have been grown for forty years in succession, 1843-1882 
 inclusive. Samples of the soil have only been taken once, namely, 
 in April, 1870; that is, after the experiment had been continued 
 twenty-seven years. At that time 35 plots were sampled, and four 
 samples were taken from each plot, each 6 by 6 inches area, and to 
 a depth of 3 times 9, or 27 inches. 
 
 The following table shows the percentage of nitrogen in the surface 
 soil of the continuously unmanured plot, and of three plots with 
 mineral manure alone : — 
 
 Table XII, — Barnfield Root-crop Land. 
 
 Nitrogen, j)er cent, in dry Mould, first 9 inches. 
 
 [Root-crops (except barley three years) 40 years in succession, 1843-1882 inclusive.] 
 
 Description of Manure. 
 
 1870. 
 
 Plot 3. — Unmanured 
 
 Plot 4. — Mixed mineral manure. . . . 
 Plot 5. — Superphospliate alone .... 
 Plot 6. — Supcrph'isphate and potash 
 
 Mean of plots 4, 5, G. . . . 
 
 Per cent. 
 -0852 
 
 -0934 
 -0888 
 -0807 
 
 -0896 
 
 Having only taken samples once, we have, of course, no means of 
 comparing the condition of the land as to its percentage of nitrogen 
 at different periods. The point to b" observed in the results given in 
 the table is, that each of these four plots, which have received no nitro- 
 genous manure, shows, after twenty-seven years of experiment (twenty- 
 four years roots and three years barley), a lower percentage of nitrogen 
 
41 
 
 or 
 
 is 
 
 of 
 
 ,he 
 
 ine 
 
 in the surface soil tban lias been found in any of the other experi- 
 mental fields ; though determinations made in samples from other parts 
 of the same field, and also in an adjoining field, show considei'ably 
 higher results. The nearest approach to so low an amount in any 
 other field is where the land had been under alternate wheat and 
 fallow, without manure, for more than thirty years. 
 
 It will be remembered that the root-crops gave, with mineral 
 manure alone, a very much higher yield of nitrogen than the cereals 
 in the earlier years, and as low a yield in the later years. That they 
 did not give less still is probably owing to the fact that their growth 
 extends later in the season than that of the cereals, by virtue of 
 which they are probably enabled to arrest the nitric acid formed 
 within the soil during the early autumn months, which in the case of 
 the cereals would be more subject to loss by drainage. 
 
 Both the mechanical conditions of surface soil known to be favour- 
 able for the growth of th'^ root-crops, and the large amount of fibrous 
 root they throw out near the surface, are indications of an active 
 demand on the resources of the upper layers of the soil, and are per- 
 fectly consistent with the supposition that their growth has led to a 
 greater reduction in the stores of nitrogen of the superficial layers 
 than in the case of any of the other crops. 
 
 The evidence afforded, both by the facts of production, and by the 
 determinations of nitrogen in the soil, is indeed strongly in favour of 
 the view that the source of the nitrogen of the root-crops, as of the 
 cereals, is, when grown without nitrogenous manure, the soil itself, 
 and the small quantity of combined nitrogen annually contributed by 
 rain, and the minor aqueous deposits from the atmosphere. It is said, 
 however, that these crops require a certain amount of nitrogen to be 
 supplied by manure, and that they are able to take up the remainder 
 from atmospheric sources. The facts of production recorded at page 11 
 afford no countenance to such a view. We conclude, indeed, that the 
 dependence of these crops for their nitrogen, on the stores of the soil 
 itself, or on supplies by manure, is as clearly established as in the case 
 of the cereals. 
 
 Is THE Soil a Source of the Nitrogen of the Leguminos^ ? 
 
 We have now to consider the bearing of the evidence on the 
 question of the sources of the nitrogen of the Leguminosje ; and here 
 we approach not only the most important but the most difficult part 
 of our subject. 
 
 
42 
 
 The first of the leguminous crops, the yield of nitrogen in which 
 is recorded in Table I, is beans. Without manure the yield of nitrogen 
 was in the earlier years very much higher than with the cereals ; but 
 the decline was very great, and in the later years it was as low as 
 with the cereals. With mixed mineral manure, including potash, the 
 yield throughout was much higher, but the decline was, as without 
 manure, very great. We have not a sufficiently comparative series of 
 determinations of nitrogen in the soils of the bean plots, but such 
 results as are at command lead to the conclusion that there has been 
 a gradual decline in the percentage of nitrogen in the surface soils ; 
 but, considering the little tendency of the plant to throw out feeding 
 root in the superficial layers, it may be a question how far the reduc- 
 tion is due to exhaustion by the direct action of growth, or how far 
 to nitrification and passage of the nitrates downwards. 
 
 
 Nitrogen in the Soils of the Experimental Glover Plots. 
 
 The most important of the leguminous crops to which reference 
 has been made is red clover. In Table I is recorded the yield of 
 nitrogen over twenty-two years, 1849-70, in only six of which, how- 
 ever, was any crop obtained. The experiment has ' een continued, 
 with some modifications ; and in 1877, that is after twenty-nine years, 
 in nine of the last ten trials the plant had died ofp during the winter 
 and spring succeeding the sowing of the seed. Several small crops 
 have since been obtained, and in March, 1881, samples of soil were 
 taken from five places where no nitrogenous manure has been applied 
 from the commencement, and at each place to thi'ee depths of 9 inches 
 each. Exactly corresponding samples were also taken from an imme- 
 diately adjoining plot, which had been thirty years under alternate 
 wheat and fallow, without manure of any kind. The nitrogen was 
 determined in each of the five separate samples, and also in the mix- 
 ture of the five. Table XIII summarises the results. 
 
43 
 
 lich 
 ygen 
 but 
 as 
 the 
 lout 
 iS of 
 |mch 
 3een 
 loils ; 
 [ding 
 |duc- 
 far 
 
 
 I. 
 
 Table XIIL— Hoosfield Clover, and Wheat and Fallow, Land. 
 
 Nitrogen ;per cent, in dry Motdd, first 9 inches. 
 
 [Experiments more than 30 years.] 
 
 Mean. 
 
 Mean of determinations on five separate samples, 
 Mean on the mixture of the five samples 
 
 Mean , 
 
 1881. 
 
 Clover Land. 
 
 Per cent. 
 -1007 
 -1055 
 
 0-1061 
 
 Fallow Land. 
 
 Per cent. 
 0925 
 0-0984 
 
 -0955 
 
 It is true that the tendency of the evidence on the point is to show 
 that red clover derives, at any rate much of its nitrogen, from the 
 lower layers of the soil ; but it is surely significant that, after the 
 growth of heavy crops in 1849, when the land was in ordinary condi- 
 tion as to manuring and cropping, and the constant failure since, there 
 is, coincidently with this, nearly as low a percentage of nitrogen in the 
 surface soil as with alternate wheat and fallow without manure. It is 
 obvious that any accumulation near the surface, due to residue from 
 the small crops, has been more than compensated by exhaustion. The 
 evidence afforded by the figures may be said to be of a somewhat 
 negative character ; but it is at any rate clear that failure of growth 
 of the clover has been associated with a declining, and a very low, 
 percentage of nitrogen in the surface soil. 
 
 The next results are of a very much more definite character. They 
 relate to the two portions of the field which had grown six corn crops 
 in succession by artificial manures alone, was then divided (in 1873), 
 and on one half clover (sown in the previous year), and on the other 
 half barley, was grown. Table I shows that in the clover crops 
 151 "3 pounds, and in the barley only 37"3 pounds of nitrogen were 
 removed. Yet, in the next year (1874), barley being grown over 
 both portions, the one which had yielded 151-3 pounds in clover 
 now yielded 69*4 pounds in barley ; and the other, which had yielded 
 only 37"3 in barley, now yielded only 39-1 pounds in barley. 
 
 In October, 1873, after the clover and barley had been removed, 
 and before the land was ploughed up, samples of the soil were taken 
 as follows : From each portion four separate samples, each 12 by 12 
 inches area and 9 inches deep, and the nitrogen was determined in 
 
44 
 
 each separate sample, and also in an equal mixture of the four. Six 
 other samples, each 6 by G by 9 inches, were also taken from each of 
 the two portions, and the six samples representing each portion were 
 mixed, and the nitrogen determined in the mixture. At each place 
 corresponding separate samples were taken, and mixtures made, re- 
 presenting respectively the second and the third 9 inches of depth. 
 In all cases three and in many four determinations of nitrogen were 
 made on each sample. The following table gives the mean results on 
 each of the four separate samples, the mean of these, the mean on the 
 mixture of the four, the mean on the mixture of. the six, and the mean 
 of all : — 
 
 Table XIV. 
 
 Experimental Clover and Barley Land. 
 
 [Nitrogen per cent, in dry Mould, first 9 inches.] 
 
 Description of Samples. 
 
 • 
 
 1873. 
 
 Clover Land. 
 
 Barley Land. 
 
 Samnle No. 1 fl2 x 12 x 9 inches') 
 
 Per cent. 
 0-1574 
 0-1529 
 0-1484 
 1G31 
 
 Per cent. 
 0-14G8 
 
 Samole No. 2 (12 x 12 x 9 inches) 
 
 0-1341 
 
 Sample No. 3 (12 x 12 x 9 inches) 
 
 1431 
 
 Samnio No. 4 (12 x 12 x 9 inches) 
 
 • 1405 
 
 
 
 Mean on the four separate samples (12 x 12 x 9 inches) 
 Mean on a mixture of the four samples (12 x 12 x 9 ins.) 
 Mean on a mixture of six samples (G x G x 9 inches) .... 
 
 1554 
 15G6 
 0-1578 
 
 0-1411 
 -1387 
 0-1450 
 
 General means 
 
 0-15G6 
 
 0-141G 
 
 
 
 The determinations on the individual samples given in the upper 
 pr tion of the table (XIV), forcibly illustrate the inapplicability of 
 results obtained on single samples of soil. But the accordance of 
 the mean results of the three sets of determinations for the clover 
 land, and again of the three for the barley land, can leave no doubt 
 whatever that there was a considerably higher percentage of nitrogen 
 in the first 9 inches of the clover ground than to the same depth of 
 the barley ground. 
 
 The results must, indeed, be accepted as indicating a marked distinc- 
 tion, which, in direction, is entirely consistent with what is known of 
 the influence of a clover crop as a prepai'ation for a succeeding cereal 
 one, and entirely consistent with the results actually obtained with the 
 barley succeeding the clover. It is, however, difficult, to suppose 
 
45 
 
 that the figures correctly r ^present, in degree, the average difference 
 in the composition of the first 9 inches of the two plots ; for, calcu- 
 lated per acre, the excess of nitrogen in the surface soil of the clover 
 plot would represent an accumulation equal to about twice as much 
 as was removed in the three cuttings of the clover, notwithstanding all 
 visible vegetable debris was removed before the soils were submitted 
 to analysis ;* nor have the subsequent crops benefited as much as might 
 have been expected from such an amount of accumulation. On the 
 othtir hand, samples taken in 1877 still show a higher percentage of 
 nitrogen in the surface soil of the clover than of the barley land. 
 
 It is, at any rate, obvious that the surface soil of the clover ground 
 has gained nitrogen, either from above or from below — from the 
 atmosphere or from the subsoil. And, so far as the determinations of 
 nitrogen in the subsoils go, the indication is that, if from below, it is 
 at least mainly from a lower depth than 27 inches. 
 
 It is freely admitted that, in the facts of this experiment as they 
 stand, there is no evidence as to the source of the large amount of 
 nitrogen of the clover crop, and of the increased amount of it 
 in the surface soil. In the absence of such evidence, it is natural 
 enough to assume that the atmosphere has been the source. But 
 whilst there is absolutely nothing in favour of this view excepting 
 the fact that an explanation is needed, and that if that source were 
 established the difficulty would be solved, there is, to say the least, 
 much more evidence in favour of the supposition that the subsoil has 
 been the source of at any rate much of the nitrogen. 
 
 The Soils of the Melilotus leucantha and White Clover Plots. 
 
 Reference has already been made to the enormous growth of 
 Melilotus leucantha, and the enormous amount of nitrogen it yielded, 
 for several years in succession, on the land where no nitrogen had 
 been applied for more than thirty years, and where red clover had so 
 frequently failed (p. 12). The crop of 1882, the fifth in succession, 
 was the highest, and the yield of nitrogen in it was not far short of 
 150 pounds per acre ; whilst, under exactly similar conditions, ordi- 
 nary red and white clover gave very small produce. Accordingly, as 
 soon as the crops were removed, samples of soil were taken from one 
 of the melilotus plots, and from the corresponding white clover plot. 
 Samples were taken from two places on each plot, and in each case to 
 
 * This was more completely done in the case of the four 12x12x9 inch samples, 
 than in that of the six 6 x 6 x 9 inch ones, and the latter are seen to give slightly 
 higher percentages of nitrogen. 
 
46 
 
 the depth of six times 9 inches, or in all 54 inches. The examination 
 of these samples of soil is as yet very incomplete, but the following 
 interesting facts have been ascertained : — 
 
 Whilst the strong roots of the melilotus were found to penetrate 
 to the lowest depths of the sampling, there was very little develop- 
 ment of white clover roots beyond the surface soil. Whilst to the 
 eye, and to the hand, the subsoil where the melilokis had grown was 
 obviously pumped dry, and was somewhat disintegrated, to the full 
 depth sampled, that of the clover plot had no such characters. De- 
 terminations of moisture in the soils and subsoils show, at each of the 
 six depths, much less water in the melilotus than in the white clover 
 soils ; and the difference is by far the greater in the lower depths. 
 Calculated per acre, it would appear that, to the depth of 54 inches, 
 the melilotus soil had lost approximately 540 tons more water per 
 acre than the white clover soil ; and there can be no doubt that the 
 pumping action had extended deeper still. 
 
 There is here, then, clear evidence that the plant, whose habit of 
 gi'owth, and especially whose range, and feeding capacity, of root, 
 suited it to the conditions, was enabled to take up much more water, 
 and doubtless with it much more food, than, under exactly similar 
 conditions of soil, were at the command of the plant of the much 
 weaker and more restricted development. 
 
 Nitrogen as Nitric Acid in the Melilotus and White Clover Soils. 
 
 That the deep-rooting melilotus did derive more nitrogen from the 
 subsoil than the shallow-rooting white clover is obvious from the 
 following facts : — Watery exhausts were made of each soil, at 
 each depth, and the nitrogen as nitric acid determined in them, by 
 Schlosing's method, as nitric oxide, by its reaction with ferrous salts. 
 
 The f oUowir iable summarises the results : — 
 
 ■» 
 
ion 
 ate 
 
 
 47 
 
 Table XV. 
 Nitrogen as Nitric Acid. 
 
 
 Per million, dry Soil. 
 
 Per Acre. 
 
 
 Melilotus 
 Soil. 
 
 White 
 Clover Soil. 
 
 Melilotus 
 Soil. 
 
 White T^.„ 
 Clover Sou. difference. 
 
 First 9 inches 
 
 Second 9 inches 
 
 Third 9 inches 
 
 Fourth 9 inches 
 
 Fifth 9 inches 
 
 Sixth 9 inches 
 
 1-28 
 0-36 
 0-21 
 0-33 
 0-28 
 55 
 
 3 24 
 1-10 
 0-66 
 1-03 
 146 
 1-77 
 
 lbs. 
 3 39 
 0-97 
 0-61 
 0-C9 
 0-84 
 1-65 
 
 lbs. 
 8 59 
 2-97 
 1-91 
 3 09 
 4-38 
 5-31 
 
 lbs. 
 
 5 20 
 
 2-00 
 
 1-30 
 
 210 
 
 3-54 
 
 3 66 
 
 Total 
 
 • • 
 
 •• 
 
 8-45 
 
 26 25 
 
 17 -80 
 
 
 
 Thus the melilotus had not only exhausted the water, but the nitric 
 acid of the soil, at each depth very much more than the white clover 
 had done ; and the difference is very marked, and increases, at the 
 lower depths. It is seen that in the case of the white clover soil there 
 is a diminishing amount of nitric acid from the first to the third depth, 
 and then an increasing quantity to the sixth depth. There was, in 
 fact, about the same total amount found in the three lower as in the 
 three upper layers. It may fairly be supposed that there is greater 
 concentration lower still, and that the exhausting action of the melilotua 
 extended beyond the depth examined. 
 
 There is here direct evidence that the soil is the source of at 
 any rate some of the excess of nitrogen of the melilotus over that in 
 the white clover. The quantity, and the distribution, of nitric acid 
 in the soil at any one time are so dependent on temporary conditions, 
 that it would be fallacious to attempt to estimate from the figures as 
 they stand the exact amount which the melilotus has taken up more 
 than the white clover. Then it is obvious that the action extended 
 below the depth examined ; and it is a question whether, with the 
 greater disintegration, and greater aeration, nitrification would not be 
 favoured in the lower depths, and if so the supply would be in a sense 
 cumulative. Lastly, it may be that the deeply and widely distributed 
 m.elilotus roots have the capacity of taking up nitrogen from the soil 
 in other forms than as nitric acid. 
 
 \*..J^ 
 
48 
 
 i 
 
 Nitrogen as Nitric Acid in other Soils and Subsoils. 
 
 It will be some furtlicr aid in judging of tho possibility or pro- 
 bability that the nitric acid in the soil and subsoil may be an adequate 
 source of tho nitrogen of the LeguminoscB, if wo quote a few results 
 indicating the amount of nitric acid found in some other soils under 
 known conditions. 
 
 In the first place, three soil drain-gauges, one with 20, ono with 40, 
 and one with GO inches depth of soil, in its natural state of consolida- 
 tion, and each of one-thousandth of an acre area, have been under 
 experiment for between eleven and twelve years. No manure has been 
 applied to these soils, nor have they gi'own any crop, from the com- 
 mencement. The drainage has been regularly collected and measured ; 
 and for nearly the whole of the last five years the nitric acid has 
 been determined in monthly average samples of the drainage waters. 
 Taking the result of the three gauges, for four harvest-years (Sep- 
 tember 1, 1877, to August 31, 1881), these soils, which had been 
 about six years without any manure at the commencement of the 
 period under consideration, have lost by drainage an average of nearly 
 43 pounds of nitrogen as nitric acid per acre per annum, of which 
 perhaps not much more than 5 pounds would be duo to rain and con- 
 densation of combined nitrogen from the atmosphere. In fact, about 
 35 pounds, or perhaps more, would appear to have been annually due 
 to the nitrification of the nitrogenous matter of these unmanured soils. 
 It has to be borne in mind, however, that tho blocks of soil having 
 access of air from below as well as from above, the nitrification may 
 have been freer than it would be in soil in its ordinary condition. 
 
 Again, in some of the samples of soil taken from the plots in the 
 experimental wheat field, in October 18G5, and in many of those taken 
 in October 1881, that is in each case about two months after the 
 removal of the crop, the nitric acid has been determined. 
 
 In the case of one plot sampled in 18G5, which had received 
 annually mixed mineral manure and ammonium salts, determinations 
 made in 186G (by Br. Pugli's method), showed nearly 76 pounds of 
 nitrogen as nitric acid per acre to tho depth of 27 inches. As, how- 
 ever, these soils had been stored in a rather moist condition, it is 
 possible that nitrification may have taken place after the collection, 
 and that the results are so far somewhat too high. 
 
 The following table (XVl) gives an abstract of the results of the 
 determinations of nitrogen as nitric acid in the 1881 samples of the 
 experimental wheat field soils : — 
 
 \'WW^ 
 
49 
 
 Taiu-e XVT. 
 
 NUror/en as Nitric Acid. 
 
 Complex Mineral Manure 
 
 and 
 
 Ammonium 
 
 Salts. 
 
 and 
 Sodium 
 Nitrate. 
 
 Sodium 
 
 Kitrate 
 
 alone. 
 
 Unmanured 
 continuously. 
 
 Per Million Dry Soil. 
 
 Per Acre. 
 
 "Pirsf. P inrlifia 
 
 lbs. 
 22-8 
 11-3 
 5-8 
 
 lbs. 
 19-7 
 10-0 
 
 8-3 
 
 lbs. 
 16 3 
 20 1 
 18-0 
 
 lbs. 
 9-7 
 
 Second 9 inches 
 
 Third 9 inches 
 
 5-2 
 
 2-8 
 
 
 
 Total 
 
 39-9 
 
 38-0 
 
 54-4 
 
 17-7 
 
 
 
 Thus, in these 1881 samples, collected, like those in 18G5, about 
 two months after the removal of the crops, the amounts of nitric acid 
 found to the depth of 27 inches only, represented — in the soil of the 
 plot receiving mixed mineral manure and ammonium salts, 39"9 
 pounds of nitrogen per acre to that depth ; in that of the plot receiving 
 the same mineral manure and sodium nitmte, 38 pounds ; in that of 
 the plot to which nitrate of soda alone is annually applied, 54-4 pounds; 
 and in the soil of the continuously unmanured plot, 177 pounds. 
 
 As in the case of the white clover land, in all cases (except with the 
 nitrate alone), the amount decreased from the first to the third 9 inches 
 of depth from the surface ; and if, as in that case, it increased in the 
 lower depths, and in anything like the same degree, we have evidence 
 of a considerable store of nitric acid available for such plants as, by 
 virtue of their habit of growth, are able to gather up the residue 
 accumulated within the subsoil. 
 
 Determinations made in samples collected in the experimental rots,- 
 tion field, in September 1878, showed the following amounts of 
 nitrogen as nitric acid per acre to the depth of 18 inches - 
 
 iii# 
 
50 
 
 
 With Super- 
 phosphate 
 only.* 
 
 With 
 
 Complex 
 
 Mineral and 
 
 Nitrogenous 
 
 Manure.* 
 
 After fallow 
 
 lbs. 
 30-3 
 10 -G 
 
 lbs. 
 48-8 
 
 After beana 
 
 20-5 
 
 
 
 Difference ■ . . > 
 
 25-7 
 
 28-3 
 
 
 
 Samples collected at the same date from the unmanured alternate 
 wheat and fallow plots showed to the same depth : — 
 
 lbs. 
 
 After fallow 33-7 
 
 After wheat 2 G 
 
 Diifercnce 31 '1 
 
 Lastly, two fields which had been manured and cropped in the 
 
 ordinary course of the farm, and had been fallowed since the previous 
 
 autumn, showed, according to determinations in samples collected in 
 
 October 1881, the following amounts of nitrogen as nitric acid per 
 
 acre to the depth of 27 inches : — 
 
 lbs. 
 
 Claycroft field 58-8 
 
 Foster's field 5G '5 
 
 Thus there was very much less nitrogen as nitric acid found in the 
 soils to the depths examined, after the growth of the leguminous crop 
 beans, as well '^er that of the gramineous crop wheat, than in the 
 correspond' .w soils; indicating, therefore, a like source of 
 
 some, r ' . jc;, of the nitrogen of both crops. 
 
 It oe seen, however, that even in the cases of the soils 
 
 receiving nitrogenous manure, the amuunt of nitric acid found to the 
 depths examined, is very far from sufficient to account for so large 
 an accumulation in the crop, and in the surface soil, as the figures 
 relating to the nitrogen in the produce of the clover, and in the clover 
 and barley soils, would indicate had been accumulated. 
 
 The amounts of nitric acid formed, or remaining, within a limited 
 depth from the surface, at any one time, is, it is true, as already 
 intimated, dependent on so many temporary circumstances, that it is 
 
 * The manures are applied every fourth year, for the root-crop commencing 
 each course of — roots, bp- ^ey, leguminous crop or fallow, and wheat. 
 
51 
 
 IX 
 
 and 
 
 0U8 
 
 * 
 
 not to be expected that tlio amount found within such limits at any 
 given time would represent more than a fraction of that which would 
 be available, even within that range, during the long period of growth 
 of the clover crop. Then, the indications are that there is considerable 
 accumulation beyond the depth to which most of our examinations 
 apply. Still, it is difficult to suppose, with the evidence at command, 
 that the whole of ^he nitrogen which has to be accounted for, either 
 in the Melilotus, or in the clover and barley experiment, can be 
 attributed to that source. There remains the question whether the 
 roots of the plant do not take up nitrogen from the soil in other 
 states than as nitric acid. 
 
 Finally in regard to the experiments with clover and barley, it is 
 admitted that the various results of soil examinations which have 
 been adduced do not conclusively show the source of the whole of 
 the nitrogen to have been the soil. It will, we think, nevertheless 
 be granted, that they do clearly point to the fact that at any rate 
 much of it is derived from that source ; whilst there is no evidence 
 whatever of an atmospheric source of more than the small amount of 
 combined nitrogen coming down in rain, and the minor aqueous 
 deposits, and the probably still smaller amount absorbed from the 
 atmosphere by the porous soil. 
 
 Nitrogen in some of the Soils of the Ex;periviental Mixed Herbage Plots. 
 
 The results next to be referred to will afford additional evidence of 
 the soil-source of the nitrogen of the Logurainosaj. 
 
 In Table III it was shown that in the mixed herbage of permanent 
 grass land, without manure 33'0 pounds, and with a purely mineral 
 manure (including potash) 55-6 pounds of nitrogen were yielded per 
 acre per annum in the crop over a period of twenty years. Whence 
 comes the 22*6 pounds more nitrogen per acre per annum taken up 
 when the mineral manure was applied than without manure ? 
 
 After twenty years of continuous experiment, samples of soil 
 were taken from three places on each plot, and in each case to the 
 depth of six times 9 inches, or 54 inches. The mean results of the 
 determinations of nitrogen in the surface soils of the unmanured 
 plot, and of the plot receiving a complex mineral manure (including 
 potash), are given in Table XVII which follows :— 
 
 m-m 
 

 
 52 
 
 Table XVII. — Experiments on Permanent Meadow Land. 
 Nitrogen, per cent, in dry Mould, and per Acre. 
 
 
 1870. 
 
 187G. 
 
 1878. 
 
 Plot 3. — Unmanured - 
 
 Per cent. 
 2517 
 
 • • 
 
 • f 
 
 • • 
 
 • • 
 
 Per cent. 
 -2466 
 0'223G 
 
 
 Plot 7. — Mixed mineral 
 
 manure, including potash 
 
 -2246 
 
 Difference 
 
 0230 
 
 lbs. 
 
 506-0 
 
 25-3 
 
 
 Difference per acre 
 
 r Total 20 yeai^ 
 
 \ Average per annum 
 
 • t 
 
 • • 
 
 Although we have not previously quoted the figures, we have on 
 several occasions stated in general terms that determinations of nitro- 
 gen show a lower amount in the mineral-manured soil, approximately 
 corresponding to the increased yield in the crop. 
 
 It is in reference to our statements on this point that M. Joulie has 
 called in question +he possibility of obtaining results of the kind appli- 
 cable to our argument. He takes the fact of the increased yield of 
 nitrogen under the influence of purely mineral manure as conclusive 
 proof of the atmospheric source of the increased amount of nitrogen 
 assimilated. He assumes that our calculations are based on determi- 
 nations of nitrogen in a sample of the mixed soil to the total depth of 
 54 inches. He calculates that in the mass of soil to that depth the 
 difference in the amount in the two cases would be far too small 
 to furnish a justitication for the important conclusion that the soil 
 was the source of the nitrogen. He objects that the roots of such 
 herbage would derive their nutriment chiefly in the superficial layers. 
 He further objects that if the diflerence we assume were a fact, it is 
 probably due to an accidental difference in the soil of the two plots, 
 such a difference having been admitted by us in the case of another 
 plot. Lastly, he suggests that if there really were the reduction we 
 suppose, it might be due to other causes — such as increased activity 
 of nitrification under the influence of the mineral manure and passage 
 of the nitrates downwards. 
 
 In the first place, in the case of the irregularity in the condition 
 of one of the plots referred to, the difference was readily seen in the 
 section of the soil, and there was no such difference in the instance 
 now under consideratior. 
 
 Then it is the determination of nitrogen in the first 9 inches of soil 
 
 M 
 
53 
 
 alone, to which we have hitherto referred, and to which we confine 
 attention on the present occasion. 
 
 In the nex<- place, that the difference in the condition of the two 
 plots is not merely local is shown by the fact that the determinations 
 on a sample from the unmanured plot taken in 1870 entirely confirm 
 the relative composition shown Ly the samples of 1876. Again, the 
 lower percentage of nitrogen in the 1876 samples of the mineral 
 manured plot is entirely confirmed by the results obtained on samples 
 taken in 1878. Further, of the twenty experimental plots, there is 
 only one other showing so low a percentage as the mineral-manured 
 plot, and that is the one which had received the same mineral manure, 
 but for a shorter series of years. 
 
 We have in fact no doubt whatever that the differences indicated by 
 the figures are real, and dependent on the conditions of manuring and 
 of growth. The reduction is, moreover, very great, amounting to 
 nearly one-tenth of the total quantity of nitrogen, and far beyond 
 the limits of accidental difference in the sampling or the analysis. 
 
 Calculated per acre, the sui'face soil of the mineral-manured plot 
 contained, at the end of the twenty years, 50G pounds less nitrogen than 
 the soil oi the unmanured plot to the same depth, corresponding to an 
 annual reduction of 25"3 pounds of nitrogen per acre per annum. It 
 is, to say the least, a very remarkable coincidence that the in'^reased 
 yield of nitrogen in the crop on the mineral-manured plot which has 
 to be accounted for is 22'6 pounds per acre per annum. 
 
 We do not pretend to claim absolute accuracy for such results, but 
 we ourselves entertain no doubt whatever of their significance and 
 their importance. 
 
 It will be asked — How is it that in the case of the red clover, and 
 the melilotus, it was concluded that, so far as the plants had derived 
 their nitrogen from the soil, it was at any rate mainly from the lower 
 depths, and that here, in the case of the permanent mixed herbage 
 plots, we assume the increased yield of nitrogen to be derived from 
 the surface soil ? 
 
 Under the influence of the mineral manure, a larger proportion 
 and amount of leguminous herbage was developed than on any other 
 p,ot ; but the leguminous plant the most, indeed very prominently, 
 favoured was the Lathyrns p-atensis, which throws out an enormous 
 quantity of root near the surface ; and it is sufficiently established 
 that the potash of artificial manures remains almost exclusively in the 
 superficial layers. On the other hand, the perennial red clover, and 
 the Lotus corniculatus, which have a much more deeply-rooting ten- 
 dency, are comparatively little encouraged. 
 
 D 2 ' 
 
I! 
 
 54 
 
 The actual amount of leguminous herbage produced, however, is 
 not sufficient to account for nearly the whole of the increased yield 
 of nitrogen in the produce of the plot. The fact is that, besides a 
 porportionally very large increase in the growth of leguminous her- 
 bage, there has been a gradually increasing amount of gramineous 
 produce developed ; far beyond what would be anticipated from the 
 extremely limited effect of such manures on gramineous crops grown 
 separately on arable land. How far this result may be due to an 
 increased tendency of the grasses to form stem, and to ripen, under 
 such conditions ; — how far to more active nitriBcation induced under 
 the influence of the mineral manure in the much more highly nitro- 
 genous gi'ass-land than in the poorer arable soil, and so yielding a 
 direct supply to the Gi-amineoe of the mixed herbage ; — or how far to 
 an increased supply in a condition available for the grasses as the 
 result of a previously increased growth of the Legumiuosse, may be 
 a question. But it is of interest to note that the gramineous species 
 that are developed are among the most superficially rooting of the 
 grasses found on the experimental plots. 
 
 Before leaving the subject of these experiments on the mixed 
 herbage of grass land, it may be well to call attention to the fact that, 
 on the assumption that the whole of the nitrogen of the herbage, 
 beyond the small amount of already combined nitrogen coTjtributed by 
 rain and condensation from the atraosphe*"e, is derived from the soil, 
 we have to conclude that about 25 pounds per acre per annum have 
 been yielded by the soil of the unmanured plot, and nearly an addi- 
 tional 25 pounds, or in all about 50 pounds, from the mineral- 
 manured plot. It was estimated that, in the case of the continuous 
 wheat experiments, about 20 pounds of nitrogen had been annually 
 obtained in the crop, and a minimum of 12 pounds lost by drainage ; 
 in all 32 pounds. It cannot fail to be observed how closely this 
 amount corresponds with the annual yield of nitrogen (83 pounds) in 
 the unmanured mixed herbage. With the richer grass-land, tliough less 
 aerated than arable land, it might be expected there would be some 
 increased activity of nitrification, even in the unmanured soil ; and 
 there may be some loss by drainage. But, with a mixed herbage of 
 some 50 species, of very varying habit of growth, and with the 
 possession of the soil all the year round, it is only what would be 
 expected that there would be more of the available nitrogen taken up 
 by the crop, and less lost by drainage, than with the cereal grown sepa- 
 rately on arable land, and occupying the soil for only a very limited 
 period of the year. 
 
 We conclude, then, that the results relating to the two mixed 
 
a 
 3r- 
 us 
 he 
 wn 
 an 
 er 
 er 
 fro- 
 
 a 
 
 I 
 
 55 
 
 herbage plots can leave little doubt that the increased yield of nitro- 
 gen in the more highly leguminous produce of the mineral-manured 
 plot had its source in the stores of the soil itself. 
 
 Source of the Nitrogen of Glover Grown on Rich Garden Soil. 
 
 We have one more illustration to bring forward having an import- 
 ant bearing on the question of the sources of the nitrogen of the 
 Leguminosee. 
 
 In view of the signal failure in the attempts to grow red clover on 
 a nitrogen exhausted arable soil, it is of much interest that large, 
 though declining, crops have been grown for twenty-nine years in 
 succession on a small plot of rich kitchen- garden soil. 
 
 The experiment was commenced in 1854, and the following table 
 shows the percentage of nitrogen in samples of the first 9 inches of 
 soil, taken in October 1857, and in IMay 1879 ; that is, with an 
 interval of twenty-one seasons of growth. In 1857 only one sample 
 was taken, and only to the depth of 9 inches ; but in 1879 three 
 samples were taken, in each case to the depth of twice 9, or 18 inches. 
 The results given in the table relate to the first 9 inches of depth 
 only : — 
 
 Table XVIII. — Clover Grown on Kitchen Garden Soil. 
 Nitrogen, per cent, in dry Mould, and per Acre. 
 
 
 1857. 
 
 1879. 
 
 Difference. 
 
 
 Per cent. 
 
 Per cent. 
 0-3C35 
 -3610 
 -3026 
 
 Per cent. 
 
 
 0-5095 
 
 0-3G3i 
 
 1461 
 
 "Ppi* nr»iv> tnfjil* ........••■'<••« •• 
 
 lbs. 
 9,528 
 
 lbs. 
 6,790 
 
 lbs. 
 2,732 
 
 
 130 
 
 
 
 The percentage of nitrogen given for the single sample collected in 
 October 1857, is the mean of determinations made in 1857, 1866, and 
 
 * In the original paper, too high an average weight of soil per acre was adopted, 
 and hence the amounts of nitrogen per acre were estimated to be higher than now 
 given ; but the difference was only 9 pounds more (139) than according to the 
 new calculation. 
 
 i;'W 
 
If 
 1 
 
 ^1 
 
 
 if 
 
 i >.: 
 
 56 
 
 1880, and is almost ideutical with the mean of those made at the latest 
 date. 
 
 The first point to observe is that the first 9 inches of the garden 
 ground contained more than half a per cent, of nitrogen, nearly four 
 times as much as the average of the arable soils, and nearly five times 
 as much as the exhausted clover land soil. It is of course true that 
 the soil would be correspondingly rich in all other constituents ; but 
 some portions of the arable soil where clover failed, had received 
 much more of mineral constituents by manure than had been removed 
 in the crops. 
 
 The means of the determinations made on the three separate 
 samples taken in 1879 are seen to agree very well, and the results can 
 leave no doubt that there has been a great reduction in the stock of 
 nitrogen in the surface soil. The reduction amounts to nearly 29 per 
 cent, of the total. Reckoned per acre, as shown at the foot of the 
 table, it corresponds to a loss of 2,732 pounds during the twenty-one 
 seasons of growth ; and although really good crops are still grown in 
 mo.st years, there has been, with this great reduction of the stock of 
 nitrogen in the soil, a very marked reduction in the clover-growing 
 capability of the soil. Thus, during the first fourteen of the twenty- 
 nine years of the experiment, seed was sown only three times ; whilst 
 during the last fifteen years it has been necessary to sow ten times. It 
 is obvious, therefore, that the plant stood very much longer during 
 the earlier than the later years. Then, again, the produce from the 
 three sowings during the first fourteen years was nearly twice as 
 much as has been obtained since. 
 
 The question obviously arises — what relation does the amount of 
 nitrogen lost by the soil bear to the amount taken off in the crops ? 
 We quite admit the uncertainty of calculations of produce per acre 
 from the results obtained on a few square yards. We are, however, 
 disposed to estimate the average yield of nitrogen over the twenty-one 
 years between the two periods of soil sampling at about 200 pounds 
 per acre per annum. The table shows that against this we have an 
 estimated loss of nitrogen by the first 9 inches of soil of 130 pounds 
 per acre per annum, corresponding approximately to two-thirds of 
 the amount estimated in the crop. 
 
 There is, however, evidence leading to the conclusion that, in the 
 case of arable soils to which excessive amounts of farm-yard manuro 
 are applied, there may be a loss by evolution as free li-^rogen ; and, 
 obviously, so far as this may have occurred in the garden soil, there 
 will be the less of the loss determined in the surface soil to be credited 
 to assimilation by the growing clover. 
 
57 
 
 On the other hand, it is known that when growing on ordinary 
 arable soil, the clover plant throws out a large amount of roots in the 
 lower layers, and although in the case of so rich a surface soil, the 
 plant may derive a larger proportion of its nutriment from that 
 source, we must at the same time suppose that it has also availed 
 itself of the resources of the subsoil. Unfortunately, we did not 
 sample deeper than 9 inches in 1857, so that we can make no com- 
 parison of the condition of the subsoil at the two periods. It may, 
 however, be observed that, in 1879, the second 9 inches showed about 
 three times as high a percentage as the subsoils of the arable fields at 
 the same depth ; indeed, not far from twice as high a percentage as 
 several of the exhausted arable surface soils. It cannot be doubted, 
 therefore, that the subsoil of the garden plot has contributed to the 
 yield of nitrogen in the crop. 
 
 If, then, we have not here absolute proof that the source of the 
 whole of the nitrogen of the clover growing on the garden soil was 
 the soil itself, we have surely very strong grounds for concluding that 
 much, and perhaps the whole of it, has been so derived. 
 
 General Conclusions. 
 
 After this review of the evidence which the determinations of 
 nitrogen in the soils of our experimental plots afford, we end, as we 
 began, by saying that, although we admit the facts of production are 
 not yet conclusively explained, we maintain that there is, to say the 
 least, much more of direct experimental proof of the soil than of the 
 atmospheric source of the nitrogen. Moreover, we submit that this 
 rnay be said, not only c . the source of the nitrogen of the cereals, but 
 also of that of the root-crops, and of the Leguminosse. 
 
 If, on the other hand, the atmosphere is the main, if not the ex- 
 clusive, source of the nitrogen of the Leguminosoe, we would ask here, 
 as we have asked elsewhere — why those leguminous crops which take 
 up the most nitrogen can be less frequently grown on the same soil ? 
 Why we entirely failed to grow clover successively on ordinary arable 
 land, which was nevertheless in a condition to yield fairly good cereal 
 crops ? Why the only condition under which we have been able to 
 grow clover continuously was where the soil was very much richer in 
 nitrogen (and of course in other constituents also) than the arable 
 land ? And lastly, why its growth under such circumstances has been 
 accompanied by a rapid diminution in the amount of nitrogen in the 
 soil, and with this a marked decline in the produce ? 
 
 It will not for a moment be supposed that because in the foregoing 
 

 illustrations and arguments we have confined attention almost ex- 
 clusively to the nitrogen in the soils, we in any way ignore the 
 importance of a liberal available supply of the mineral constituents, 
 so essential for the effective action of the nitrogen. There is abundant 
 evidence, however, that the failures that have been cited have not 
 been due to a deficiency of mineral constituents. 
 
 If, then, the supply of mineral constituents not being defective, 
 the yield of our crops is in the main dependent on the amount of 
 nitrogen which is available to them within th„ period of their growth 
 from the soil itself, or from manure applied to it, surely the fertility of 
 a soil must be largely measured by the amount of nitrogen it contains, 
 and the degree in which it becomes available. And, if this be so, is 
 not the soil a *' mine," as well as a laboratory ? 
 
 In this connection, speaking here in America, it will not be in- 
 appropriate to conclude with a brief reference, such as the limited 
 data at our command will permit, to what we believe must be a cha- 
 racteristic difference between a large proportion of the comparatively 
 recently, or even not yet, broken up soils of this continent, and those 
 which have been long under arable culture on the other side of the 
 Atlantic. 
 
 A sample of Illinois Prairie soil, obtained some years ago by Mr. 
 (now Sir) James Caird, and submitted by him for analysis to Dr. 
 Voelcker, to whom we are indebted, not only for his own analytical 
 results, but also for a sample of the soil itself, shows, by almost 
 identical results in the two laboratories, very nearly 0*25 per cent, of 
 nitrogen. We have no special history of this soil, nor do we 1 low 
 the depth to which it was taken ; but Dr. Voelcker informs us that 
 the sample supplied to us was a mixture of both soil and subsoil as 
 supplied to him, and that in the separate surface soil he found 0"33 
 per cent, of nitrogen. 
 
 During the present year (1882), between forty and fifty samples of 
 soil from the North-west Territory, taken at intervals between Win- 
 nipeg and the Rocky Mountains, were sent over to the High Com- 
 missioner in London, and exhibited at the recent show of the Royal 
 Agricultural Society of England, at Reading. The soils were exhi- 
 bited in glass tubes four feet in length, and are stated to represent 
 the core of soil and subsoil to that depth. Three samples of the 
 surface soils have kindly been supplied to us for the determination 
 of the nitrogen in them : — 
 
 No. 1 is from Portage le Prairie, about 60 miles from Winnipeg, 
 and has probably been under cultivation for several years. The dry 
 mould contained 0"2471 per cent, of nitrogen. 
 
 
 ^MEm' 
 
59 
 
 No. 2 is from the Saskatchewan district, about 140 miles from 
 Winnipeg, and has probably been under cultivation a shorter time 
 than Wo. 1. The dry mould contained 0'3027 per cent, of nitrogen. 
 
 No. 3 is from a spot about 40 miles from Fort Ellis, and may be 
 considered a virgin soil. The dry mould contained 0'2500 per cent, of 
 nitrogen. 
 
 In general terms it may be said that these Illinois and North-west 
 Territory Prairie soils are about twice as rich in nitrogen as the average 
 of the Rothamsted arable surface soils ; and, so far as can be judged, 
 they are probably about twice as rich as the average of arable soils 
 in Great Britain. They indeed correspond in their amount of nitrogen 
 very closely with the surface soils of our permanent pasture land. As 
 their nitrogen has its source in the accumulation from ages of natural 
 vegetation, with little or no removal, it is to be supposed that, as a 
 rule, there will not be a relative deficiency of the necessary mineral 
 constituents.* Surely, then, these new soils are " mines " as well as 
 laboi-atories ? If not, what is the meaning of the term a fertile soil ? 
 
 Assuming these soils not to be deficient in the necessary mineral 
 supplies, and that they yield up annually in an available condition an 
 amount of nitrogen at all corresponding to their richness in that con- 
 stituent, it may be asked — whether they should not yield a higher 
 average produce of wheat per acre than they are reported to do ? 
 
 The exhausted experimental wheat field at Rothamsted, the sur- 
 face soil of which at the commencement of the experiments thirty- 
 nine years ago probably contained only about half as high a percentage 
 of nitrogen as the average of these four American soils, yielded over 
 the first eight years 17|; over the next fifteen years, 15| ; over the 
 last fifteen years (including several very bad seasons), only 11]| 
 bushels ; and over the whole thirty-eight years about 14 bushels per 
 acre per annum. 
 
 So far as we are informed, the comparatively low average yield 
 of the rich North-west soils is partly due to vicissitudes of climate, 
 partly to defective cultivation, but partly, also, to the luxuriant 
 growth of weeds, which neither the time at command for cultivation, 
 nor the amount of labour available, render it easy to keep down. 
 Then, again, in some cases, the straw of the grain crops is burnt, and 
 manure is not retu ned to the land. Still, if there be any truth in the 
 
 * Since the above was in type, we have seen Dr. Voelcker's report on the Illinois 
 Prairie soil above referred to, and find he caUed attention to its richness in potash 
 and other mineral constituents. He also called attention to the much higher per- 
 centage of nitrogen in it than in the soils of this country which he and others had 
 analysed. 
 
60 
 
 views we have advocated, it would seem it should he an ohject of 
 consideration to lessen, as far as practicable, the waste of fertility of 
 these now rich soils. At the same time it is obvious that, with laud 
 cheap and labour dear, the desirable object of bringing these vast 
 areas under profitable cultivation cannot be attained without some 
 sacrifice of their fertility in the first instance, which can only be 
 lessened as population increases. 
 
 HAEBIBQir AND aONfl, PEINTEE8 IN OEDINABY TO HKB MAJE8TT, 8T. MAETIn'b IAKB.