GIFT ©F
Professor Walter P. Kelley

THE PRIZE ESSAY ON SULPHATE OF
AMMONIA.

THE UTILITY OF

SULPHATE OF AMMONIA

IN*

AGRICULTURE.

BY

JAMES MUIR, M.R.A.G.,

FORMERLY PROFESSOR AT THE ROYAL AGRICULTURAL COLLEGE,
CTRENCESTER, AND AT THE YORKSHIRE COLLEGE, LEEDS; INSTRUCTOR
AGRICULTURE TO THE SOMERSET COUNTY COUNCIL.

£ ilje
SULPHATE OF AMMONIA COMMITTEE,

AT

No. 4, FENCHURCH AVENUE, LONDON, E.C.
1899.

PRINTED BY

KING, SELL, AND RAILTON, LTD.,

12, GOUGH SQUARE, AND 4, BOLT COURT,

FLEET STREET, E.G.

SIFI

Ml

CONTENTS.

PAGE.

Introduction 5

Manufacture of Sulphate of Ammonia 5

Substances Essential for Plant Growth 6

Natural Supplies of Nitrogen to the Plant 6

Losses of Nitrogen from the Soil 7

Increase from Nitrogenous Manuring 7

Do Nitrogenous Manures Impoverish the Land ? . . . . 9

Effect of Nitrogenous Manures on the Plant 10

How Nitrogen is Taken Up by Plants it

Absorption of Ammonia by Soils 12

Possible Loss of Ammonia when Applied as Sulphate . . 14

Nitrification 15

Conditions necessary for Nitrification 15

Conditions preventing Nitrification 17

Rapidity of Nitrification 18

Loss of Nitrates 19

Influence of Climate and Season on the Effect of Sulphate 20

Time of Year to Apply Sulphate 21

Stage of Growth Best for the Application of Sulphate . . 24

Use of Sulphate on Different Soils 26

Residue from Sulphate of Ammonia 27

Effect of Applying too much Sulphate 29

Effect of Sulphate of Ammonia on the Soil 30

Method of Applying Sulphate 31

Composition of Sulphate of Ammonia 32

Cost and Valuation of Sulphate 33

Impurities and Adulterants 34

Effect of Sulphate on Individual Crops 34

Wheat 35

Sulphate for Continuous Wheat Growing .... 35

Sulphate for Wheat in Rotation 38

Barley 40

Effect of Sulphate on Yield 40

Effect of Sulphate on Quality 42

Oats 45

Mangels 47

Effect of Sulphate on Yield 48

Effect of Sulphate on Feeding Value 48

Sulphate for Mangels in Rotation 50

M

PAGE.

Turnips and Swedes 51

Potatoes 54

Beans 57

Clover 58

Grass Land 58

Influence of Sulphate on Weight of Produce ... 59

Influence of Sulphate on Botanical Composition. . 61

Influence on Palatability and Feeding Value . « . 63

Summary i ; . 66

THE

UTILITY OF SULPHATE OF AMMONIA

IN

AGRICULTURE.

More than half a century ago, in dealing with the subject
of the " Food of Plants," Fownes wrote as follows : "I beg
once more to call attention to the salts of ammonia. Should
these really be found to produce the beneficial effects antici-
pated, we shall possess at home, within the limits of our own
island, resources for the improvement of agriculture com-
pared with which guano, and nitrate of soda, and all such
things, are quite insignificant — resources which only require
to be judiciously used to produce the most extraordinary
results."*

This prediction was made when the value of nitrogenous
manures was very little understood, and when artificial top-
dressings in particular were undergoing their first trials, and
were regarded with great suspicion by the majority of agricul-
turists. Subsequent discovery and research have proved the
general correctness of the forecast, though the judicious use
of salts of ammonia is not met with as often as might be.
It is the object of this essay to point out the manner of
action of sulphate of ammonia ; and, relying only on results
of actual experiments, to show how it may best be used on
the various crops of the farm with a view to profit.

MANUFACTURE OF SULPHATE OF AMMONIA.

Sulphate of ammonia, in common with other compounds
of ammonia, is obtained chiefly as a bye-product in the
manufacture of coal gas. When coal is heated in the retorts
to drive off the gas, most of the nitrogen it contains com-
bines with hydrogen, also found in the coal, to form ammonia
— a gas consisting of fourteen parts by weight of nitrogen,
and three parts of hydrogen. To remove this ammonia
from the coal gas, in which it would be a harmful ingre-
dient, the mixture is usually brought into contact with
water in a special apparatus called a " scrubber," when the
ammonia is dissolved, while the rest of the gas passes on.

* " Journal of the Royal Agricultural Society of England," Vol. IV.

Steam is blown through this solution of ammonia and con-
densed in sulphuric acid, when the compound sulphate of
ammonia is formed by combination between the ammonia
and the acid.

In a similar manner, sulphate of ammonia is obtained
from coke-ovens, blast-furnaces, shale-oil works, and to a
slight extent in the manufacture of charcoal from bones.
In France, a certain amount is derived from the ammoni-
acal liquids from cesspools. Proposals have also been put
forward for producing sulphate of ammonia by the heating
and destructive distillation of wool refuse and other animal
matter containing nitrogen, and from peat ; but these
methods are not yet of practical importance.

The production of sulphate of ammonia in this country
has steadily increased for a number of years ; the output
having risen from about 75,000 tons in 1883 to 151,500 tons
in 1893, and 196,000 tons per annum at the present time.
The amount produced in the whole of Europe at present is
estimated by Sir William Crookes* at about 400,000 tons
per annum.

Sulphate of ammonia belongs to the class of Nitrogenous
Manures — i.e., those which are valuable for the nitrogen they
contain. We must, therefore, consider it as a source of
nitrogen only ; bearing in mind that if crops require other
substances, they must be supplied from other sources. We
will, therefore, first deal with the plant's requirements as to
nitrogen, and the effect of nitrogenous manurings generally.

SUBSTANCES ESSENTIAL FOR PLANT GROWTH.
There are in all ten substances which are absolutely essen-
tial for plant growth — that is, if any one of them is deficient
or absent from the soil, the crop grown will be deficient or
will fail accordingly. Many other substances are usually
taken up by plants ; but these can be dispensed with. Of
the essential elements, the majority are supplied naturally
in ample quantity— carbon chiefly by the carbon dioxide
(carbonic acid) in the air, hydrogen and oxygen in water,
lime, magnesia, iron, and sulphur as constituents of the soil ;
though, as we shall see, the quantity of lime may be deficient.
We find, therefore, that the substances that the farmer must
supply to his crops are usually only the three — nitrogen,
phosphates, and potash ; and even of these, potash is some-
times not required, as it often occurs in large quantities in
the soil.

NATURAL SUPPLIES OF NITROGEN TO THE PLANT.

Of all the essential constituents, nitrogen is most likely

to be lacking in any state in which it can be used by plants.

There is, of course, an unlimited quantity of free nitrogen

in the air ; but in that state it is useless, for plants can only

* British Association Presidential Address, 1898.

take it up when it is fixed or combined with oxygen or some
other element. Combined nitrogen is supplied naturally in
rain-water, and in dew and hoar-frost ; but the total average
quantity so added to the soil was estimated at Rothamsted*
to be only about 4^ Ibs. per acre per annum — a good deal
less than is required by any ordinary farm crop.

Clover, beans, and other leguminous plants make the soil
on which they grow richer in combined nitrogen. It was
first shown by Hellriegel and Wilfarth that this family of
plants normally have on their roots small nodules, contain-
ing bacteria which have the important power of using the
free nitrogen of the air, and preparing it for the use of their
hosts. The amount of nitrogen thus obtained, and left in
the soil as root and leaf residue, is often very large. These
facts must be remembered when we come to deal with the
effects of nitrogenous manures on leguminous crops.

LOSSES OF NITROGEN FROM THE SOIL.
Whatever the quantity of nitrogen in the soil it is always
liable to loss, apart from its removal by crops. Nitrogen in
the soil may be said to be always in one of three forms — viz.

i. — Nitrogenous organic matter.

2. — Ammonia.

3. — Nitrates.

In the first form, as organic matter — i.e., the remains of
plant or animal life — the nitrogen is for the most part safe
from loss. Sooner or later, however, it is liable to be acted
upon by bacteria in the soil, and changed into the second
form, when in the majority of soils it is still retained ; clay
and humus being able to hold or "fix" ammonia, while
sand, gravel, and lime have no absorptive power, as it is
called. Eventually organic and ammoniacal nitrogen will
undergo a further change, through the action of micro-
organisms, and will be converted into the third form — that
of nitrates. It is then that serious loss takes place ; for
nitrates cannot be retained permanently by any soil, but are
lost by drainage following rain. More will be said with
regard to both the absorption of ammonia by soils and the
formation of nitrates, when considering the action of sulphate
of ammonia.

INCREASE FROM NITROGENOUS MANURING.
Seeing, then, that the natural supply of nitrogen to the
soil is generally insufficient for the farmer's needs, and that
loss is continually occurring, it is obvious that the supply of
nitrogen in suitable form and quantity must increase the
return from the land, and, indeed, must be an essential part
of farm management. Both field and laboratory experiment,
as well as general agricultural practice, fully bear out this
conclusion. Out of the great mass of evidence as to the

* lt Journal of the Koyal Agricultural Society of England," Vol. XIX., S.S.

"8

effect of nitrogenous manures, the following summary may
be chosen, showing the average produce obtained from the
use of nitrogen on various crops at Rothamsted ; each crop
being grown continually on the same land, in most cases for
a long series of years.

TABLE I.

Crop.

Mineral
Manures.

Ammonia Salts.

Minerals and
Ammonia Salts.

Wheat

Bjshels.
15

Bushels.
201

Bushels.
331

Barley

223

29

43i

Oats

24£

47

59

Mangels (roots) . . .
Swedes

. Tons. Cwt.
5 2
2 9

Tons. Cwt.
6 6
0 13

Tons. Cwt.
14 13
4 9

Potatoes

3 72

1 172

5 181

Comparing the produce with mineral manures, which in-
clude, phosphates, potash, &c., and that with mineral
manures and ammonia salts, we at once see the immense
gain from the use of nitrogenous manures. In the case of
three of the six crops mentioned — viz., wheat, oats, and man-
gels— the nitrogen added to the mineral manures more than
doubled the crop, and with barley it nearly doubled it.

It will be noticed, however, that the produce with ammonia
salts only was not nearly so large as with mineral manures
and ammonia salts together, and in two cases was below
that from minerals only. Neither minerals alone nor
ammonia salts alone could produce such a good crop as
when they are used together. Indeed, this follows from
what has been already said. The mineral manure supplies
all the essential constituents of plant food except nitrogen,
while ammonia salts supply nitrogen, but nothing else.
Therefore, with the application of either for a series of years
on the same land and crop, some essential substance will
soon become deficient, and the produce will fall off in propor-
tion. When both minerals and ammonia salts are used, how-
ever, everything necessary is being supplied, and a full crop
may be obtained. It is not strictly accurate to say that the
difference between the produce with minerals and that with
minerals and ammonia salts is due entirely to the ammonia
salts. It is rather due to both manures being able to give
their full effect when used together.

In passing, it may be noticed that many misleading
results have been obtained in trials of manures^particularly
in field experiments — for want of proper appreciation of the
interdependence of the different classes of manures.

In ordinary farm practice, however, the soil is usually
more deficient in nitrogen than in minerals, and then, from
the farmer's point of view, the increase shown by the addition

of a nitrogenous manure may be fairly credited to the
manuring. To illustrate the effects of nitrogen on ordinary
farm crops grown in rotation, the results obtained in experi-
ments carried out in the year 1886 by the Norfolk Chamber
of Agriculture, in conjunction with the Royal Agricultural
Society* may be taken as fairly representative. They are
as follows : —

TABLE II.

Crop.

Phosphates, Potash, and
Phosphates and Nitrogen.

Potash. Average of Various

Dressings.

Corn. Straw. Corn. Straw.

Bush. Cwt. Qrs. Lbs. Bush. Cwt. Qrs. Lbs.

Barley after swedes . . . . 44-5 25 1 26 53'93 28 0 22

Barley after wheat . . . . 34-8 18 1 17 38-59 22 2 25

Tons. Cwt. Qrs. Lbs. Tons. Cwt. Qrs. Lbs.
Swedes (average of three

farms) 15 4 1 3 18 5 2 6

Mangels 17 5 3 20 21 12 0 23

In every case, a larger crop was grown where nitrogen
was supplied in addition to phosphates and potash, though,
as might be expected, the difference was not so great in pro-
portion as in the Rothamsted experiments, where cropping
and manuring were continually the same year after year.

In the Norfolk experiments, no plots were dressed with
nitrogenous manure only. An experiment carried out at
Pontefract under the direction of the Agricultural Depart-
ment of the Yorkshire College in 1895 gave typical results
as to the effect of nitrogenous manuring alone on swedes
on ordinary farm land. Phosphates and potash gave
1 8 tons 2 cwt. 1 6 Ibs. of roots per acre ; with nitrogen in
addition, 19 tons 12 cwt. 46 Ibs. ; but nitrogen alone gave
only 15 tons 8 cwt. 94 Ibs. — the order of the produce of
different manurings being the same as that with swedes at
Rothamsted. Here, then, we see that nitrogenous manures
used by themselves are not to be relied on for crops gro\vn
in the ordinary course of farming, any more than under the
conditions of experiment at Rothamsted. We shall have
occasion to refer later to many other instances of the same
thing.

Do NITROGENOUS MANURES IMPOVERISH THE LAND ?

Something must be said on the common idea amongst
farmers that nitrogenous manures are exhausting to the
land. Obviously, if larger crops are grown by the use of
nitrogenous manures, and these crops therefore remove

* "Journal of the RDyal Agricultural Society of England," Vol. XXIII.,
S.S., Part 1.

IO

larger quantities of phosphates and potash, the land will be
so much the poorer in those substances. If its fertility is to
be kept up, they must be returned to the soil in the form of
manure. But that is no reason why nitrogenous manures
should be considered as mere stimulants, and not as plant
food. A favourable season might equally well be considered
exhausting to the land ; for it produces large crops which, of
course, remove more plant food from the soil than small
ones would take up. With regard to lime, however, manures
in which the nitrogen is in the form of salts of ammonia are
exhausting ; for they cause it to be carried away in the
drainage from the land. This is, of course, of most practical
importance on soils deficient in lime, which in other ways
are less suitable for ammoniacal manures than those in which
lime is abundant. The whole question as to the advis-
ability of using nitrogenous manures becomes one of money.
If the cost of the extra manures used, both to produce the
crop and to compensate for the extra demands made upon the
land, is greater than the increased returns that may be
expected from their application, nitrogenous manures will
not be remunerative. This, however, is very seldom the case
on ordinary farm land, for the judicious and moderate use of
nitrogenous manures enables the crops to make use of mineral
matter which would otherwise lie idle in the soil.

EFFECT OF NITROGENOUS MANURES ON THE PLANT.

Having satisfied ourselves that the proper use of nitro-
genous manures is advantageous, we may pass on to con-
sider generally their action on plants.

Comparing plants grown with a full supply of nitrogen
with those receiving little, the most noticeable difference is
that, if all other conditions for healthy growth are fulfilled,
the plants receiving nitrogen produce a much larger leaf
growth of a very dark colour. The importance of this will
be recognized when it is remembered that the leaves are the
organs by which the plant feeds on the air — taking the
element carbon from the carbon dioxide which the air con-
tains; and that the green colouring matter, called chloro-
phyll, is the necessary agent in this action. The nitrogen
may thus be said to increase the apparatus of the plant for
the assimilation of carbon. Mineral substances are neces-
sary for the building up of the carbon into such compounds
as starch, sugar, and cellulose, which are called carbo-
hydrates. Potash particularly seems to be needed for this
purpose — an important fact, to which we shall refer again.

Another effect resulting from the use of nitrogenous
manures is that the maturing of the plant is somewhat
hindered, especially if the manure is applied late in the
crop's growth. Provided the crop is grown early enough
in the season to allow of its maturing properly, this is no
disadvantage, as it gives the plant a longer time in which

II

to grow and collect food from the air and soil. The late
application of these manures, however, is to be avoided, as
we shall see later.

In this connection it is worth noticing that, in the
Woburn wheat experiments, ammonia salts appeared not
to delay the ripening of the crop so much as nitrate of
soda.

The net effect of the increase of leaf and chlorophyll, and
of the lengthened period of growth, is the apparent anomaly
that a very large increase of non-nitrogenous material is
produced by the use of nitrogenous manures. For example,
Sir John Lawes and Sir H. Gilbert estimate a very large
gain per acre in carbohydrates (starch, sugar, &c.) from
manuring with nitrogen and minerals, as compared with
minerals only, in all the chief crops under experiment at
Rothamsted. The gain in carbohydrates for each pound of
nitrogen in the manure has been as follows, on the average of
several plots dressed with nitrogen in different forms and
quantities per acre —

TABLE III.

Carbohydrates

Crop. per Pound of 'Nitrogen

in Manure.

Lb6.

Wheat 31-0

Barley 46-3

Sugar Beet 42-1

Mangels 29-9

Potatoes 17-0

Beans 5-5

How NITROGEN is TAKEN UP BY PLANTS.

Like all the substances taken up by the roots of plants,
nitrogenous matter is only useful when in a state of solu-
tion, for plants have no power of absorbing insoluble
material. In this respect, sulphate of ammonia and other
ammonia compounds are quite suited to the requirements of
plants, being freely soluble in water.

The three forms of nitrogen in the soil differ in their use-
fulness to the plant. Organic nitrogen is for the most part
useless, and must be regarded as a reserve which is gradually
drawn upon as the nitrogen is converted into other forms.
Ammoniacal and nitric nitrogen are, however, both use-
ful to plants. Nitric nitrogen is taken up readily, and is
often stored up in the plant for a time. Under favourable
conditions — a suitable temperature and the presence of
carbohydrates in the plant being especially necessary — it is
gradually changed into various organic substances, such as
amides and finally albuminoids.

Ammoniacal nitrogen may also be directly used by plants.
Owing to the fact that, under natural conditions, most of a
crop's nitrogen, if not the whole of it, is taken up in the
nitric form, statements are frequently met with to the effect

12

that ammoniacal nitrogen cannot be directly used by plants.
That this, however, is not the case has been shown by many
investigators. A. Muntz grew various plants in a soil the
only nitrogen of which was in the form of sulphate of
ammonia ; and though taking full precautions against nitri-
fication, he found that the plants took up large quantities
of the nitrogen." About thirty years ago Hampe had
come to the same conclusion,! but found that, in the early
stages of growth, plants seemed less able to use ammoniacal
nitrogen ; and Wagner and others have obtained similar
results. We may assume, however, that ammonia is not
taken up so readily as nitric nitrogen — i.e., nitrogen in the
form of nitrates ; and under practical conditions the ammonia
of manures is almost always converted into the nitric form
before being used by plants.

Though nitric nitrogen is stored up in the plant for a time,
until circumstances allow of its being utilized, ammonia
compounds are not to any appreciable extent, but are con-
verted at once into a substance called asparagine. This
can only be formed when carbohydrates are present. If
they are deficient, compounds of ammonia act as plant
poison — sulphate of ammonia perhaps least so. J

In connection with this action, and the importance of the
presence of carbohydrates in the plant when ammoniacal
manures are used, it is worth repeating that mineral manures,
and potash particularly, are necessary to enable the plant
to form carbohydrates. The results of many experiments
seem to show, as we shall see, that by withholding a full
supply of potash from the soil, the action of ammonia com-
pounds is more injuriously affected than that of other forms
of nitrogenous manures.

The asparagine and other amides formed are not the final
product from the nitrogen which the plant takes up. In the
mature plant particularly, albuminoids are found in consider-
able quantities, these being formed from the amides. Among
other requirements for their formation, besides those already
mentioned, it is worth noticing that the presence of a sulphate
is essential. As Liebig pointed out,§ sulphate of ammonia
may gain in effect from this cause ; but the cases in which
it does so must be few, for sulphates are practically always
present in the soil in sufficient quantity for the plant's require-
ments.

ABSORPTION OF AMMONIA BY SOILS.

We may now pass on to consider what happens wrhen sul-
phate of ammonia is applied to the soil. The actions and
changes to be described take place in the same way with
other compounds of ammonia, but the sulphate is the form

* " Comptes Kendus," 109. f Vs. St., 10. + Bui. Coll. Ag. Imp. Univ.
Tokyo, 1895. § " Chemistry of Agriculture and Physiology." Third Ed.

almost always used as manure, and for the present concerns
us most.

When first applied to the land, sulphate of ammonia, being
readily soluble in water, is dissolved by the water which the
soil contains. When used as a top-dressing, especially on
grassland, so that it does not come into close contact with
the soil, it may sometimes remain undissolved until rain
falls ; but the soil generally contains enough water to dis-
solve sulphate, if in close enough touch with it.

In a state of solution, the sulphate of ammonia spreads all
through the soil ; and unless some change takes place in its
condition, it may be gradually washed away in the drainage
from the soil. We have already referred to the fact that
clay and humus in a soil have the power of fixing or
absorbing ammonia ; and, of course, the majority of soils
contain a certain proportion of one or both of these consti-
tuents. In what way the ammonia is fixed, is not clearly
understood ; but it is probably chiefly by chemical com-
bination, though capillary action may possibly assist in
retaining it.

The humus and clay of the soil, however, can only absorb
ammonia when it is either in the free state — i.e., not com-
bined with other substances — or in the state of carbonate.
The ammonia of sulphate of ammonia must, therefore, be
converted into one of these forms before it can be fixed.
This is brought about by chemical action in the soil be-
tween the sulphate of ammonia and carbonate of lime, a
substance which most soils contain. It will be remem-
bered that sulphate of ammonia is a compound of ammonia
and sulphuric acid, and carbonate of lime consists of lime
and carbonic acid. When these two substances come into
contact in the soil, an exchange takes place ; the ammonia
and carbonic acid combining to form carbonate of ammonia,
and the lime and sulphuric acid forming sulphate of lime.
That this action does really take place, is shown by the fact
that after the application of sulphate of ammonia to the
land the drainage water contains large quantities of sul-
phate of lime, and little or no ammonia.

The carbonate of ammonia thus formed can then be
absorbed and fixed by the clay and humus, when it is prac-
tically safe from loss by drainage — at least, until nitrifica-
tion takes place. Brustlein has shown experimentally that
without the presence of carbonate of lime, absorption of
ammonia does not take place when it is applied in the form,
of sulphate, or any other compound of ammonia except the
carbonate.

The requirements for the absorption of ammonia applied
as sulphate may therefore be summarized as : —

i. — The presence of enough carbcnate of lime in the soil
to convert the sulphate into carbonate of ammonia.

2. — The presence of clay or humus to absorb the carbonate
of ammonia thus formed.

It must not be understood that these actions are imme-
diate or complete. It is a common mistake, and one which
leads to a good deal of confusion of idea, that chemical
action takes place as readily and completely in the soil as in
the beakers and test-tubes of the chemist's laboratory. It
is really quite otherwise ; and in the case we are considering,
some sulphate of ammonia may remain unchanged for along
time, though the supply of carbonate of lime is plentiful. As
this sulphate sinks lower and lower in the soil, most of it is
gradually converted into carbonate, and is then fixed; but
probably many other actions take place, though generally
on a small scale and with quite unimportant results.

POSSIBLE Loss OF AMMONIA WHEN APPLIED AS SULPHATE.

Carbonate of ammonia which results from the interaction
of sulphate of ammonia and carbonate of lime is a very
volatile substance — that is, when exposed to the air, it
gradually disappears in a state of vapour, unless previously
fixed by the clay or humus of. the soil. It has, therefore,
been suggested that, on light calcareous soils — i.e., those
rich in carbonate of lime, and deficient in clay and humus —
serious loss of nitrogen must take place, owing to the rapid
formation of carbonate of ammonia, and the want of enough
absorbent material in the soil to save it from volatilization.
The amount of this loss, however, has been probably ex-
aggerated, and is hardly appreciable, except in cases where
the land is particularly rich in carbonate of lime. Even
then, according to Pechard,* the loss is prevented if
sulphate of lime is present ; for this tends to convert the
ammonia in the soil into sulphate of ammonia. As to
what occurs under ordinary conditions, Muntz found
in an experiment on a light soil, containing 2 per cent.
of lime, that the ammonia given off into the air was
only at the rate of 8f grains (0-56 gram) per acre per
day, during the first five days after a dressing of sulphate
of ammonia at the rate of 4 cwt. per acre — a heavy dressing.
Where farmyard manure was employed, the amount of
ammonia lost in the same time was 25 grains per acre per
day. These quantities are so small that they may be safely
neglected in practice, especially as we may assume that the
amount of ammonia given off into the air would be greatest
during the first few days after the manure was applied — at
any rate in the case of sulphate of ammonia. Other experi-
ments with a variety of soils have shown even less loss of
ammonia.

* " Comptes Rendus," 109.

NITRIFICATION.

It has been said already that though plants can make use
of sulphate of ammonia and other ammonia compounds,
yet they can use nitric nitrogen more easily, and do, in fact,
take up most of their nitrogen in that form. Nitrification,
or the process by which organic and ammoniacal nitrogen is
changed into the nitric form in the soil, must therefore
next be considered.

In a general way, nitrification may be described as a series
of changes in which nitrogen is taken from its various com-
pounds in the soil, and made to combine with oxygen obtained
from the air to form nitric acid. Like other acids, this com-
bines with any of the substances which the chemist calls
bases, to form compounds called nitrates.

CONDITIONS NECESSARY FOR NITRIFICATION.

These reactions depend on the presence and activity of
micro-organisms or bacteria in the soil. It has been shown
by Warington* that there are two different organisms con-
cerned in this action, one of which converts the ammonia
into nitrites — compounds in which the nitrogen is combined
with a smaller proportion of oxygen than in nitrates — and
the other acts on the nitrites, causing their further oxidation,
with the formation of nitrates. From a practical point of
view, we may consider their actions as a single process ; for,
under the conditions existing in the soil, the two organisms
are equally active. If, however, they are to cause free
nitrification, the soil must be suitable for them.

In the first place, it must contain nitrogen for the organisms
to convert into nitric acid. This nitrogen may be in the
form of either organic matter or compounds of ammonia, the
latter being more readily acted upon.

If the nitrogen is present as ammonia, there must also be
organic matter in the soil to act as food for the organisms ;
for like other living things — both animals and plants — they
only thrive when they have enough food. If the nitrogen is
in the form of organic matter, the latter will, of course, serve
the double purpose of supplying nitrogen and feeding the
organisms.

A supply of oxygen is also necessary to enter into com-
bination with the nitrogen, for it must be remembered that
the process of nitrification consists essentially of the oxida-
tion of nitrogen in the soil. This oxygen is, of course, derived
from the air ; and from this point of view the texture of the
soil, and the freedom or otherwise with which the air per-
meates it, are highly important, by influencing the facility
with which nitrification can take place.

Moisture is also essential fgr nitrification. Provided the
soil is not water-logged, a large amount of water in the soil

* •• Journal of the Chemical Society," 1891.

i6

seems to assist the action of the nitric organisms ; while if
the supply is insufficient, their activity is hindered or ceases.
Schloesing obtained the following results in a long-continued
series of experiments bearing on this point :—

TABLE IV.

—

I.

II.

III.

IV.

Water in soil, per cent. .

9-3000

14-6000

16-0000

20-0000

Nitric acid formed per

.

' 1000 parts of soil in

first thirteen months .

0-1570

0-1720

0-3970

0-4780

Nitric acid formed per

1000 parts of soil in

next six months . . .

0-0289

0-0488

0-0530

0-0866

These figures show clearly that the amount of nitric
acid formed is greater or less according as the soil is more
or less moist. It must be noticed, however, that the
amount of nitric acid formed is not in strict proportion to
the amount of water in the soil, but is, on the whole, pro-
portionately greater in the moister soils. Thus, com-
paring Column IV. with Column I., we see that in the
former, which is little more than twice as moist, about
three times as much nitric acid was formed during each
of the two periods of experiment.

A certain degree of warmth is also necessary for the
action of the organisms. Below a temperature of about
40° Fahr., they are practically inactive ; but with greater
warmth, nitrification becomes more and more rapid up to
about 95° Fahr., which is the most favourable tempera-
ture. Above that, the rapidity of nitrification very soon
becomes less, and at about 120° Fahr. practically ceases.
Muntz found the following quantities of nitric acid formed
in similar nitrifying solutions kept at the temperatures named
for nearly two months :—

TABLE V.

Nitric Acid

Formed.
Milligrams.

41 to 46 2-3

57 ,,'61 19-5

73 39-4

80 59-7

91 81-8

There is here a steady increase in the amount of nitric
acid formed, corresponding to each increase of temperature
up to 98° Fahr., after which the quantity falls off rather
rapidly with each further increase.

For the continued action 'of the micro-organisms, it is
also necessary that the soil should contain some "base" —
that is, some substance which can combine with nitric acid

Temperature.
.Deg. Fahr.

Temperature.
Deg. Fahr.

98 ...

Nitric Acid
Formed.
Milligrams.

. . 98-9

109 . . .

. . 40-3

120

. . 5-1

133 . . .

. . o-o

as it is formed, taking away its acid characteristics, and
producing a nitrate. If no base is present, the nitric acid
accumulates in the soil ; and as the organisms cannot
continue their action in the presence of any acid, nitrifica-
tion soon ceases. Almost invariably it is carbonate of lime
which acts in this way— nitrate of lime being formed ; but
other bases, such as potash, are also capable of combining
with the acid.

The requirements for nitrification may, therefore, be
summarized as —

i. — The presence of the proper organisms.

2. — Nitrogen, either in the form of ammonia or as
organic matter.

3. — Organic matter.

4.— Oxygen.

5. — Moisture.

6. — A proper degree of warmth.

7. — Carbonate of lime or some other base,

CONDITIONS PREVENTING NITRIFICATION.
The conditions adverse to nitrification which are most
frequently met with are —

i. — Absence of oxygen.

2. — Absence or deficiency of carbonate of lime.

3. — Presence of acid in the soil.

The absence of oxygen from the soil may be due to the
naturally close texture of the latter, as in the case of heavy
clays, to imperfect cultivation in the case of arable land,
or to the fact of the soil being water-logged, either from its
impervious nature or from want of drainage. Whatever
the cause, nitrification will cease ; and under these cir-
cumstances an opposite action — denitrification — may take
place, in which, under the influence of micro-organisms
which are only active in the absence of oxygen, the nitrates
present in the soil are destroyed and the nitrogen lost to
the air in a gaseous form.

The absence of carbonate of lime, though not common,
is sometimes met with. The obvious remedy is the addi-
tion of some form of lime to the land ; lime, chalk, marl, and
shell sand being all suitable for the purpose.

The presence of acid in the soil is usually connected with
one or both of the two foregoing points. When plant refuse
or other organic matter decays, various acids are formed
(carbonic, humic, &c.). If there is a plentiful supply of
carbonate of lime, most of these acids will be neutralized —
that is, will have their acid characteristics removed by
combining with it, just as we have already seen in the
case of nitric acid. Even if carbonate of lime is deficient,
these acids may still be washed out of the soil if the
drainage is good. On the other hand, if the acids accu-
mulate, the land becomes sour and nitrification ceases.

B

i8

RAPIDITY OF NITRIFICATION.

Under favourable circumstances, where all the necessary
conditions are fulfilled, nitrification goes on with great
rapidity. Thus, in two experiments, Schlcesing obtained
the following results. In each case the figures show the
actual quantity of ammonia and nitric acid respectively
present in 500 grams of soil, at the beginning and end of
the experiment.

TABLE VI.

Date.

I.

ii.

June 13 ...
July 1 ...

Ammonia
Milligrams.
55-65
5-95

Nitric Acid.
Milligrams.

isis'-so

Ammonia.
Milligrams.
57-00
6-80

Nitric Acid.
Milligrams.

206-50

In each experiment a large proportion of the ammonia
present on June 13 was evidently nitrified — from 88 to 90
per cent, of it having disappeared by the end of the ex-
periment— and in its place a large amount of nitric acid
was produced. It will be noticed that the change was
remarkably rapid ; the whole time occupied by the experi-
ments being only eighteen days. In a natural soil nitrifi-
cation will seldom be as rapid as this ; but even in ordinary
cultivated land, it will often take place very quickly. For in-
stance, the following results were obtained in an experiment
on light land on the farm of the French Institute Agrono-
mique in 1888. The amounts of ammonia and of nitric
acid in the soil were ascertained on the dates mentioned
on two plots, one receiving no nitrogenous manure, and
the other manured at the rate of 462 Ibs. cf sulphate of
ammonia per acre. The results are stated per 100,000
parts of the dry soil.

TABLE VII.

Date.

No Nitrogenous Manure.

Sulphate of Ammonia.

Ammonia.

Nitric Acid.

Ammonia.

Nitric Acid.

May 8

0-32

1-08

4-94

1-08

„ 10

0-32

1-08

4-94

2-28

„ 17

0-25

1-77

3-00

6-17

June 9

1-63

0-65

19-22

„ 14

0-15

1-24

0-49

16-08

„ 24

1-03

9-73

July 2

0-14

0-57

0-14

1-84

As in the preceding instance the ammonia gradually
disappeared from the plot manured with sulphate of
ammonia, until the quantity was the same as in that
receiving no nitrogenous manure, and nitric acid took
its place. That the amount of nitric acid was not

19

greater at any one time is explained by the fact that
heavy rain fell frequently during the course of the ex-
periment, and washed much of it away. We may, how-
ever, safely conclude that during the season of the year
when crops are growing most freely, nitrification takes
place very rapidly ; and, in this way, a supply of nitric
nitrogen is kept up.

We have stated incidentally that, though both organic
and ammoniacal nitrogen can be nitrified, yet the nitrogen
of ammonia compounds is much more quickly and easily
acted upon than that of organic substances. This may
perhaps be explained by the fact observed by Schloesing,*
that when the necessary nitrogen is present in the form of
nitrogenous organic matter, the nitrifying organism oxidizes
not only the nitrogen, but also the carbon and hydrogen of
the organic matter. Thus it may be said that the ferment
spends part of its energy in other ways than nitrification —
ways that are without beneficial influence on the plant.
With compounds of ammonia, however, as the source
of nitrogen, the organism exercises almost the whole of
its oxidizing power on that nitrogen, only taking from
organic matter the carbon necessary for its own growth and
reproduction.

As influencing our choice of ammonia compounds for use
as manure, it is worth noticing that sulphate of ammonia
is more readily nitrified than other ammonia compounds.
Schlcesing found the following to be rates at which the com-
pounds named were nitrified under favourable conditions : —

Chloride (muriate) of ammonia . oo Ibs. of ammonia per acre per day.
Carbonate of ammonia .... 67 ,, ,, „

Sulphate of ammonia .... 150 ,, ,, ,,

These quantities are greater than could be expected in
ordinary farm land; but they may be taken as representing
the comparative speed with which nitrification takes place.

Loss OF NITRATES.

We have seen that when sulphate of ammonia is applied
to the soil, the am.nonia is in most cases retained by virtue
of the absorptive power of the soil, but that sooner or later
it is nitrified — a nitrate (almost always nitrate of lime)
being formed; the change taking place most rapidly in hot
weather and in a somewhat moist soil.

This inevitable and often rapid change is one that must
be carefully borne in mind in estimating the probable
effects of a dressing of sulphate of ammonia, or indeed of
any nitrogenous manure. For while most soils have more
or less absorptive power for ammonia, it must be repeated
that no soil has the power of holding any nitrate, except
in a purely mechanical way, as a sponge may hold water.

* " Comptes Eendus," 109.

B 2

20

Therefore when the ammonia has been nitrified, and the
resulting nitric acid has combined with carbonate of lime
to form nitrate of lime, the nitrogen is then subject to
serious loss by drainage after every fall of rain that occurs,

INFLUENCE OF CLIMATE AND SEASON ON THE EFFECT
OF SULPHATE.

The many conditions affecting nitrification, and the in-
fluence which the rate of nitrification must obviously have
on the waste of nitrogen applied as sulphate of ammonia,
suggest that some seasons and climates must be more suit-
able for this manure than others. In this connection, it is
interesting to compare sulphate of ammonia and nitrate of
soda. The former is rather the less soluble, and requires to
undergo nitrification before it is liable to be washed out of
the soil. Nitrate, on the other hand, is always subject to
loss by drainage. Therefore we find in practice that sul-
phate of ammonia usually gives better results than nitrate
of soda in a wet season, but in a dry one it is likely to
remain inert in the soil, and therefore to have a relatively
wrorse effect. As will be shown later on, in the latter case
part of the unused manure may be recovered in subsequent
crops.

Wet climates and wet seasons are therefore favourable to
sulphate of ammonia; dry climates and seasons, to nitrate
of soda. An example of this with regard to season is
afforded by the Woburn wheat experiments. The follow-
ing table shows the produce per acre of corn and straw in
each year in which the rainfall of the growing season (April
to September) was 2 inches or more either above or below
the average. *

TABLE VIII.

AMMONIA SALTS.

NITRATE OF SODA.

Rainfall,

Year.

April to September.

Corn.

Straw.

Corn.

Straw.

Bush.

Cwt. Qrs. Lbs.

Bush.

Cwt. Qrs. Lbs.

1878

Above average

16-7

21 1 16

11-9

19 2 0

1879

»

14-7

20 2 22

12-0

19 1 21

1882

32-0

31 2 22

26-0

32 0 22

1885

.

31-2

25 2 10

28-1

28 0 21

1889

§

26-3

26 1 27

18-9

23 0 2

1884

Below aveiage

40-3

35 1 22

31-9

29 3 10

1887

.

26-1

22 1 14

35-0

29 0 10

1890

•

24-7

19 2 15

31-2

26 3 14

Average of wet seasons

24-2

25 0 19

19-4

24 1 24

Average of dry seasons

30-4

25 3 8

32-7

28 2 11

* Voelcker,
Vol. IX., T.S.

Journal of the Royal Agricultural Society of England,"

21

This shows that while in the dry seasons (in the dry climate
of Woburn, be it remarked) nitrate of soda was better than
ammonia salts by about 2^ bushels of corn and 2f cwt. of
straw per acre, ammonia salts gave a better return in the wet
seasons by about 4f bushels of corn and f cwt. of straw '
per acre.

Depending upon the absorptive power of the soil and the
rate of nitrification, are the two practical questions — What is
the right time to use sulphate of ammonia, with reference
both to season of the year and stage of growth of crops?
and — Is there any valuable residue left* after the first crop
has been taken from the land ?

TIME OF YEAR TO APPLY SULPHATE.

With regard to the former of these points, fuller know-
ledge has altered the ideas originally held. When it was
first discovered that most soils could firmly hold ammonia
applied to them, so that it was no longer liable to be washed
away, it was concluded that sulphate of ammonia might
safely be applied to the land in the autumn, especially in
the case of an autumn sown crop, such as wheat. The
extreme rapidity with which much of the nitrogen of
sulphate of ammonia may be nitrified was not at the time
recognized; and it was, therefore, considered an advantage
to apply it to the land some time before the period of active
growth in spring. Accordingly, in the Rothamsted wheat
experiments the ammonia salts were for many years applied
in autumn. In the course of investigations, however,
as to the composition of the drainage water from land
manured in various ways, it was observed that large quanti-
ties of nitrates and nitrites, chiefly of lime, \vere washed
away during the winter from land receiving ammonia salts
(equal weights of sulphate and muriate of ammonia) ; and,
further, that the amount of nitrates and nitrites was greatest
where the largest dressings of ammonia salts were employed.
Later experiments proved that the serious loss of nitrates
began after the application of the ammonia salts.

Table IX. shows the proportion of nitrates in the
drainage water from various plots of the Rothamsted wheat
experiments on the different occasions when the drains ran
during the year 1881-2.*

In the season of the experiment the drains did not run
after March 7 until harvest was over, so that there was no
loss by drainage during the growth of the crop. But when
drainage took place later in the year, loss of nitrate occurred
even from the plots receiving no nitrogenous manures
(Columns I. and II.). This nitrate would be produced by
the nitrification of the nitrogenous matter of the roots and

* Lawes and Gilbert, " Journal of the Royal Agricultural Society of
England." Vol. XIX., S. S.

22

other remains of previous crops. This action will probably
also explain at least part, if not the whole, of the loss of
nitrates where ammonia salts, spring sown, were applied in
addition to minerals (Column III.), for the larger crop thus
produced would, of course, leave in the soil a larger quantity
of nitrogenous matter capable of undergoing nitrification.

TABLE IX. — Nitrogen as Nitrates per Million of Water.

I.

II.

III.

IV.

V

Minerals and

Minerals

Minerals and

Date.

Unmanured.

Mineral
Manures.

400 Lbs. of
Ammonia
Salts Sown

and 400 Lbs.
of Ammonia
Salts Sown

600 Lbs. of
Ammonia
Salts Sown

in Spring.

in Autumn.

in Spring.

Mar. 5, 6, 7 .

3-4

3-6

3-9

11-6

5-3

Aug. 30, \

1-2

1-5

6.30 a.m. j

Aug. 30, )

n.q

1-4

4-1

2 to 3 p.m.]

U \j

* *

* *

Sept. 25

4-7

6-0

. .

Oct. 14

6-3

8-1

. .

. .

„ 23

8-7

9-5

18-5

13-1

23-0

Nov. 25

5-4

6-0

9-8

66-6

17-1

» 27

7-0

7-3

11-7

40-5

18-2

Dec. 7

5-1

6-3

10-9

34-8

16-8

„ 17, 18,1
20, & 21 )

4-1

5-0

7-3

26-4

11-2

January . .

3-5

3-9

7-2

224

10-2

The plot receiving minerals and 400 Ibs.of ammonia salts
sown in autumn (Column IV.), showed a very different rate
of loss by drainage. On Oct. 23, the proportion of nitrates
in the drainage water was less than where the ammonia
salts were spring sown, probably because smaller crops had
been produced, and there was therefore less material in the
soil to undergo nitrification. On Oct. 27, the ammonia
salts for the following year's crop were applied ; and the
next time the drains ran the proportion of nitrates had enor-
mously increased, being then higher than in any other sample
of drainage water examined. All through the winter, until
the end of the experiment, the quantity of nitrates, though
steadily falling, remained a good deal above that washed
from any of the other plots. Judging by the results obtained
on March 5, 6, and 7, we may conclude that the same
exceptionally heavy loss continued until the spring. When
it is remembered that about 70 per cent, of the total drainage
of the year occurs during the months of October to March
inclusive, it will be seen what a large quantity of nitrate may
thus be lost in the course of the winter.

Column V. of Table IX. is added for comparison with
Column III., to illustrate the fact that has been mentioned

23

that the amount of nitrates lost in the drainage water was
greater with increased dressings of ammonia salts.

As soon as this loss was recognized, an experiment was
begun to ascertain whether the effect of the loss of nitrogen
by drainage during the winter made an appreciable difference
to the wheat crop. The following table shows the corn pro-
duced, in bushels, the weight of straw, and the weight of the
total produce, in each case per acre, obtained by the use of
ammonia salts, autumn sown and spring sown, for the years
1873-9 inclusive: — *

TABLE X.

CORN.

STHAW.

TOTAL PRODUCE.

Season.

Autumn Spring
Sown. | Sown.

Autumn
Sown.

Spring
Sown.

Autumn
Sown.

Spring
Sown.

i Bush.

Bush.

Lbs.

Lbs.

Lbs.

Lbs.

1873 .... 22

321

2021

3079

3344

5031

1874 .... 39$

29fc

4645

2776

7094

4588

1875 ....

251

25*

3422

3204

5110

4915

1876 .... 23£

2212

2428

3793

4083

1877 .... 19|

33&

1835

2788

3048

4795

1878 .... 22£

31|

3071

4952

4486

7017

1879 ....

61

16J

906

3012

1275

4063

Average . .

22*

27|

2587

3177

4021

4927

Autumn sowing gave the best result in only one year —
1874 — an exceptionally dry season ; while in four years the
result was as decidedly in favour of spring sowing, and in
two years there was no material difference.

These experiments established the fact that ammonia
salts should not be applied to the wheat crop in autumn ;
so in 1878 and following years they were put on to the
experimental wheat crop in the spring. In 1884, a further
change was adopted, one quarter of the ammonia salts being
applied in autumn and the remainder in spring ; and this
practice has been continued since. A small quantity of
nitrogen is thus at the disposal of the plant for its autumn
growth ; but it is not till more active vegetation has com-
menced in spring that the full quantity is put on. The
next table [p. 24] gives the average produce of wheat in
bushels per acre per annum, obtained at Rothamsted by con-
tinuously manuring with minerals only, and with minerals
and ammonia salts, for each of the three periods 1852-77
inclusive, when the ammonia salts were applied in the
autumn; 1878-83 inclusive, when they were put on in
the spring; and 1884-94 inclusive, when one-quarter of
the ammonia salts were applied in the autumn and the rest
in the spring.

Lawes and Gilbert, " Journal of the Royal Agricultural Society of
England," Vol. XYL, S.b.

24

TABLE XI.

Excess of

Minerals.

Minerals and
Ammonia Salts.

Minerals and
Ammonia Salts
over Minerals

only.

Bushels.

Bushels.

Bushels.

1852 to 1877 ....

15|

33£

i?i

1878 to 1883 ....

1S|

31£

18$

1884 to 1894 ....

14J

34|

20£

Too much reliance must not be placed on these figures, as
the last two periods are comparatively short, and the returns
may be affected by variation of the seasons. The dif-
ferences, however, -bet ween the produce of the two systems
of manuring — the purely mineral and the mineral and nitro-
genous— probably fairly represent the comparative efficacy of
the three methods of applying the ammonia salts.

We may take it, therefore, that the system of putting on a
small dressing of sulphate of ammonia in the autumn, but
reserving most of it until the spring, is the most economical
for such a crop as wheat. The spring dressing should
usually be given some time in March or early in April, so
that the later spring rains may serve to distribute it through
the soil.

In the case of spring-sown crops, there is no question that
sulphate of ammonia should be applied in spring only, for
there is no object in patting on any of it in autumn.

STAGE OF GROWTH BEST FOR THE APPLICATION OF
SULPHATE.

With regard to the period of growth of the crop at which
sulphate of ammonia may best be applied, everything points
to the advisability of using it so as to supply nitrogen to the
earliest stages of the plant's growth, as well as later. Apart
from autumn-sown crops, therefore, we find that the applica-
tion of sulphate of ammonia at the time of sowing the seed
gives the best results. There is then a short time allowed
for nitrification before the plant requires a supply of nitro-
genous manure. In early spring, when nitrification is slow,
it may even be sown and harrowed in a few days before the
crop is sown. It has been suggested that better results
would follow if sulphate of ammonia were ploughed in at the
last ploughing for the crop ; and in a very dry season, this
might be advantageous, as the manure would be better
mixed with the soil. In an average spring, however, in
this country, there is usually enough rain to distribute the
sulphate of ammonia through the soil ; and it must be
remembered that when it had been ploughed in, it would be
subject to great loss from nitrification and subsequent
drainage, if wet weather came on and delayed sowing.

25

It has also been suggested to mix the sulphate of ammonia
with the seed before solving. This, however, is risky, and
likely to hinder the germination of the seed. Recent ex-
periments of Vandevelde* have shown that substances dis-
solved in the water supplied to seeds often decrease the
power and energy of germination ; and this is, of course,
exactly the state of things when the manure and seed are
mixed together. The same experiments proved the impor-
tant fact that, of the three groups of salts, nitrates are most
injurious to germination, chlorides less so, and sulphates
least harmful.

The steeping of the seed in a solution of sulphate of am-
monia before sowing has been suggested ; and as long ago as
1843, a communication was made to the Royal Agricultural
Society! detailing most favourable results from this method.
It is unsafe in practice, however ; for the vitality of the seed
is easily injured in this way.

Dressings of sulphate of ammonia, or of any nitrogenous
manure in which the nitrogen is readily available for the
plant's use, are uncertain in their action if given too late in
the life of the crop.

It has been stated already that one effect of the appli-
cation of nitrogenous manures is to retard the ripening of
the plant. If this takes place late in the crop's life, its
growth may go on so long that, in the case of a corn crop, it
ripens badly, and in late districts the harvest is put off till
the comparatively unfavourable weather of the late autumn ;
or, in the case of roots, the crop has to be taken up or fed in
an immature condition, when, of course, its feeding value is
less than it should be.

Another effect of the use of nitrogenous manures will be
remembered — viz., the increased formation of leaf. In the
case of a late dressing, this result is exaggerated, much of the
energy of the plant being consumed in this way, and the
amount and quality of the seed being deteriorated. Follow-
ing as a secondary result from this rankness of growth, is
the great tendency of corn crops to go down or be laid, when
they have been dressed with nitrogenous manures late in the
season of growth. Such crops are also more likely to be
injured by rust and mildew, or blight.

It is worth while to point out here that the unfavourable
effects mentioned are not the result of the late application of
sulphate of ammonia only, but are common to all kinds of
concentrated, readily available, nitrogenous manures. In
fact, sulphate of ammonia is on the whole less likely to do
harm to the crop, even when used injudiciously, than nitrate
of soda.

* Bot. Centr., 69.

f Campbell, " Journal of the Royal Agricultural Society of England,"

Vol. IV.

25

USE OF SULPHATE ON DIFFERENT SOILS.

The time and manner of application which enables sul-
phate of ammonia to give its best results will, however,
depend a good deal on the soil treated. On light sandy soils,
which have little power of holding manure of any kind, and
in which nitrification takes place rapidly, sulphate should
be applied just when the plant needs the nitrogen — that is,
when growth is just beginning. Two, or even three, small
dressings will also give better results than the same quantity
of the manure put on at one time. By carrying out these
principles, the crop will have the opportunity of using a
larger proportion of the nitrogen, and less will be washed
away.

On heavy land, the exact reverse is the case ; for such
soil has great power of holding ammonia, is not well adapted
for nitrification, and is so impervious to water that nitrates,
even when formed, are washed away comparatively slowly.
There is, therefore, less risk of loss, and the sulphate of
ammonia may be applied rather before the crop needs it,
and all at one time.

Soils containing a large proportion of lime are in their
texture and physical properties generally similar to light
sandy land. There is, however, the difference already men-
tioned— that there is more risk of loss of nitrogen to the air
in the form of carbonate of ammonia from calcareous soils
than from others. It has been shown that this loss, in the
case of most soils, is extremely small, and, it may be added,
even from calcareous soils need generally be considered only
when the usual plan of top-dressing is adopted. Less loss
will generally occur when the sulphate of ammonia is
ploughed or harrowed in — at least if care be taken to apply
it a short time only before the seed is sown. Altogether,
these exceptionally calcareous soils are not so well adapted
for the use of quick-acting ammoniacal manures as either
light or heavy land.

On the other hand, soils deficient in lime, whether they
are of vegetable or mineral origin, are also unsuibed for the
use of sulphate of ammonia. This will be understood from
what has been said as to the important part lime plays with
regard to the absorptive power of soils and the process of
nitrification, and need not be gone into more fully. It may
be added, however, that soils which are poor in lime often
contain large quantities of nitrogen in an organic form.
When this is the case, there is obviously greater economy
in bringing this nitrogen into action by liming, &c., than in
applying nitrogenous manures.

What has been said with regard to the action of sulphate
of ammonia on different soils, must be taken as applying
directly to soils of extreme composition — exceptionally
sandy, 'clayey, or calcareous. All the soils between these

27

extremes — that is, the great majority — may be dressed with
sulphate with good results. The above remarks, however,
indicate the general principles which must govern the mode
of application, according as the character of the soil ap-
proaches most nearly to one or other of the extremes
mentioned.

RESIDUE FROM SULPHATE OF AMMONIA.

On the question whether any valuable residue is left
after the first crop has been removed, some difference is
found in the evidence afforded by different experiments.
In both the Rothamsted and the Woburn wheat experi-
ments, special attention has been paid to the point. At the
former experimental station, plots have been manured with
mineral manures alone and with ammonia salts alone in
alternate years. Thus, when the mineral manures are
applied, there is abundance of mineral matter, and any
residue that may be left from the previous year's dressing
of ammonia salts ; while when ammonia salts are used, there
is a full supply of nitrogen and the residues left from the
last mineral manuring. On theheavy land at Rothamsted,
the mineral manures with residues of ammonia salts gave,
on the average of forty years, 15^ bushels of wheat per
acre, against 15 bushels on land which had received mineral
manures only each year of the same period. This seems
to show that, on the soil experimented with, there is practi-
cally no valuable residue.

It should be noticed, however, that for the first twenty-
four years of the experiment, the crop grown with minerals
and residues of ammonia was rather better in proportion
to that obtained by the use of minerals alone, though, it
will be remembered, the ammonia salts were at the time
applied in the autumn, and therefore were not giving their
full effect.

At Woburn, on comparatively light land, an experiment
carried out on similar lines, except that mineral manures
were applied every year, gave rather different results. On
the average of fifteen years, the following results were
obtained with sulphate of ammonia and nitrate of soda
respectively : —

TABLE XII.

Manures. Ammonia Salts. , Nitrate of Soda.

Bushels. Bushels.

Minerals and nitrogenous manures.

37-2 34-0

Minerals and residue of previous

year's nitrogenous manures . .

23-1

16-4

The average produce of the land continuously manured
with minerals only was 14-4 bushels for the same period.

28

The results, therefore, show that the residue left after the
removal of the first crop is capable of producing an in-
crease of about 8f bushels per acre when ammonia salts
are used, and of 2 bushels with nitrate of soda.

The difference between the Rothamsted and the Woburn
results is difficult to account for; but it may perhaps be
explained by the difference of soil, and by the fact that at
Woburn minerals were applied every year, but at Rotham-
sted only in alternate years. The shorter duration of the
Woburn experiments may also influence the result ; for at
Rothamsted, as we have noticed, at first the residues of
ammonia salts had some effect.

It may be safely concluded, however, that a considerable
residue from ammonia salts may remain in the soil after
the removal of the first crop. It is probable that much of
this is in the form of nitrogenous organic matter, such
as roots and stubble left by the crop, which gradually
decays and undergoes nitrification. A part, however,
seems in the Woburn experiments to have been left
untouched by the first crop, and to have remained
in its original state in the soil ; for the residue left
by the ammonia salts gives its greatest effect in the
year following an under-average crop obtained with a
direct dressing of nitrogenous manure. For instance, the
following results were obtained in the wheat experiments
at Woburn in 1895 an<^ 1896, the former of which years was
exceptionally dry, and therefore prevented the full action
of the ammonia salts. It will be remembered that mineral
manures were applied every year to each plot.

TABLE XIII.

Plot.

Nitrogenous Manure.

1895. 1896.

SA
SB

9A
9B

Ammonia
Nitrate of

salts .
soda .

Applied,
Omitted,
Applied,
Omitted,

17-2 bush.
17-0 „
20-1 „
13-4 „

Omitted,
Applied,
Omitted,
Applied,

26-9 bush.
30-5 „
12-0 „
25-9 „

In 1895, ^ will be seen that the application of ammonia
salts on plot SA gave practically no larger return than the
mere residue from the previous year's manuring on plot SB.
But the ammonia salts which failed to act in that year
gave an extra return in 1896 ; the yield on plot SA in the
second year being within about 3^ bushels of plot SB, to
which in 1896 ammonia salts were directly applied. We
see from this that, if ammonia salts are not used by the
crop to which they are applied, a considerable proportion
may remain in the soil for the use of succeeding crops.
Moreover, this residue must be to a great extent in its
original state ; for if it consisted only of roots and other
plant refuse, we should find that when the nitrogenous

29

manure produced a small crop (which would, of course,
leave comparatively little organic matter in the soil), the
residue would also produce little effect. But the exact
opposite of this occurred in the above experiment. A dry
season on the light soil at Woburn may interfere with
nitrification during the hottest part of the year, when
normally it takes place most rapidly. If this happens, the
washing away of nitrogen in the form of nitrate during the
autumn will be comparatively small.

The comparison given in Table XIII. between ammonia
salts and nitrate of soda is important, because it illustrates
one marked difference in the action of these two principal
nitrogenous manures. The figures relating to nitrate of
soda show clearly that if this manure is not used by the
crop to which it is applied, it will be practically lost ; for
on plot 9A, though in the dry year of 1895 ^e cr°P was
a good deal under the average obtained by the direct
application of nitrate, in 1896 the residue gave a crop
below the average of those obtained from such residues.
(See Table XII.) On the other hand, the residue of the
ammonia salts, under the same conditions, produced a crop

3*8 bushels above the average.

»

EFFECT OF APPLYING TOO MUCH SULPHATE.

Passing on from this question, a word must be said with
regard to the effect of different quantities of sulphate of am-
monia on crops. All the injurious effects arising from the
use of nitrogenous manures too late in the season — such as
the late ripening of the crop, the over-production of leaf and
poor yield of grain, &c. — may also be produced by their
application in too large quantity. In both cases, it must
be observed, the injury is done, not by any unsuitability
of the manures for use on the farm (a conclusion too often
arrived at from very insufficient evidence), but by their use
in an injudicious manner.

The quantities of sulphate of ammonia usually suitable
for the chief farm crops will be mentioned later, when the
crops are considered in detail. For the present, however,
it must be noticed that no absolute rule can be laid down
as to the quantity of any manure that will give the best
results. Soils and seasons differ enormously ; and the
effect of manures varies in proportion. Even in the case
of similar soils and seasons, differences in condition of the
former may cause different results from any dressing of
manure. The benefit arising from the use of nitrogenous
manures on barley after wheat, and the injury they do to
barley after roots fed off by sheep, is a good example of
this.

The effect of the application of a given quantity of sul-
phate of ammonia or other nitrogenous manure, depends
also on whether the crop has a plentiful supply of the

30

mineral substances it requires. If not, a comparatively
small dressing of the nitrogenous manure is likely to pro-
duce all the possible injurious effects to an exaggerated
degree. If, on the other hand, all the essential mineral
substances are in abundance, a comparatively large dress-
ing of nitrogenous manure will only stimulate a strong but
healthy growth, and will therefore prove remunerative. A
balance or proportion between the mineral and nitrogenous
manures is the important thing. Failure to realize this is
one of the common causes of unsatisfactory results from the
the use of nitrogenous manures, and is chiefly responsible for
the exhaustion of the soil which sometimes follows their use.

EFFECT OF SULPHATE OF AMMONIA ON THE SOIL.

The effect of sulphate of ammonia on the soil must also
be mentioned. In explaining the action of the soil in ab-
sorbing ammonia, it has been stated that when sulphate
of ammonia comes into contact with carbonate of lime
in the soil, carbonate of ammonia and sulphate of lime are
produced, of which the last named is washed away in large
quantities in the drainage water. Loss of lime, therefore,
follows the use of sulphate of ammonia. Under any condi-
tions likely to arise in ordinary farm practice, this will not
be of much consequence, except on soils specially deficient
in lime. Even then an occasional liming will supply all
the lime required, and will in any case be useful or even
necessary to the soil, quite apart from the effects of
sulphate of ammonia. In long-continued experiments in
continuous cropping and manuring, however, such as those
at Rothamsted and Woburn, where in some cases very
large dressings of ammonia salts are given every year, the
soil after a time shows clearly the effects of this removal of
lime. It becomes very sour, and the crops grown become
unhealthy. For instance, in the Woburn permanent barley
experiments, the average produce per acre from the use of
ammonia salts, which, in the first three periods of five years
each, had been 36-6 bushels, 42-2 bushels, and 34-5 bushels
per annum respectively, fell to 21 bushels per annum for
the fourth period — the sixteenth to the twentieth years of
the experiment — a proportionately greater falling off" than
occurred on the plots where ammonia salts were not em-
ployed.

When a soil has thus been robbed of its lime, it becomes
like one naturally deficient in that constituent — its absorp-
tive power for ammonia is injured, and nitrification may
be stopped for want of a base to combine with the nitric
acid as it is formed. We must repeat, however, that
these extreme effects are not likely to result under the
usual management of a farm, in which sulphate of
ammonia is only used occasionally, and in comparatively
small quantities.

Sulphate of ammonia is not alone among the artificial
manures in causing injury to the land when used con-
tinuously in excessively large quantities. On heavy land,
nitrate of soda injures the texture of the soil, by increasing
its power of retaining moisture. On clay land this change
soon becomes appreciable, even under farming conditions,
so that among farmers nitrate of soda is reputed to make clay
plough up " like liver," sodden and wet, and work with diffi-
culty. For example, in the experiments on continuous oat
growing at Rothamsted, the plots dressed with nitrate of
soda had become so retentive of moisture by the sixth year
that it was found impossible to work the land properly, and
very irregular crops were produced in consequence.

METHOD OF APPLYING SULPHATE.

The practical difficulty of applying a small quantity of
sulphate of ammonia (sometimes less than a hundredweight
per acre), so as to spread it evenly over the surface, and the
unevenness of crop that results unless this is done, naturally
suggests the advisability of mixing the manure before sowing
with two or three times its own bulk of something that will
serve to dilute it, so to speak — that will add to its bulk with-
out adding to the nitrogen it contains. It is then easier to
distribute the sulphate of ammonia evenly ; and any trifling
irregularity in the sowing no longer causes harmful differ-
ences in the crop.

Sand, ashes, and salt are all commonly used, and all serve
their purpose, provided they are in dry condition, and are
mixed with the sulphate of ammonia just before use. Salt,
however, is often damp, or even if dry when mixed with the
sulphate, it will become damp rapidly by taking up moisture
from the air. Hence the importance of mixing just before
use ; for it need hardly be said that, if the mixture be damp,
the difficulties of even sowing are greatly increased.

Thorough mixing of the manure and ashes, or whatever
may be used, is important, though sometimes neglected ; for
it is obvious that, without care in this respect, there can be
no gain in evenness of sowing.

Where other manures are to be applied at the same time,
they are frequently mixed with the sulphate of ammonia,
instead of any such comparatively inert substances as those
mentioned above. This plan answers the required purpose
quite well, provided that such substances as kainite, &c.,
which take up water from the air, and might therefore spoil
the condition of the mixture for sowing, are only mixed in
at the last moment before use, and are themselves in a dry
state. The suitability of sulphate of ammonia for mixing
with other substances is taken advantage of by manufacturers
of compound manures, who employ it very largely as a
source of nitrogen for corn, grass, and other manures. It
compares favourably in this respect with nitrate of soda,

32

which becomes damp when mixed with other manures, and
spoils the condition of the mixture.

An important exception must be made in the case of
manures containing lime or carbonate of lime. Any such
manure — as, for instance, Thomas phosphate or basic slag — •
if mixed with sulphate of ammonia will cause a considerable
amount of ammonia to be given off into the air, especially
during the mixing and sowing. Carbonate of lime is less
active in this respect, but may cause an appreciable loss —
particularly if the mixture is damp. It may be added that
nitrate of soda suffers no loss of nitrogen in this way by con-
tact with lime.

COMPOSITION OF SULPHATE OF AMMONIA.

In the pure state sulphate of ammonia has the chemical
formula 2NH4,SO4, implying that two atoms of nitrogen,
eight of hydrogen, one of sulphur, and four of oxygen are
united in it. Expressed by weight, its composition is : —

Nitrogen 21-21 per cent.

Hydrogen 6-06 „ „

Sulphur 24-24 „ „

Oxygen 48-48 „ „

As it is usually sold, sulphate of ammonia of good quality
is of from 95 to 97 per cent, purity — that is, 95 to 97 per
cent, is actual sulphate of ammonia; the remainder con-
sisting chiefly of moisture, with any earthy or other im-
purity that may have become accidentally mixed with it.
Such manure will contain from 20*15 to 20^57 per cent, of
nitrogen.

For trade purposes, nitrogenous manures are usually
described as containing , a certain percentage of ammonia,
though in many cases their nitrogen is not in that form.
This is merely a conventional way of expressing the amount
of nitrogen present. It has been said that there are four-
teen parts of nitrogen by weight in ammonia and three of
hydrogen. Therefore fourteen- seventeenths of the weight
of ammonia consists of nitrogen. Similarly, if a manure
contains 14 per cent, of nitrogen, it will be described as
having 17 per cent, of ammonia.

In the case of sulphate of ammonia, therefore, containing
2O'5 per cent, of nitrogen, the amount of ammonia equiva-
lent to this will be 20-5 X ^, or almost exactly 24-9 per

H

cent. In deciding upon the relative economy of using one
nitrogenous manure or another, and in comparing market
quotations, it is important to bear in mind the distinction
between nitrogen and ammonia, and the numerical relation-
ship (14 : 17) which exists between them.

33

COST AND VALUATION OF SULPHATE.

It cannot be too clearly understood that it is only the
nitrogen that is of value in sulphate of ammonia. Hydrogen,
oxygen, and sulphur are all necessary for plant growth, it is
true ; but they are supplied so freely by natural means that
there is never any need to apply them as manure. We
may therefore fairly consider that the whole price paid for
sulphate of ammonia is given for the nitrogen; and. we can
thus easily find out what the nitrogen costs per pound. For
instance, a recent quotation for sulphate of ammonia is
£10 2s. 6d. per ton, containing 24 per cent, of ammonia.

A ton will contain 2240 x — = 537'6 Ibs. of ammonia,

100

equal to 442-7 Ibs. of nitrogen. The price of ammonia in
the manure is, therefore, £10 2s. 6d. -f- 537*6 = 4^d. per Ib. ;
and of nitrogen, £10 2s. 6d. ^ 442-7 = 5*d. per Ib.

Calculations of this kind may be used for comparing one
manure with another. For instance, nitrate of soda contains
about 15-65 per cent, of nitrogen, equal to 19 per cent, of
ammonia ; that is 350*5 Ibs. of nitrogen per ton, equal to
425-6 Ibs. of ammonia. The price at the time of writing is
about £j 153. per ton, at which price nitrogen costs £j 155.
-^ 35°'5 = 5H- Per lt>. ; and ammonia, £j 155. -f- 425-6 =
4*d. per Ib.

A more usual way of comparing the cost of nitrogen in
different manures, and a more convenient one, is by calculat-
ing the cost of nitrogen or ammonia per unit — that is, the
price per ton of the manure for each i per cent, of ammonia
or nitrogen. For instance, in the example taken above the
sulphate of ammonia is said to contain 24 units of ammonia
or igf units of nitrogen. The price per unit of ammonia is
therefore £IQ 2s. 6d. -f- 24 = 8s.. $±d. ; while a unit of
nitrogen costs £10 2s. 6d. -f- igf = los. 3d. Similarly,
the nitrate of soda is said to contain 15-65 units of nitrogen,
or 19 units of ammonia; the price of the former being nearly
95. i id. per unit, that of the latter 8s. 2d. per unit. In actual
working, this system of estimating the cost per unit is very
simple and helpful in comparing the relative costs of manures;
for by it, and taking into account also the suitability of two
manures for any given purpose, we can decide on their com-
parative economy. It will be easily realized that nitrogen is
sometimes cheaper in one manure, sometimes in another,
according to variations in the market quotations. Very
often one comes across a tendency to buy a manure because
it is at a low price per ton ; but this may not be the cheapest
manure. The cost per unit of nitrogen, or whatever of
value the manure contains, may be greater than that in
another manure at a higher price per ton.

At the prices mentioned above, it will be seen that nitrogen
in sulphate of ammonia is slightly more expensive than in

c

34

nitrate of soda. The reverse of this is often the case, owing
to variations in prices ; and, indeed, for some years sulphate
of ammonia has been generally the cheapest source of
nitrogen in the market — the price per unit of nitrogen having
been as a rule lower (sometimes as much as 20 per cent,
lower) than in any other manure supplying nitrogen in a
condition equally ready for the use of crops.

IMPURITIES AND ADULTERANTS.

Good samples of sulphate of ammonia generally contain
little impurity except moisture, with a very small amount of
sandy matter, some free acid, and often still less common salt.
In impure specimens, however, the proportion of both earthy
impurity and of common salt is sometimes considerable. The
well-known test of putting a little of the sulphate of ammonia
on a red-hot shovel, shows their presence ; for the sulphate of
ammonia disappears as a vapour, leaving the impurities
behind. A good sample will, therefore, leave practically no
residue when tested in this way. Sulphate of soda, and
sometimes sulphate of iron also, are occasionally found, being
used as adulterants; but their presence is, of course, detected
by the same test.

Now and then cases are reported in which sulphate of
ammonia is put on the market containing considerable 'quan-
tities of free sulphuric acid (oil of vitriol). It need hardly be
said that such manures are harmful to crops, and should be
avoided.

An even worse impurity — though a comparatively rare
one — is the thiocyanate or sulphocyanate of ammonia, which
is one of the products from the distillation of coal in the
manufacture of gas. It is so powerful a poison to plants
that even a few pounds per acre of it in a dressing of sul-
phate of ammonia will do great damage to the crop. The
thiocyanate is easily detected by adding a solution of ferric
chloride to a solution of the manure, when, if it be present,
a deep red colour will appear.

At one time, arsenic was not uncommonly found in
sulphate of ammonia — derived from the impure acid used in
its manufacture ; but it is now rarely present.

EFFECT OF SULPHATE ON INDIVIDUAL CROPS.

Having dealt with the general facts and principles con-
nected with the use of sulphate of ammonia, we will next
consider its action upon the chief farm crops, as shown by
the results of experiments. As nitrate of soda is the only
other manure practically comparable with sulphate of am-
monia, we will, where possible, compare the action of the
two substances.

35

WHEAT.

Like all other plants of the natural order Gramineae —
that is the cereals and grasses — wheat benefits to an ex-
ceptional extent from the judicious application of nitro-
genous manures. This is not due to any special require-
ment of nitrogen on the part of the members of this order,
but probably to the comparative difficulty they have in
obtaining it — owing perhaps to their habit of root develop-
ment, or in many cases to the season of the year when their
most active growth takes place. Both corn and straw are
largely increased by nitrogenous manuring.

SULPHATE FOR CONTINUOUS WHEAT GROWING.
Experiments in continuous cropping and manuring are
important as indicating with far greater certainty than-
rotation experiments the characteristic results of applying^
particular manures to particular crops. In the experi-
ments on continuous wheat growing at Rothamsted, the-
following results per acre per annum have been obtained,,
on the average of forty years, 1852 to 1891 inclusive : —

TABLE XIV.

Manuring.

COBN.

Straw,

Bushels.

Weight per
Bushel.

13
15

m

22$
33&
35g

Lbs.

57i

56§
59£
59

Cwt.
39f

Mineral manure only
Ammonia salts = 86 lb?. of nitrogen.
Nitrate of soda = 86 Ibs.of nitrogen*
Ammonia salts and minerals . . . |
Nitrate of soda and minerals* . . . !
i

* Nitrate of soda = 43 Ibs. of nitrogen only, applied in last seven years.

These figures are a good example of the usual relative
increase yielded under the different systems of manuring.
Mineral manures alone (sulphates of potash, soda, and
magnesia, and superphosphate of lime) gave little increase
compared to the unmanured plot ; and the plots receiving
nitrogenous manures only, though producing more than
that receiving minerals only, were yet far behind those
manured with both minerals and nitrogen. Another im-
portant point is that with nitrogenous manures only — that
is, when the soil was well supplied with nitrogen, but was
deficient in the other constituents of plant food — the
weight per bushel of corn was diminished. This almost
certainly implies that the quality and value of the corn
was less than on the unmanured plot. As a matter of fact,
the average weight per bushel on the two plots manured
with nitrogen only was lower than under any other system

c 2

36

of manuring experimented with. On the other hand,
where minerals were supplied with nitrogen, the quality of
the grain, as indicated by the weight per bushel, was a good
deal higher than that of the unmanured plots.

It is, however, with the comparison afforded between
ammonia salts and nitrate of soda that we are at present
most concerned. It must be remembered that these two
manures were used so as to supply the same amount of
nitrogen to the crop, not in equal weights of the manures
themselves. Thus, 400 Ibs. per acre of ammonia salts
were compared with 550 Ibs. per acre of nitrate of soda.
This must be clearly remembered, as it is important in
•drawing conclusions from the experiments as to the relative
••economy of different manures. In all experiments to be
-quoted comparing the action of sulphate and nitrate, the
same quantity of nitrogen was applied per acre in the two
forms, except where it is distinctly stated that equal weights
of the manures were used.

In the Rothamsted experiments, nitrate of soda gave the
larger increase ; but the weight per bushel of the corn was
distinctly lower than that produced by ammonia salts,
whether the manures were used alone or with minerals.
The proportion of grain to straw is also worth noticing,
:for generally a crop giving a large proportion of straw is
more liable to be laid before harvest, and in many seasons
to suffer from blight. Averaging the two plots dressed
with ammonia salts, there was ill Ibs. of straw to each
_ioo Ibs. of grain ; but with nitrate of soda, there was on
-the average 210 Ibs. of straw to each 100 Ibs. of grain.

In the experiments carried out at Woburn on continu-
ous wheat growing, similar results were obtained on the
average of twenty years. The following was the return
per acre per annum with the manures mentioned : —
TABLE XV.

Manuring.

CORN.

Straw.

Bushels.

Weight
per bush.

Lbs.

Cwt.

Qrs.

Lbs.

No manure . ....

15-3

57-3

15

o

9

Mineral manures ....

15-1

57-8

15

2

13

Ammonia salts • 50 Ibs. of

3, in mould) *

23-8

57-3

23

1

20

Nitrate of soda = 50 Ibs. of

23-6

55-2

23

2

27

Ammonia salts = 50 Ibs. of

ammonia and minerals . .

30-2

58-7

29

0

6

Nitrate of soda = 50 Ibs. of

ammonia and minerals . .

31-2

57-8

31

1

13

Ammonia salts = 100 Ibs. of

ammonia and minerals* . .

37-2

58-7

36

3

18

Nitrate of soda = 100 Ibs. of

ammonia and minerals* . .

34-0

57-0

38

0

6

* Nitrogenous manures applied in alternate years.

37

These results are very similar to those obtained at
Rothamsted, but are more favourable to the use of am-
monia salts. \Yhen the nitrogenous manures were used
alone, ammonia salts and nitrate of soda gave practically
equal yields. With minerals, a moderate dressing
of ammonia salts gave one bushel per acre less than
nitrate of soda ; but when double the amount of each of
the nitrogenous manures was given, ammonia salts pro-
duced over three bushels more than nitrate of soda. The
lower weight per bushel of the corn grown with nitrate
was even more marked than in the Rothamsted experi-
ments, especially when used alone or in the heavier dress-
ing with minerals. It should also be noticed that where
moderate dressings of the nitrogenous manures were given
with minerals, the extra weight per bushel of the corn pro-
duced by ammonia salts partly compensated for the smaller
quantity ; the difference in the total weight of corn between
the two nitrogenous manures being only about 30 Ibs. per acre.
The lower proportion of straw to grain with ammonia salts
is also seen — though not so markedly as at Rothamsted,
except with the heavy dressings of the nitrogenous manures,
where the additional quantity of nitrate applied seems to
have been used by the crop chiefly in the formation of
straw.

As bearing on the quality of the wheat grown with
different manures, it is interesting to notice the relative
values of the wheat grown on the various plots at YVoburn,
in the twenty-first year of experiment — 1897.* The values
per quarter fixed by practical valuers were —

TABLE XVI.

No manure 37s. Od. per qr.

Minerals only 37 0

Ammonia salts = 50 Ibs. of ammonia 37 0

Nitrate of soda = 50 Ibs. of ammonia 35 0

Ammonia salts = 50 Ibs. of ammonia and minerals . 38 6

Nitrate of soda = 50 Ibs. of ammonia and minerals . 36 0

Ammonia salts — 100 Ibs. of ammonia and minerals* 38 6

Nitrate of soda = 100 Ibs. of ammonia and minerals* 36 6

* Nitrogenous manures applied in alternate years.

The average value of the corn from the three plots re-
ceiving ammonia salts was 385. a quarter, against an average
of 355. lod. on the plots receiving nitrate of soda — that is,
ammonia salts raised the value of the corn is. a quarter
above the produce of the unmanured plot, but nitrate re-
duced the value to is. 2d. below that of the unmanured
corn. These values refer to one season only ; and therefore
too much stress must not be laid upon them. But they are
probably fairly representative ; being confirmed by the

* " Journal of the Royal Agricultural Society of England," Vol. IX.,
Third Series, Part 3.

38

weight per bushel of the corn, recorded over a long series
of years both at Rothamsted and at Woburn, and by
similar results which will be noticed in connection with
other crops.

For wheat, therefore, the results of these experiments
seem to show that there is not much difference in the bulk
of the corn produced by a given amount of nitrogen in the
manure, whether in the form of ammonia salts or nitrate of
soda ; but the quality of the corn is distinctly better from
ammonia salts. Both at Rothamsted and Woburn, the
average rainfall is lower than in many parts of the country ;
and therefore the results obtained are perhaps on that
account more favourable to nitrate than would be the case
in moister climates.

The amount of straw, on the other hand, is greater with
nitrate of soda, though any advantage in this is counter-
balanced by the crop's greater liability to be laid, and less
power to resist mildew. If too much nitrogen be applied,
either in comparison to the mineral plant food present in
the soil, or to the plant's requirements, harm is more likely
to result when nitrate is used than with ammonia salts.

SULPHATE FOR WHEAT IN ROTATION.
As to the best way of using sulphate of ammonia for
wheat under the conditions of ordinary farming, some light
is afforded by the experiments of the Norfolk Chamber of
Agriculture in 1888."- These were carried out at three
centres ; but the results of two stations only will be con-
sidered at present, for at the third — Flitcham — no mixture
of manures which did not contain potash was effective, so
that the inclusion of its results would only serve to mask
those of the other two stations for our present purpose.
The following table shows the average yield per acre at the
two stations, Whitlingham and Cawston :—

TABLE XVII.

Manuring. Corn. Straw.

Bush.

1 cwt. sulphate of ammonia, sown in autumn . 23-92

2 cwt. sulphate of ammonia, sown in autumn . 23-13
2 cwt. sulphate of ammonia, half sown in

autumn, half in spring 24-93

No manure 22-67

Cwt.Qrs.Lbs.

17 2 16
16 2 19

18 0 2
16 1 14

In the first place, as explaining the small increase
obtained by any of these manurings, it should be mentioned
that the season was on the whole unfavourable to their

* " Journal of the Eoyal Agricultural Society of England," Vol. XXV.,
S. S., Part 1.

39

action, and that in the district where the experiments were
carried out, farmyard manure seems necessary to produce
a full crop of wheat. The actual increase obtained by the
various dressings of nitrogenous manures is, therefore, less
than would be usually obtained. Comparing the yields of
the different plots, however, we see that the limit of
economy was reached for autumn sowing at i cwt. per acre
of sulphate of ammonia ; 2 cwt. giving less corn and less
straw than i cwt. When half the sulphate was applied
in the spring, better results were obtained, as would be ex-
pected from what has already been said on this point.

One point should be mentioned in connection with the
results obtained at Flitcham, the station not included in the
above table. It will be remembered that the soil here was
remarkably deficient in potash, so that without potash
manuring other artificials gave a very small return ; but
with potash they gave a comparatively large increase. The
results afford a very good example of the fact already noted,
that the presence of potash seems particularly important
if sulphate of ammonia is to produce its full effect ; for that
manure gave relatively worse results at Flitcham than at
the other two stations — Whitlingham and Cawston — in the
soils of which available potash was comparatively plentiful.

In experiments with wheat carried out on sterile sand,
Pagnoul has found the same thing.* When a complete
manure was supplied, there was little difference in the
results obtained from the two manures; but if potash were
deficient, nitrate was twice as effective as sulphate. In a
second year's experiment,! he found that, while the addi-
tion of potash to nitrate increased the yield in the pro-
portion of 13 : 10, potash with sulphate increased it as
26 : 10. The weight of individual grains of corn was
increased by potash with nitrate in the proportion of
14 : 10, and with sulphate of ammonia in the proportion
of 17 : 10.

A possible cause of the less favourable effect of sulphate
of ammonia when potash is deficient has been mentioned
already — viz., the need of potash for the formation of
carbohydrates, and the importance of carbohydrates in
the plant for the formation of asparagine from the nitrogen
of ammonia salts, preparatory to the further formation of
albuminoids, &c. The nitrate of soda, also, may perhaps
give its better effect under these conditions, by the soda
of the manure taking the place of potash to some extent
in the plant, and so partially supplying the deficiency.
The evidence on this point is conflicting; but the results
obtained by some investigators seem to make this explana-
tion possible. « >? ^«,p^. -i*q?

The Rothamsted wheat7experiments have already been

* " Comptes Rendus," 111. t " Ann. Agron," 17.

40

quoted to show that the best way to apply ammonia salts
is to put on a small part of the dressing in the autumn,
and the rest — about three-quarters — in spring. Another
question arises as to whether the spring dressing should
be put on at one time or in several applications. It is
generally known that nitrate of soda gives a better return
when applied in two or three dressings. Should sulphate
of ammonia be used in the same way ? An early experi-
ment at Rothamsted answers this question as far as heavy
land is concerned. In the wheat experiments of 1845,
two plots were manured with ammonia salts — one re-
ceiving all the manure at one time in the early spring, the
other in four different dressings. The results were as
follows : —

TABLE XVIII.

Corn. Straw.

Busb. Pks. Lbs. Per 100 of Corn.

Ammonia salts in one dressing . . 33 1£ . . 4058 190

„ „ in four dressings. .31 3£ . . 4266 215

There was evidently an advantage in applying the whole
of the manure at once. The lower yield of grain, the in-
crease in straw, and the large increase in the amount of
straw per 100 of grain, all showed that with four dressings
part of the manure had been applied too late in the growth
of the crop. As already mentioned, very light soils form a
possible exception to the rule of applying all the sulphate
at once.

Practically a dressing of about i cwt. of sulphate, of
ammonia per acre will generally be found enough for
wheat grown in rotation. If the crop be very weak and
thin after the winter, a rather heavier dressing — up to
2 cwt. as a maximum — may be given; while on the other
hand, if the land be in high condition, f cwt. or even ^ cwt.
will be better.

BARLEY.

EFFECT OF SULPHATE ON YIELD.

For this crop, we find that nitrogenous manures are even
more effective than for wheat. Otherwise the differences
between the two crops are not very important. We will
first consider the use of sulphate of ammonia with reference
to the yield only. At Rothamsted, Sir John Lawes and
Sir Henry Gilbert obtained the following results per acre
per annum on the average of forty years' experiments in
continuous barley growing: —

41
TABLE XIX.

No NITROGEN. AMMONIA SALTS

NITRATE OF
SODA.

.Mineral nunura.

Corn.

Straw. Corn.

Straw.

Corn.

Straw.

Bush.

Lbs. Bush.

Lbs.

Bush.

Lbs.

No mineral manure

.

16*

1044

1793

32f

2127

Superphosphate . .

.

21$

1210 42|

2674 45$

3018

Sulphates of potash,

soda, i

18

1076

312

2011 33*

2322

and magnesia . .

• •

•

m

Superphosphate and
phates of potash,

sul-}
soda, -

28|

1279

43*

2904

45*

3186

and magnesia . .

• • .)

The increase from the nitrogenous manures, even when
applied alone, was considerable, while with minerals in
addition heavy crops were obtained. The relative import-
ance of superphosphate with the nitrogenous manures, and
the small effect from the additional use of potash and other
minerals, must be noticed. Thus while superphosphate
and either of the nitrogenous manures gave a crop about
half as large again as the nitrogenous manure alone, the
sulphates of potash, soda, and magnesia yielded with
nitrate of soda only f bushel more corn than the nitrate
alone, and with ammonia salts 2§ bushels more. In the
same way, the addition of potash and other minerals to
superphosphate and nitrate caused a decrease of -J bushel
of corn ; and where the nitrogen was in the form of am-
monia salts there was an increase of £ bushel. This is
another instance, though not a very marked one, of the
relative importance of potash with ammonia salts, and
the slight or even injurious effect of its use with nitrate
of soda.

Passing on to compare the effects of ammonia salts and
of nitrate of soda, we see that the latter, whether used by
itself or with mineral manures, gave somewhat the higher
yield. The higher proportion of straw from nitrate is pro-
bably on the whole a disadvantage, as making the crop
more likely to be laid — an effect more injurious to the
value of barley than to that of wheat.

In the Woburn experiments, the results are similar to
those obtained at Rothamsted. It will be remembered,
however, that the crops manured with ammonia salts became
markedly unhealthy towards the end of the first twenty
years of experiment ; owing probably to the continual loss
of lime from the soil, occasioned by the use of ammonia
salts in considerable quantity year after year.

One result not shown by the Rothamsted experiments
must ,be noticed. On plots at Woburn dressed annually
with minerals and in alternate years with nitrogenous

42

manures, a marked difference was shown between barley
and wheat. In the case of wheat, it will be remembered
that, while mineral manures and the residue from the
application of nitrate of soda to the previous crop gave
only 2 bushels increase over the mineral manures alone,
the residue from ammonia salts gave about 8f bushels
increase. (See Table XII.) In the case of barley, the
residues of the two nitrogenous manures gave practically
identical results, as will be seen in the following table,
giving the average produce per acre per annum from the
manures mentioned for the first fifteen years of experiment.
The yield from mineral manures only was 22*6 bushels for
the same period.

TABLE XX.

Ammonia Nitrate of
Salts. Soda.

Minerals and nitrogenous manures 44-9 . . 50' 1

Minerals and residue of previous year's nitro-
genous manures 31-0 . . 31-1

It should be observed that, in these experiments, the
residue from ammonia salts was as effective on barley as
on wheat ; but the residue from the previous application
of nitrate of soda was more effective on barley than on wheat.

On farms worked in the ordinary way, sulphate of am-
monia gives precisely similar returns compared to nitrate of
soda as in the continuous experiments mentioned. For
example, in an experiment carried out in 1887 by the
Norfolk Chamber of Agriculture at Whitlingham, f cwt. of
sulphate of ammonia with minerals gave exactly the same
return of corn as i cwt. of nitrate with minerals, and rather
more straw ; double the quantity of nitrate gave much
better results ; while doubling the sulphate yielded no addi-
tional crop. It must be remembered, however, that 1887
was a remarkably dry year, and would therefore favour the
action of nitrate of soda, and would also preserve the crop from
any likelihood of suffering from the larger dose of nitrate.

EFFECT OF SULPHATE ON QUALITY.

So far the yield per acre only has been considered ; but
the quality of the grain for malting purposes is more im-
portant from an economical point of view than the mere
quantity. The quality of barley is, however, a thing upon
which it is difficult to obtain accurate statistics, and one
which can hardly be expressed by figures. Unlike wheat,
the weight per bushel of which is an approximate index of
quality, the weight per bushel of barley is a secondary
matter. Of course, other things being equal, a high weight
per bushel is desirable ; and in this respect sulphate of
ammonia and nitrate of soda have the same relative effect on
barley as on wheat — sulphate giving grain of greater weight
than nitrate. In both the Rothamsted and the Woburn
experiments this is shown ; the average weight per bushel
being about | Ib. greater with sulphate than with nitrate.

43

But this is a comparatively unimportant matter ; for the
maturation of the grain is the chief factor controlling its
malting quality. It has been pointed out that nitrogenous
manures in general delay the ripening of the crop ; and
accordingly we find that they cannot be used in large quan-
tity without spoiling the sample. It will be remembered that
this action is less noticeable in the case of sulphate of
ammonia than with nitrate of soda, and where there is a
full supply of minerals than where they are deficient. We
should expect, therefore, that a better malting sample of
grain would be produced by the use of sulphate of ammonia
than by nitrate of soda, particularly when minerals were also
freely supplied ; and we shall see that this is the case.

An inquiry was carried out by Tanner* some time ago on
this subject, which led him to the conclusion that sulphate
of ammonia improves the quality of barley for malting,
while nitrate of soda invariably makes it worse.

More recently, Munro and Beavanf have published the
results of an examination of the barley grown at Rothamsted
under various conditions of manuring for twenty-four years
(1872 to 1895). Though from the long storage of many of
the samples an accurate valuation was impossible, it was
found that they could be divided into four classes — viz.,
those in which the grain was —

i. — Over average in maturation and size.

2. — Over average in maturation, under average in size.

3. — Under average in maturation, over average in size.

4. — Under average in maturation and size.
The following table shows the number of times in the
twenty- four years that each manure produced barley of each
of the above classes. The arrangement is in the order of
their malting quality.

TABLE XXI.

Number of Samples in Each Class.

Manures.
Ammonia salts, superphosphate, and
alkaline salts ... ...

(I)
18

(ID
2

(HI.)
4

IV.

0

Superphosphate

15

5

3

1

Nitrate of soda, superphosphate, and
alkaline salts

13

6

5

o

Nitrate of soda and superphosphate .
Superphosphate and alkaline salts .
Ammonia salts and superphosphate .
In manured

9
10
6

i;

10
3
9
6

2

8
3
9

3
3
6
3

Alkaline salts

5

1

11

7

Ammonia salts and alkaline salts . .
Ammonia salts

3
2

2

4

10

3

9
10

Nitrate of soda ... .

2

4

5

13

Nitrate of soda and alkaline salts . .

1

2

8

13

. * " Journal of the Bath and West of England Society," Third Series,
Vol. XIII.

f " Journal of the Royal Agricultural Society of England," Vol. VIII.,
Third Series.

44

From this we see that barley grown with ammonia salts
with superphosphate and alkaline salts (sulphates of potash,
soda, and magnesia) was of higher average malting quality
than that produced by any other manuring, producing grain
of the highest class in eighteen years out of the twenty-four
considered, and was distinctly better than nitrate of soda
with the same mineral manures. When the alkaline salts
were omitted, nitrate gave a better average sample than
ammonia salts — another instance of the importance of a
sufficiency of potash and other similar substances wrhen
ammonia salts are used. In both the other applications of
the nitrogenous manures — that is, by themselves and with
alkaline salts — the ammonia salts were distinctly better than
nitrate of soda in their effect on the quality of the corn.

The unfavourable influence of nitrate of soda is perhaps
due to, or correlated with, its tendency to produce a large
proportion of straw, with which is usually found coarseness
of the husk enveloping the grain, and a greater proportion
of tail corn. Both these points correspond closely with the
malting quality as shown in the above table. The follow-
ing is the average proportion of grain per 100 of straw, and
of tail corn per 100 of total grain, from plots at Rothamsted
receiving ammonia salts and nitrate of soda, alone and with
mineral manures, for the forty years 1852 to 1891.

TABLE XXII.

Grain Tail Corn

Manures. per 10J per 100

Straw. Total Grain.

Ammonia salts, superphosphate, and alkaline salts 85'0 . 3-9

Nitrate of soda, superphosphate, and alkaline salts 81-4

Ammonia salts and superphosphate 90-7

Nitrate of soda and superphosphate 86'0

Ammonia salts and alkaline salts 88-0

Nitrate of soda and alkaline salts 81-5

Ammonia salts 91'2

Nitrate of soda 86*7

Average of four plots receiving ammonia salts . . 88-7
Average of four plots receiving nitrate of soda . . 83-9

4-9
5-3
5-0
5-7
6-5
6-6
7-0

5-4

5-8

In each pair of plots the proportion of grain to straw was
higher with ammonia salts than with nitrate of soda ; and
in each case, except \vhere superphosphate only was added
to the nitrogenous manures, the percentage of tail corn was
lower with ammonia salts.

To sum up the matter with regard to barley, sulphate of
ammonia gives a large increase in the crop ; and though this
is somewhat less on the average than that obtained from
nitrate of soda, yet the gain in quality wrill generally more
than make up for the smaller return. On a crop so liable to
be injured by over- manuring, the use of sulphate of ammonia
for barley after a sheepfold would, of course, almost always
be harmful ; but no practical man needs to be told that.
After wheat, however, or roots drawn off the land, or under

45

any conditions that impoverish the soil, a dressing of from
$ cwt. to i cwt. per acre is useful and economical. On very
hungry or poor land, up to i£ cwt. may be given with effect.
In all cases of manuring barley with sulphate of ammonia,
it is important to remember the need of the crop of minerals,
both phosphates and potash. These may be present in the
soil, either as a natural constituent or as a residue from pre-
vious manuring ; but if not, they must be supplied as manure,
or the sulphate cannot give its full effect.

OATS.

With regard to this crop, there are no records available
of experiments carried out over long series of years — such
as the wheat and barley experiments at Rothamsted and
Woburn. At the same time, the evidence we have on the
effect of sulphate of ammonia on oats is so free from contra-
dictions or anomalies, that we need have no hesitation in
accepting the conclusions arrived at.

At Rothamsted, experiments on the continuous growth of
oats were carried out from 1869 to 1878 ; but after the first
five years, the plots dressed with nitrate of soda became so
wet that the crop was badly got in, and the plant was there-
fore irregular. Taking, therefore, the first five years only,
the average results obtained were as follows per acre per

annum : —

TABLE XXIII.

1

DRESSEI

> GRAIN.

Total

Quantity.

Weight
per Bushel.

fetraw. .

TJnmanured

Bushels.
19*

Lbs.
334

Cwt.

103

Mineral manures*

244

35

AV$

134

Ammonia ^alts

47

3.5 Z

OH^

Ammonia salts and mineral manures*
Nitrate of soda

59

47i

37
351

4ij[

27$

Nitrate of soda and mineral manures*

57*

35|

35

* Mineral manures are in all cases sulphates of potash, soda, and
magnesia, and superphosphate.

Without minerals, ammonia salts and nitrate of soda gave
almost identical results ; but when minerals were given in
addition, the difference in the quantity of grain, though
slight, was in favour of ammonia salts, as was also the
weight per bushel. A somewhat unexpected point was the
larger proportion of the straw to the grain produced by the
ammonia salts.

If we were to include with the above the yields of the last
four crops, obtained in the five years 1874 to i878inclusive,
the average result would be much more in favour of ammonia

> *

46

salts compared with nitrate of soda ; but, as already ex-
plained, these years do not furnish such a fair compariso n of
the action of the two manures.

Other investigators have obtained similar results. Thus
Baessler* found, in experiments on a sandy humous soil, that
sulphate of ammonia applied to oats gave a yield of grain
about equal to that from nitrate of soda ; phosphates being
supplied in both cases. He found, however, that nitrate pro-
duced more straw. Rhodinf , on the average of two years,
found sulphate of ammonia distinctly better than nitrate of
soda in its results on oats grown on heavy clay.

Amongst experiments carried out on oats grown in rota-
tion on ordinary farms, we may take as typical those con-
ducted by the Glasgow and West of Scotland Technical
College on a number of farms in the south-west of Scotland
in each of the years 1894 an<3 1895. The following table
gives a summary of the average results per acre, as far as
they concern our present subject : —

TABLE XXIV.

1894.

1895.

AVERAGE.

13 FARMS.

15 FARMS.

1894-5.

Manures.

Corn, j Straw.

Corn.

Straw.

Corn. Straw.

Lbs.

Lbs.

Lbs.

Lbs.

Lbs. Lbs.

No manure

1375

2867

1358

2654

1366 2760

Sulphate of ammonia, 88 Ibs.

1803

3859

1683

3110

1743 3484

Nitrate of soda, 1 cwt. .

1749

3847 ! 1473

3000

1611 : 3423

Sulphate of ammonia, 88 Ibs.

superphosphate, 2 cwt.
Nitrate of soda, 1 cwt. ; super

2018

4132

1812

3017

1915 | 3574

phosphate, 2 cwt. . .

2004

4203

1763

3159

1883 3681

Sulphate of ammonia, 88 Ibs.

superphosphate, 2 cwt.

muriate of potash, 1 cwt.

2091

4396

1891

3139

1991 3767

Nitrate of soda, 1 cwt. ; super-

phosphate, 2 cwt. ; muriate

of potash, 1 cwt. . . .

1999

4257

1716

3141

1857 ' 3699

The results of these experiments are very consistent.
The increase obtained from all the manures was greater in
the wet season of 1894 tnan m tne dry one of 1895; but
the average produce of the different plots was in each year
in the same order. In every case the plots dressed with
sulphate of ammonia — whether used alone, with super-
phosphate, or with superphosphate and muriate of potash —
gave a larger yield of corn than the corresponding plots
receiving nitrate of soda. Also when used either alone or
with superphosphate and .muriate of potash, sulphate of
ammonia produced more straw than nitrate of soda; but

Bied. Centr.," 1889.

t " Exper. Stat. Kecord," 4.

47

with superphosphate only in addition to the nitrogenous
manures, the reverse was the case. It must also be noticed
that in each year nitrate of soda with superphosphate pro-
duced a rather better effect than the same manures with
muriate of potash in addition. On the other hand, the
addition of muriate of potash to sulphate of ammonia and
superphosphate raised the yield of both straw and grain.
Thus, again, we see the different effect of potash manures
with nitrate or sulphate of ammonia.

In each year the most productive plot was that manured
with sulphate of ammonia, superphosphate, and muriate of
potash, not only of those plots included in Table XXIV.,
but of others also which were in the scheme of the experi-
ments. Whether this manuring would prove most econo-
mical, would, of course, depend on the market price of the
manures and of produce. In any calculation on this subject,
it is well to remember that the quality of grain is likely to
be distinctly better when sulphate of ammonia is used than
with nitrate of soda.

In view of the common practice of top-dressing corn crops
with nitrogenous manures alone, when any top-dressing is
given, it is interesting to note the large increase obtained
by the use of mineral manures in addition. On the average
of the two years, the gain is equal to about 6 bushels of
corn and 2| cwt. of strawr per acre.

In passing, it may be noticed that these experiments seem
to explain an apparent discrepancy between the results
obtained at Rothamsted and those of Baessler quoted
above. It will be remembered that at Rothamsted,
ammonia salts and mineral manures gave a larger yield
of straw than nitrate and mineral manures ; while Baessler
found the opposite to be the case. In the latter experi-
ments, however, phosphates only wrere given in addition to
the nitrogenous manures. Turning to the Scotch experi-
ments, we find both these results confirmed ; ammonia salts
yielding most straw when phosphates and potash were sup-
plied, nitrate when phosphates only were added.

As a general rule, a dressing of f cwt. to i^ cwt. per acre
will give the best results in practice, though more than i cwt.
will only be required when the land is in poor condition.
Even in the case of ordinary farm land, the addition of
minerals to the nitrogenous manure will on the average give
a largely increased crop ; about 2 cwt. per acre of super-
phosphate, and the same quantity of kainite, being suitable
amounts to apply ; or basic slag might be used in place of
the superphosphate.

MANGELS.

In considering the results of experiments on this and other
similar crops, we are met with a difficulty in estimating the
economical effect of manures, because the composition, and

48

consequently the feeding value, of the roots is affected very
greatly by differences in manuring. As the root crops are
in the great majority of cases grown for consumption on the
farm, it is the feeding value rather than the market value
that must be taken into account.

EFFECT OF SULPHATE ON YIELD.

At Rothamsted, as far as weight of roots per acre is con-
cerned, nitrate of soda gave better results on mangels grown
continuously on the same land than ammonia salts. The
following table gives the weight of roots per acre per annum
on the average of seventeen years — 1876 to 1892 — produced
by the manurings mentioned : —

TABLE XXV.

Standard Manures. Alone.

With Nitrate
of Soda.

With Am-
monia Salts.

Tons.
Farmyard manure 15

Cwt.

10

15
15

5

Tons. Cwt.
21 8

22 8
14 14

14 16

Tons. Cwt.
21 1

20 6
8 1

13 9

Farmyard manure and superphos-

Superphosphate 4

Superphosphate and sulphate of
potash . : 4

These figures again illustrate the principles we have
noticed in the case of the corn crops. The addition of
nitrogenous manure gave in each instance a large increase ;
and again we see that, while superphosphate and nitrate of
soda give about the same return as those manures with
potash in addition, when ammonia salts take the place of
nitrate, potash manuring seems essential for a full crop.

EFFECT OF SULPHATE ON FEEDING VALUE.

When the amount of food for stock per acre is considered,
we find different results according to the treatment of the
crop as regards farmyard manure. As mangels are com-
paratively seldom grown without farmyard manure, and as
it is well established that they make use of it as well as, or
better than, any other crop, we will first deal with the feed-
ing value of the crops at Rothamsted to which farmyard
manure was applied. The most important food constituent
of the crop is sugar, the percentage of which, and quantity
produced per acre, on the plots manured with farmyard
manure, on the average of four years, 1877 to 1880, are given
in the following table.

49
TABLE XXVI.

—

ALONE.

NITRATE OF SODA.

AMMONIA SALTS.

Sugar
per Cent.

Sugar Sugar
per Acre. perCent.

Sugar
per Acre.

Sugar
per Cent.

Sugar
per Acre.

Lbs.
3409

3179

Farmyard manure . .
Farmyard manure and
superphosphate . .

8-04
8-10

Lbs.

2858

2487

6-69
6-42

Lbs.
2916

3069

7-20
6-80

The addition of the nitrogenous manures to the others
reduced the percentage of sugar in the roots, especially in
the case of nitrate of soda ; but the increase in the weight
of the crop more than counterbalanced this, so that the
weight of sugar per acre is increased. The largest quantity
of sugar per acre is produced by farmyard manure and
ammonia salts ; being 340 Ibs. greater than the highest
produce of sugar obtained with nitrate of soda — viz., that
from nitrate, farmyard manure, and superphosphate. Even
the smaller quantity of sugar produced by ammonia salts,
farmyard manure, and superphosphate, was still no Ibs.
per acre higher than the best yield from nitrate of soda.

We may conclude, therefore, from this that with farm-
yard manure ammonia salts produce more feeding mate-
rial per acre than nitrate of soda, though the weight of the
crop may be less.

Without farmyard manure, the opposite is the case ;
nitrate giving the largest amount of food per acre. The
following table shows the percentage and quantity per acre
of sugar, on the average of the plots at Rothamsted dressed
with superphosphate and sulphate of potash, and with a
complete mineral manuring, the minerals alone, and with
nitrogenous manures in addition : —

TABLE XXVII.

MANURES.

St'GAK.

Per Cent. Per Acre.

Mineral manures alone

Lbs.

Do. and nitrate of soda ....
Do. and ammonia salts ....

7-18
8-1 s

2740

.

2487

The figures given are the averages of four years— 1877-80.
This shows clearly the superiority of nitrate of soda for
mangels where no farmyard manure is used ; for the pro-
duce of sugar per acre is 253 Ibs. greater than from ammonia

50

salts. But, as has been already pointed out, mangels
grown without farmyard manure form only a small pro-
portion of the whole area under the crop, so this supe-
riority of nitrate of soda is relatively unimportant.

SULPHATE FOR MANGELS IN ROTATION.

These results obtained at Rothamsted are fully con-
firmed by many other experiments carried out on farms in
all parts of the country. For example, in an experiment
of the Norfolk Chamber of Agriculture in 1886,* on light
loam at Whitlingham, on mangels grown without farm
manure, a given quantity of nitrogen as nitrate of soda
gave a distinctly greater weight of roots than sulphate of
ammonia.

In the same year, the experiments of the Essex Agricul-
tural Society, in which farmyard manure was used, showed
an average advantage in weight of roots of only i4cvvt. per
acre from the use of nitrate of soda, compared with sulphate
of ammonia ; and from what we have seen of the
Rothamsted results, it is probable that the actual feeding
value in this case would be in favour of sulphate of
ammonia.

A good deal of difference of opinion exists amongst
farmers as to whether nitrogenous manures should be
applied to mangels with the seed or as a top-dressing later.
The experiments of the Essex Agricultural Society referred
to above, throw light on the question. Taking the re-
sults of strictly comparable plots, we obtain the following
averages : —

TABLE XXVIII.

Nitrogen applied Nitrogen applied
with Seed. in July.

Tons Cwt. Lbs. Tons Cwt. Lbs.

Average of nitrate of soda plots ... 24 12 54 .. 25 3 56
Average of sulphate of ammonia plots. 24 17 2 . . 23 11 8

There is not very much difference shown here, except
that evidently sulphate of ammonia should be applied at
seed time, and not as a top dressing later in the year.
Nitrate, on the other hand, was somewhat more effective
as a top dressing than when sown with seed.

Judging from the results of experiments, therefore, we
may conclude that when farmyard manure is used sulphate
of ammonia will yield, on the average, an almost equal
weight of roots per acre, compared with the produce of
nitrate of soda — particularly if there is also a plentiful
supply of phosphates and potash, either in the soil or in the
manures used. The feeding value per acre is also probably
higher when sulphate of ammonia is employed than with
nitrate of soda. Without farmyard manure, nitrate is

* " Journal of the Royal Agricultural Society of England," Vol. XXIII.,
S.S., Part I.

51

probably superior to sulphate of ammonia, both in yield
per acre and in feeding value.

From i to 2 cwt. per acre applied at seed time is a good
dressing in practice, with farmyard manure, 3 or 4 cwt. of
superphosphate, and 2 cwt. of kainite. These quantities are,
of course, variable according to soil and other conditions.

TURNIPS AND SWEDES.

Following the order adopted in considering other crops,
the experiments at Rothamsted on the continuous growth
of swedes, from 1856 to 1871, may first be examined. The
manuring of the plots was not absolutely the same all
through the experiment ; nitric acid and sawdust being
used in place of nitrate of soda for the first five years. For
the sake of brevity, however, we will speak of these plots
as receiving nitrate of soda.

The following table shows the weight of roots per acre
per annum produced by various manures :—

TABLE XXIX.

Manures.

Alone.

With
Ammonia
Salts.

With
Nitrate
of Soda.

Farmyard manure,

Tons. Cwt.
6 4

Tons. Cwt.
8 8

Tons. Cwt..
7 0

Do., and superphosphate
Unmanured

G 7
0 11

8 5
0 13

7 13

Om

Superphosphate

2 12

3 16

4 13

Superphosphate each year, and sul-
phate of potash for first five years.

2 7

4 5

4 11

The results are somewhat similar to those already noticed
in the case of mangels. With farmyard manure, ammonia
salts were undoubtedly more effective than nitrate of soda ;
while without farmyard manure, nitrate was in every in-
stance superior to ammonia salts in the weight of roots it
produced. The effect of potash, when used with super-
phosphate and a nitrogenous manure, was just what we.
have seen so often with regard to other crops — tending,,
if anything, to diminish the yield when nitrate was used,,
but increasing it with ammonia salts.

Passing on to experiments on turnips grown under ordi-
nary farm conditions, an important series, carried out in,
Banffshire,::: under the direction of the Highland and Agri-
cultural Society, in 1893-4, may be taken as an example.
The following are the results, so far as they concern the
present subject, obtained on the various plots for each of
the years of experiment. The results of 1893 are the

* " Transactions of the Highland and Agricultural Society," Vols. VI.
and VII., Fifth Ssries.

D 2 >

52

average of 25 experiments where artificials only were used,
and of 15 where farmyard manure was also employed.
Those of 1894 are t*16 averages of 22 and 16 experiments
respectively.

TABLE XXX.

1893.

1894.

Average.

With

With

With

With

With

With

Sulphate

Nitrate

Sulphate

Nitrate

Sulphate

Nitrate

of

of

of

of

of

of

Ammonia.

Soda.

Ammonia.

Soda.

Ammonia.

Soda.

Tons.Cwt.

Tons.Cwt.

Tons.Cwt.

Tons.Cwt.

Tons.Cwt.

Tons.Cwt.

Bone meal . .

18 17

17 15

17 5

15 7

18 1

16 11

Superphosphate

21 16

20 7

18 13

18 0

20 4

19 3

Bone meal and

farmyard

manure . .

22 2

20 19

17 12

18 1

19 17

19 10

^Superphosphate

and farmyard

manure . .

24 4

23 7

18 1

19 17

21 2

21 12

In 1893, witn each kind of additional manure, sulphate
of ammonia gave distinctly better results than nitrate of
soda ; and in 1894, sulphate was also more efficient when
-used with artificials only. With farmyard manure, how-
ever, contrary to what we should expect, nitrate gave a
better return, so that on the average of the two years it
yielded half a ton more roots with superphosphate and
farmyard manure, though with bonemeal and farmyard
manure it was still 7 cwt. inferior to sulphate of ammonia.
This is another example of the comparatively better effect
•of superphosphate and nitrate than of superphosphate and
sulphate. It is unfortunate that this series of experiments
<iid not include plots dressed with potash ; for it would
•have been interesting to see whether, as with other crops,
the addition of potash to the other manures would have
increased the yield where sulphate was used to a greater
extent than with nitrate.

The effect of season has much to do with the question of
the relative economy of sulphate of ammonia and nitrate of
goda on the turnip crop. Thus, in a similar experiment to
the above, carried out in the year 1892" — not included with
the results of 1893-4 because the manurings tested were
not exactly similar — sulphate of ammonia with bone meal
gave 10 cwt. more roots than nitrate; but with super-
phosphate, nitrate produced 9 cwt. more than sulphate, a
result less favourable to sulphate of ammonia than those
of 1893-4.

* " Transactions of the Highland and Agricultural Society," Vol. V.,
Fifth Series.

53

Another interesting comparison was afforded by the
experiments of the Norfolk Chamber of Agriculture in
i&86:;: with swedes. The following were the weights of
roots grown on the different plots named per acre on the
average of three farms : —

TABLE XXXI.

Mineral Manures.

Alone.

With 1J Cwt.
Sulphate of
Ammonia.

With l| Cwt.
Nitrate of
Soda.

Superphosphate, 4 cwt.
Do. with sulphate of
potash, 2 cwt. . . .

Tons. Cwt. Lbs.
14 2 97

15 4 31

Tons. Cwt. Lbs.
17 5 56

18 14 19

Tons. Cwt. Lbs.
16 14 74

18 8 48

The effect of potash with superphosphate and nitrate of
soda was rather greater than we have seen in other instances.
Sulphate of ammonia, however, whether with or without
potash, gav.e a larger weight of roots than nitrate.

One more instance may be quoted as showing how the
relative effects of sulphate and nitrate vary according to
the manures with which they are used. The following
results were obtained as the average of two experiments
carried out in 1897 under the direction of the Yorkshire
College. The figures relating to rape dust are included for
comparison : —

TABLE XXXII.

With i Cwt.
Sulphate of
Ammonia.

With 1 Cwt.
Nitrate of Soda.

With 3 Cwt.
Rape Dust.

Tons.

Cwt. Lbs.

Tons.

Cwt. Lbs.

Tons. Cwt. Lbs.

Farmyard manure, 15

tons ; kainite, 4 cwt. . 19

17

6

19

8

84

18

3

104

F

.M.,lotons;K.,4cwt.;

superphosphate, 3 cwt. 20

1

8

21

4

48

20

1

48

F

. M..lotons;K.,4cwt.;

bone meal, 5 cwt. . .

20

15

80

20

1

48

20

1

8

F

.M.,15tons;K.,4cwt.;

basic slag, 6 cwt. . .

18

2

16

19

17

56

17

15

80

F.M.,lotons;K.,4cwt.;

dissolved bones, 4 cwt.

23

4

72

10

3

24

20

9

32

P

.M.,15tons;K.,4c\vt.;

superphosphate 2 cwt.;

bone meal, 2 cwt. . .

22

3

C4

19

15

40

20

11

48

F

. M., 15 tons ; super-

phosphate, 2 cwt. ;

bone meal, 2 cwt. . .

20

1

8

18

5

40

19

17

20

Average . . .

20

12

20

.

13

80

19

11

48

* "Journal of the Royal Agricultural Society of Bngland,"
Vol. XXIII., S.S., Part I.

54

On the average, the seven plots dressed with sulphate of
ammonia produced about a ton per acre more roots than
the nitrate plots ; and the rape dust plots were about equal
to the latter. Looking at the results of the individual
plots, we see that in only two cases out of the seven did
nitrate give a higher yield than sulphate. Of these one
was the plot receiving superphosphate, which confirms
what we have already noticed ; and the other was the basic
slag plot, where possibly some of the nitrogen of the
sulphate of ammonia may have been lost through the
action of the lime of the slag. The high produce of
sulphate of ammonia with dissolved bones, compared with
nitrate is worth noticing ; for the results of many experi-
ments seem to show that the use of dissolved bones with
sulphate of ammonia gives particularly good returns.

In ordinary farm practice, the use of sulphate of am-
monia adds very much to the weight of the crop, and to
the extent of about i cwt. per acre may be relied on to
repay its cost and leave a profit. As we have seen with
other crops, potash manuring seems peculiarly helpful to
its action. The sulphate should be applied at the. time of
sowing, and will generally be found to give particularly
good results in seasons in which growth goes on late in the
year. It has been noted by many experimenters that
turnips grown with sulphate of ammonia are more healthy,
and keep better, than those grown with nitrate. This is
to be expected from what we have already said as to the
effect of the manures on the rankness of growth of all crops.

POTATOES.

The Rothamsted experiments naturally claim first atten-
tion with this, as with the other crops we have dealt with.
For the first twelve years of experiment in the continuous
growth of potatoes on the same land, the following were
the average weights of potatoes of different qualities per
acre per annum, and the percentage of diseased tubers
produced by various manurings.*

TABLE XXXIII.

Good.

Small.

Diseased.

Total.

Diseased
in Total.

Tons. Cwt.

Ton. Cwt.

Ton. Cwt.

Tons. Cwt.

Per Cent.

Unmanured . .

1 13£

0 5

0 ]|

1 19J

3-15

Mineral manures

3 7|

0 4|

0 2|

3 15|

3-45

Minerals and am

monia salts .

5 18£

0 ?i

0 83

G 14£

6-26

Minerals and ni

K trate of soda . .

5 17g

0 6j|

0 9£

G 13

7-00

* "Agricultural Students Gazette," New Scries, IV., 2.

55

Compared with the corn crops, we see here a relatively
large increase from the use of mineral manures alone ; but
still the nitrogenous manures gave a large further increase.
The produce is slightly higher with ammonia salts than
with nitrate of soda, both in total weight and in good
marketable potatoes.

The figures relating to disease are also interesting. As
would be expected, the proportion of diseased potatoes is
higher in the heavier crops grown by the use of nitrogenous
manures ; but it is important to notice that the crops grown
with nitrate were, on the average, more diseased than those
with ammonia salts. This, however, harmonizes with what
we know of the effects of the two manures on plant growth
generally.

Some interesting experiments were carried out by
Voelcker in i»68 and 1869, on the growth of potatoes in
rotation/1' In each year the experiment was carried out on
two farms. The following table gives the average results
per acre in each of the two years, and on the average of
both : —

TABLE XXXIV.

Manures.

1868. 1869.

Average.

Tons. Cwt. Lbs. Tons. Cwt. Lbs. Tons. Cwt. Lbs.

Unmanured 4 10 33 6 11 56 5 10 100

Superphosphate and potash

salts 7 5 100 8 5 2 i 7 15 51

•hju£rv4.£ru\so£*u.c»Wj y^Laoii ociita

and sulphate of ammonia

9

0

106

10

4

49

9

12

77

Superphosphate, potash salts

and nitrate of soda . .

7

9

12

9

11

110

8

10

61

Farmyard manure . . .

8

9

.51

9

17

21

9

3

36

The potash salts were in some cases crude potash salts,
and in others muriate of potash. Equal weights — 2 cwt.
per acre — of sulphate of ammonia and nitrate of soda were
used ; so that the sulphate plots received more nitrogen
than those dressed with nitrate.

The average results of the two years are very similar,
and to a great extent repeat what we have seen in the
Rothamsted results. But most noticeable is the superi-
ority of sulphate of ammonia used with superphosphate and
pctash salts, not only over nitrate of soda with the same
minerals, but to a less extent over farmyard manure.

The two artificial nitrogenous manures gave similar
results in an experiment carried out in Anglesey in 1893,
by the University College of North Wales, on a poor,
free-working soil on a clay subsoil. In this case, also,
equal weights of the manures were employed — i cwt. per

* " Journal of the Koyal Agricultural Society of England,"
Vol. VI., S.S.

56

acre — so that the sulphate of ammonia supplied more
nitrogen than the nitrate of soda by about 5 Ibs. per acre.
The following were the weights of potatoes grown per
acre : —

TABLE XXXV.

Manures.

Alone.

With Sulphate
of Ammonia,

With Nitrate
of Soda.

Superphosphate, 3 cwt. ;
sulphate of potash,
2 cwt

Tons. Cwt. Lbs.

Tons. Cwt. Lbs.
8 17 96

Tons. Cwt. Lbs.
4 14 32

Farmyard manure, 15
tons ; superphosphate,
3 cwt. ; sulphate oi
potash, 2 cwt. . . .

8 7 16

10 14 13

9 15 0

Average . . .

••:

9 15 110

7 4 72

The difference in favour of sulphate of ammonia when
artificials only were used is remarkable, and is possibly
partly due to accidental circumstances. That an actual
superiority of sulphate of ammonia was shown in this
experiment, may be inferred from the fact that the highest
produce of any of the plots — many of which are not in-
cluded above — was that from sulphate of ammonia with
farmyard manure and minerals. Nitrate of soda was used
in a number of different combinations, but at best gave a
crop nearly 7 cwt. worse than the best sulphate crop.

So as to avoid giving a partial view of the case, one
other experiment may be quoted. This was carried out
on two farms in Cumberland and Durham, in 1896, under
the direction of the Durham College of Science. The
artificial nitrogenous manures, it must be noticed, were
employed so as to give equal quantities of nitrogen, not in
equal weights of the manures. The following are some of
the results obtained : —

TABLE XXXVI.

Manures.

Large.

Small.

Total.

Tons. Cwt.
4 15
8 l£

7 lof
9 2
9 1J
9 8|

Ton. Cwt.
0 10£
0 17

0 19
0 llf
0 13
0 llf
0 15J

Tons
5

8

8
9
9
10
9

Cwt.
14§

14

Farmyard manure, 12 tons .
F.M., 12 tons ; superphosphate
kainite, 5 cwt

, 5 cwt.;

F.M., 12 tons ; S., 5 cwt.; K.,
nitrate of soda, 1^ cwt

5 cwt. ;

F.M., 12 tons ; S., 5 cwt. ; K., 5 cwt. ;
sulphate of ammonia, 1J cwt. . .
F.M., 12 tons; S., 5 cwt.; S.A.V
1J cwt

F.M., 12 tons; K., 5 cwt.
1£ cwt

; S.A.,

57

With a full mineral manuring, sulphate of ammonia and
nitrate of soda gave practically equal results. More ex-
ceptional, however, is the fact that the omission of kainite
from the full manuring containing sulphate of ammonia
caused a distinct increase in the produce. Possibly a
lighter dressing of kainite would have given a better return
than either the amount applied or the total omission of
potash manure.

The composition of potatoes grown with various manures
is chiefly important to the farmer when they are to be used
for feeding stock. It is, however, worth mentioning that,
just as we have seen with mangels, that the amount of
sugar produced per acre is greater by manuring with
ammonia salts than with nitrate of soda, when farmyard
manure is also applied to the crop, so with potatoes we
find that the chief feeding material they contain — starch —
is formed in larger quantity per acre with ammonia manures
than with nitrate. The amount of starch per acre per
annum in the crops on some of the plots at Rothamsted,
on the average of ten years — 1876 to 1885 — was as
follows : —

TABLE XXXVII.

No manure 1,120 Ibs. starch

Mineral manures 1,988 ,,

Minerals and ammonia salts .... 3,436 ,,

Minerals and nitrate of soda .... 3,368 „

The difference between the two plots receiving nitro-
genous manures, though not very large — 68 Ibs. of starch
per acre — is still distinctly in favour of ammonia salts.

Comparing all the evidence at our disposal, we may
safely conclude that, in practice, sulphate of ammonia will
prove the best nitrogenous manure for potatoes, and will
often give highly remunerative results. The quantity used
will, of course, vary according to the condition of the land
and the other manures employed ; but it should usually be
between i and 2 cwt. per acre.

BEANS.

This plant is a member of the natural order Leguminosse,
and, like other leguminous plants, has the special power
already noticed of obtaining the nitrogen it requires from
the air by means of the bacteria in the nodules on its roots.
As we should expect, therefore, it benefits less from the
application of nitrogenous manures than any of the other
crops we have noticed. The number of field experiments
with beans bearing on our subject is small, and may be
dealt with in few words.

In experiments on the continuous growth of beans, Sir
John Lawes and Sir Henry Gilbert found that nitrate of
soda produced greater effect than ammonia salts, but that
mineral manures were more important than either in their

-

58

influence on the yield. In opposition to this, Hellriegel*
found sulphate of ammonia more effective on the leguminous
crops generally than nitrate of soda.

On the whole, however, the conclusion cannot be avoided
that no nitrogenous manure will prove economical for
application to beans; and the subject need not be further
discussed.

CLOVER.

With this leguminous plant, as with beans, nitrogenous
manures are often of little use ; but the evidence afforded
by experiment is not quite so consistent as in the case of
beans.

In an early experiment at Rothamsted, the average pro-
duce of red clover hay per acre, from six plots, manured in
various ways, or left unmanured, was 4 tons 7 cwt. 76 Ibs.;
while six similar plots, receiving exactly the same manures,
but with the addition of ammonia salts to each, only
averaged 4 tons 4 cwt. 3 Ibs. — a falling off of about 3! cwt.
On the other hand, in the attempted continuous growth
of clover at Rothamsted, the produce of hay per acre on
the average of the seven crops grown in 29 years was, with
mineral manures only, 4171 Ibs. per acre, and with mineral
manures and nitrogenous manures in addition, 4555 Ibs.
per acre — a gain of about 3^ cwt. from the use of the nitro-
genous manures.

Somewhat more favourable results have sometimes been
obtained. For instance, Von Knieriemf found, on the
average of two seasons, an increase in the clover crop of
52 per cent, by the use of sulphate of ammonia and super-
phosphate, against 30 per cent, increase with super-
phosphate only. In the former case, the benefit of the
manuring extended into the second year ; but with super-
phosphate only, no effect was perceptible after the year of
application.

The general conclusion arrived at as the result of ex-
periment is that, though nitrogenous manures often give
an appreciable increase when applied to the clover crop,
yet they are very uncertain in their action, sometimes
actually diminishing the crop. In any case, they rarely
prove economical ; the cost of the manure usually exceed-
ing the value of the extra produce.

GRASS LAND.

The effect of any manuring on grass land is particularly
difficult to estimate, for mere bulk of produce is only one
of several factors — such as the botanical composition, the
feeding value, and the readiness with which stock eat the
grass. We will first consider the effect of sulphate of
ammonia on the weight of the crop only.

* "Ann. der Landw.," VII. and VIII. f "Bied. Centr.," 19.

59
INFLUENCE OF SULPHATE ON WEIGHT OF PRODUCE.

At Rothamsted, in the first twenty years of experiment,
the following were the average weights of hay per acre
per annum, produced on the plots mentioned :—

TABLE XXXVIII.

T/nmanured 21£ cwt.

Mineral manures 3o| ,,

Minerals and ammonia salts 51 ,,

Minerals and nitrate of soda 57 „

Both the nitrogenous manures gave a very large increase
when used with minerals ; but nitrate of soda produced
considerably more hay on the average than ammonia salts.
In comparing these two manures in order to estimate their
use on the farm, however, we must remember that, used
over a long series of years in large quantities, ammonia
salts cause a heavy loss of lime from the soil, and the land
therefore becomes sour and unfavourable for plant growth,
especially in the case of permanent grass. Thus at Rotham-
sted, after a time, the soil of plots dressed with ammonia
salts became so sour that in 1881 part of each plot was
dressed with chalk, to sweeten the land and replace the
lime which had been lost. The effect of this was to increase
the yield of these plots, and check the deterioration which
had occurred up to that time. In ordinary farm practice,
this souring of the soil would not occur to the same extent ;
and the two manures, sulphate and nitrate, would act
under more equal conditions. We see this in the average
results for the first seven years of experiment on the plots
at Rothamsted mentioned above. The average produce of
hay per acre per annum for that period was —

TABLE XXXIX.

Unmanured 25$ cwt.

Mineral manures 35 ,,

Minerals and ammonia salts otij ,,

Minerals and nitrate of soda (five years only) . . 5l| „

At first, then, ammonia salts gave the higher produce ;
but owing to their continuous application, the crop became
unhealthy, so that over the longer period nitrate produced
the heavier average yield.

Generally, therefore, in experiments on grass land on the
continuous use of manures, we find that nitrate gives the
higher yield of grass or hay per acre. Thus in the experi-
ments carried out by the Highland and Agricultural Society,
at Pumpherston, nitrate with superphosphate and potash
salts gave an average of 35-4 cwt. of hay, against 32-8 cwt.
yielded by sulphate of ammonia with the same mineral
manures. In the grass experiments at the Roya Agricul-

6o

tural College, Cirencester, a full manuring containing
nitrate produced more hay than one containing sulphate
of ammonia, though the average of all the plots dressed
with sulphate was higher than that of the plots receiving
nitrate. It may be noticed, in passing, that in the Ciren-
cester experiments potash manures seemed to have an
unfavourable effect on the action of sulphate of ammonia,
but to have assisted that of nitrate of soda.

Passing on to experiments on land in ordinary farming
condition, the evidence is somewhat conflicting. In some
experiments carried out in 1894, under the direction of the
Durham College of Science, on six farms in Durham and
Northumberland, the following weights of hay were
obtained : —

TABLE XL.

No manure 37J cwt.

Superphosphate and kainite . 43£ ,,

Superphosphate, kainite, and sulphate of ammonia . 45f ,,

Superphosphate, kainite, and nitrate of soda . . . 46f „

Nitrogenous manures here gave a very small increase
when added to minerals ; nitrate being slightly better in
this respect than sulphate of ammonia.

Similar results were obtained on nine farms in Cumber-
land, in 1895 ar]d 1896, when the following average weights
per acre per annum were obtained : —

TABLE XLI.

No manure 17f cwt.

Basic slag, kainite, and sulphate of ammonia ... 25 ,,
Basic slag, kainite, and nitrate of soda 25f ,,

On the other hand, in an experiment carried out on
twelve farms in Yorkshire, under the direction of the York-
shire College, the following average weights of hay per
acre were obtained from the application of the manures
mentioned : —

TABLE XLII.

Manures.

Alone.

With

Sulphate of
Ammonia.

With With 10 tons
Nitrate of ; Farmyard
Soda. ! Manure.

Unmanured ....

Cwt.
26

Cwt.
3H

Cwt.

271

Cwt.
30

Superphosphate, 3 cwt. .
Bone dust, 3 cwt. . . .

23f

25|

33
33£
33|

31£
31*

30*
32
33}

Superphosphate, 3 cwt. ;
kainite, 3 cwt
Dissolved bones, 3 cw't. .

27|

25£

36f
37

VAJJ

34£
33|

36
87|

Average

34

31J

6i

Equal weights of sulphate ot ammonia and nitrate of soda
were used — i cwt. in each case — so that more nitrogen was
applied to the sulphate plots. The season was, on the
whole, unfavourable to the action of artificial manures ;
and it is a curious result that of the plots dressed with non-
nitrogenous manures, all but one yielded less hay than the
unmanured land, the exception being the plot receiving
superphosphate and kainite. Nitrogenous manures in
every case gav^ a marked increase ; and in each of the six
sets of comparable plots sulphate of ammonia produced a
heavier crop than nitrate of soda — the average produce
being 2i cwt. of hay in favour of sulphate.

The figures relating to farmyard manure are given for
comparison. It is remarkable that in a season apparently
more favourable for the action of farmyard manure than
for that of artificials, the average produce from sulphate
of ammonia should be slightly higher than that from farm-
yard manure ; and not only on the average, but in four of
the six sets of comparable plots, sulphate gave the heavier
yield, and in a fifth set the two manures produced equal
crops.

As a matter of course, the residue left after the crop was
removed would be far greater in the case of farmyard
manure ; but against this must be put its high cost and
expense of applying, in all probability five or six times the
cost of using a hundredweight of sulphate of ammonia.
In this instance, there is no question that sulphate of
ammonia paid better than farmyard manure.

Comparing the farmyard manure plots with the nitrate
plots, we find that in every case but one the former gave
the best results ; superphosphate and nitrate being the only
exception.

We may therefore conclude that, though varying in its
effect under different conditions, sulphate of ammonia
compares favourably in its effects on grass land with any
other nitrogenous manure. If used in large quantities at
short intervals, it will certainly make the land sour after
a time, by causing loss of lime as already explained ; but
it is not in this way that farmers need to use it. In
practice it should rather be applied occasionally to supply
nitrogen in an effective and economical form, not to
displace altogether farmyard or mineral manures, which
supply other essential constituents of plant food.

THE INFLUENCE OF SULPHATE ON THE BOTANICAL COM-
POSITION OF THE HERBAGE.

It has been shown clearly in the Rothamsted and other
•experiments that continuous manurial treatment of any kind
invariably has a marked influence on the botanical composi-
tion of the herbage. Thus, continuous use of nitrogenous

62

manures had, by the seventh year of the Rothamsted experi-
ments, so strengthened and encouraged the growth of the
grasses that the clovers and other leguminous plants had
practically disappeared. At the same time, a change of
character took place in the plants which were present ; a
large proportion of leaf, and comparatively few stems and
seeds, being produced. The plants were also late in coming
to maturity, apparently later with ammonia salts than on
the plots manured with nitrate of soda.

The following table* shows the principal grasses found
on plots variously manured in the seventh season of experi-
ment, and the weight of each per cent, in the hay crop of
that year : —

TABLE XLIII.

Unmanured.

Mineral Manures.

Alone.

With
Ammonia

Salts.

With
Nitrate of
Soda.

Downy and yellow oat
grasses .

11-1

2-7
6-6
7-1
4-9
3-5
0-1
15-0
2-0

16-7

6-7
3-0
2-8
4-9
2-8
0-6
12-8
5-3

18-1

12-7
11-9
11-6
11-1
5-0
2-2
4-3
0-1

4-8

17-1
10-0
1-8 '
6-7
11-6
9-4
2-6
3-1

Rough and smooth stemmed
meadow grasses . .
Perennial ryegrass . .
Common bent grass . .
Yorkshire fog ....
Cocksfoot

Soft brome-grass . . .
Hard and meadow fescues
Tall oat gras^

Total graminaceous her-
bage
Total leguminous herbage .
Total miscellaneous her-
bace

74-1
6-9

19-0

66-4
24-1

9-5

89-7
0-1

10-2

89-7
0-9

9-4

The increase of the grasses and diminution of clover and
other leguminous plants, by the use of nitrogenous manures
is very remarkable ; and almost equally so is the difference
in effect of ammonia salts and nitrate of soda on individual
species. Thus, ammonia salts had greater effect than nitrate
of soda in encouraging the downy and yellow oat grasses,
common bent grass, and to a lesser extent Yorkshire fog,
and the fescues ; while nitrate increased the meadow grasses,
cocksfoot, and soft brome grass more than ammonia salts.
Similar results were obtained in the Highland and Agri-

Journal of th2 Royal Agricultural Society of England," Vol. XXIV.

63

cultural Society's experiments at Pumpherston.:;: A mixture
of grass seeds' was sown in 1887, and careful observations
were made year by year as to the proportion of the different
plants surviving on each of the variously manured plots.
The following table shows the number per cent, o'f each
species in the seed sown ; the number of plants of each
species, per cent., growing in 1893, tne ^ast year °f tne
experiment, on three differently treated plots ; and the
weight per cent, of produce of each species on the same plots
on the average of the three years 1891-3. The column
No. i gives the results of the plots receiving no manure,
No. 2 those of the plot manured with phosphates and potash,
and Xo. 3 those of the plot to which sulphate of ammonia
was given in addition to phosphates and potash.

TABLE XLIV.

Number
Per Cent,
of Seeds
Sown.

Number of Plants, Weight Per Cent.,
Per Cent., 1893. Average, 1891-3.

1 2

3

5-6
27-8
1-1
16-5
1-7
1-5

3-7

3-0
31-7
3-7
2-0

1

2

3

Perennial ryegrass .
Cocksfoot. . . .
Timothy . . . .
Dogstail . . . .
Foxtail

5-3
11-0
13-0
2-6
7-3
28-0

6-6
6-4
1 19-i)

10-5
22-8
3-3
15-1

2-1
6-1

22-2
15-4
2-5

7-8
26-6
1-7
12-1
0-3
2-6

4-8

10-3
25-4
6-5
1-9

6-0
34-0
5-0
26-0

6-7
11-0

4-0

8-5
0-5

4-2

53-0
6-0
17-0
0-3
1-4

6-0

2-0
10-0
1-1
0-1

3-0
51-0
3-3
21-0
2-0
0-7

3-5

0-7
12-5

o-t>

0-4

Meadow grasses. .
Fescues, meadow,
and tall. . . .
Fescues, sheep's
and hard . . .
Yorkshire fog . .
Clover

Weeds

In no case did the species appear at the end of the experi-
ment in the same proportions as in the seed. Speaking
generally, cocksfoot, dogstail, and the weed grass, Yorkshire
fog, had largely increased, and most of the other grasses
and clover had diminished. But the extent of this increase
and decrease is very different in the different plots. Thus,
considering the weight of the produce, cocksfoot increased
much more in the manured than in the unmanured plots,
but dogstail was more important relatively in the latter case.
Ryegrass had somewhat increased in proportion on the
unmanured land, but had diminished on the other plots —
chiefly on that receiving sulphate of ammonia.

INFLUENCE ON PALATABILITY AND FEEDING VALUE.
More important than the changes in the botanical com-
position of the herbage is the palatability of the produce lor

* " Transactions of the Highland and Agricultural Society," Vol. VI.,
Fifth Series.

stock, and its feeding value to the animal when eaten. On
these points there is little reliable information, owing to the
difficulty of such inquiries. At the close of the Pumpherston
experiments (some of the results of which have just been
given), the whole of the area of experiment was grazed ; and
several times during the season the extent to which the
different plots were fed down was estimated. The following
were the averages of these estimates ; 100 representing that
the crop was fed down as close as possible, 50 that 50 per
cent, had been eaten, and so on :—

TABLE XLV.

Unmanured 45 p c.

Superphosphate 65

Potash salts 78

Sulphate of ammonia, phosphates, and potash . . 47

Nitrate of soda, phosphates, and potash .... 27

The stock evidently preferred the crops grown without
nitrogen ; but from a farmer's point of view, the small
bulk usually obtained from the use of mineral manures
alone makes such dressings undesirable. The difference
between sulphate and nitrate is considerable, and, taken
in conjunction with the yields from these plots (nitrate
35-4 cwt. of hay, sulphate 32-8 cwt.), shows a decided
superiority in the effect of sulphate of ammonia.

One other experiment bearing on this point may be
mentioned, though it has not been carried far enough yet
to give very reliable results. On the Northumberland
County Council Farm, plots of poor grass land manured
in various ways were grazed in 1897 by sheep, and the
increase in live weight noted on each plot. In the four
months of experiment, the following live weight increase
was obtained per sheep and per acre : —

TABLE XLVI.

Per Sheep.

Per Acre.

No manure .

Lbs.
14-0

Lbs.
37-3

Superphosphate.

7 cwt. .

21-1

56-3

Superphosphate,
1$ cwt. . .

7 cwt. ; sulphate of potash,

27-1

72-3

Superphosphate,
monia, 97 Ibs.

7 cwt. ; sulphate of am-

29-6

79-0

LIVE WEIGHT INCREASE.

This is an experiment which obviously needs to be re-
peated frequently before it would be safe to generalize

65

from the results obtained; but as they stand, the above
figures point to a striking increase in feeding value per
acre, resulting from the use of sulphate of ammonia with
superphosphate. A number of manurings were tested
in the same way; but this gave the highest live weight
increase.

In the following year, however, when the same plots
were again grazed with sheep, but no further manure was
applied, sulphate of ammonia and superphosphate gave com-
paratively poor results. The produce was still not far short
of double that of the unmanured plot ; but the mineral
manures — particularly basic slag — gave relatively much
better results. This is very much what we should expect
from the consideration of the principles controlling the action
of sulphate of ammonia. A residue is left beyond the first
year after application ; but a considerable loss of nitrogen
takes place by drainage, especially during the winter. This
loss is less in the case of grass land than from arable ; but
still sulphate of ammonia cannot be expected to produce
relatively good results in the second season after application,
compared with mineral manures, the valuable constituents of
which are held safely by the soil. That the time elapsed since
the sulphate of ammonia was applied had some influence in
causing the inferior returns in the second year of experiment,
seems more probable from the fact that in the autumn and
early winter of 1897-8, when all the plots were grazed by
store cattle, the plot manured with sulphate of ammonia and
superphosphate carried the largest amount of stock ; being
equalled only by that dressed with half a ton of basic slag.
So that up till then at least, it was still doing well.

It will be noticed that, in these Northumberland experi-
ments, no other purely nitrogenous manures were employed ;
so that no further light is thrown on the effect of sulphate of
ammonia compared with nitrate of soda.

The available experiments, therefore, all seem to show
that sulphate of ammonia has a good effect on the feeding
value of the crop, besides giving a large increase in its
bulk. Used occasionally, and in moderate quantity — say,
from i to li cwt. per acre — the necessary minerals being
also present in the soil or manure, sulphate of ammonia will
give a better result on the average than any other purely
nitrogenous manure, if both the quantity and the quality
of the produce be taken into account.

We have now considered the general principles involved in
the use and action of sulphate of ammonia, and its effect on
the chief farm crops individually, as shown by experiment.
The conclusion arrived at is that, when used judiciously,
sulphate of ammonia is a most valuable nitrogenous
manure. But it must be repeated that it supplies only

66

nitrogen to crops, and therefore cannot be used with good
effect unless phosphates, and usually potash also, are
added to the soil. These mineral manures may often
be applied to one crop in the rotation, and sulphate of
ammonia to another ; and the minerals may be given as
artificials or as farmyard manure, or partly in one form and
partly in the other. But at some time in a series of years,
and in one or other form, minerals must be given, or the
use of nitrogenous manures cannot prove satisfactory.

SUMMARY.

I. — Sulphate of ammonia is a nitrogenous manure, and
must be considered as a source of nitrogen only.

2. — Nine other elements besides nitrogen are essential
for plant growth, of which phosphates and potash,
as well as nitrogen, must usually be supplied in
the manure.

3. — Combined nitrogen only can be used by plants.

4. — Combined nitrogen in Nature is supplied to the soil
only in small quantities, and is subject to con-
stant loss. The addition of nitrogenous manures
is therefore needed.

5. — Nitrogenous manures cause larger leaf growth, in-
creased chlorophyll formation, slower maturity,
and increased crops generally.

6. — Organic nitrogen is of no direct use to the plant.
Nitric and ammoniacal nitrogen are both directly
useful, though the latter almost always undergoes
nitrification before use.

7. — Ammoniacal manures generally fail to give their
maximum result unless potash is liberally supplied
by soil or manure.

3. — Sulphate of ammonia reacts in the soil with car-
bonate of lime, and carbonate of ammonia is
formed, which can then be fixed by the clay and
humus of the soil.

9. — Nitrogen may be lost by the volatilization of car-
bonate of ammonia, when sulphate of ammonia
has been applied to very calcareous soils ; but
this is rarely important.

I0. — Nitrification of ammonia compounds, especially
sulphate of ammonia, may be very rapid when
everything is favourable. It is more rapid than
the nitrification of organic nitrogenous matter.

ii. — After nitrification, the nitrogen is subject to loss
by drainage.

12. — Sulphate of ammonia is most effective in wet
climates and seasons.

67

13. — A small dressing of sulphate of ammonia may be
applied to autumn sown crops in autumn, but
most of it should be put on in spring. For all
other crops, it should be used at, or a little before,
the time of sowing the seed. If applied late in
the growth of the crop, sulphate of ammonia may
cause too great rankness.

14. — Sulphate of ammonia may be applied longer before
sou ing on heavy land than on light. It is less
suitable for very calcareous soils than for either
sandy or clay soils, and still less so for soils
deficient in lime.

15. — Sulphate of ammonia may leave a valuable residue
in the soil after the removal of the crop to which
it is applied.

16. — Too large a dressing of sulphate of ammonia causes
injury from over-rankness of growth and late
maturity, especially if mineral plant food be
deficient in the soil.

17. — Sulphate of ammonia should be mixed with dry
ashes, sand, &c., for convenience of sowing, or
with other manures, except those which contain
lime or carbonate of lime, or which are damp.

1 8. — Commercial sulphate of ammonia should be of 95 to
97 per cent, purity, containing about 24 to 25 per
cent, of ammonia. The chief impurities, apart
from sandy matter, are common salt, sulphate of
soda, sulphate of iron, arsenic, sulphuric acid, and
thiocyanate of ammonia, of which the last three
are most injurious.

19. — On wheat, sulphate of ammonia increases the quan-
tity of the produce and improves its quality.
About i cwt. per acre should be given.

20. — On barley, sulphate of ammonia gives large increase,
and on the average produces a better malting
sample than other nitrogenous manures. Average
dressing, f cwt. to i cwt. per acre.

21. — On oats, sulphate of ammonia usually yields a larger
increase of grain than nitrate of soda, and of straw
also if potash be plentifully supplied. Average
dressing, about i cwt. per acre.

22. — On mangels, when farmyard manure is used, sul-
phate of ammonia is probably superior to nitrate
of soda in produce per acre of food for stock, and
often in weight of crop. Without farmyard
manure, it has rather less effect. Average dres-
sing, i to 2 cwt. per acre.

23. — On turnips, sulphate of ammonia compares favour-
ably with nitrate, giving as large or larger crops,
which apparently keep better. Average dressing,
about i cwt. per acre.

68

24. — On potatoes, sulphate of ammonia gives very large
increase — almost always larger than that from
nitrate of soda. Sulphate is also less favourable
to the development of disease. Average dressing,
i to 2 cwt. per acre.
25. — On beans, sulphate of ammonia does not give any

profitable result.

26. — On clover, sulphate of ammonia is as effective as
other nitrogenous manures, but is rarely profitable.
27. — On grass land, sulphate of ammonia produces a
yield in weight about equal to, or slightly less
than, nitrate of soda. It specially encourages the
grasses at the expense of the clovers. The pro-
duce seems to be more palatable to stock than
that of nitrate of soda, and to have a high feeding
value. Average dressing, i to if cwt. per acre.
NOTE. — In the above summary, all comparisons between
sulphate of ammonia and nitrate of soda are between equal
quantities of nitrogen in the two forms. This is equivalent
to comparing the effect of a little over f cwt. of sulphate
with that of i cwt. of nitrate.

1894