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Soil is the layer of minerals
and organic
matter, in thickness from centimetres
to a metre or more, on the land surface. Its main
components are mineral
matter, organic matter, moisture,
and air.
Soils differ in the ratio
of these components.
Modern soil concept
Soil is “the collection of natural bodies in the
earth's [sic] surface, in places modified or even made
by man of earthy materials, containing living matter and
supporting or capable of supporting plants out-of-doors.
Its upper limit is air or shallow water. At its margins
it grades to deep water or to barren areas of rock or
ice. Its lower limit to the not-soil beneath is perhaps
the most difficult to define. Soil includes the horizons
near the surface that differ from the underlying rock
material as a result of interactions, through time, of
climate, living organisms, parent materials, and relief.
In the few places where it contains thin cemented
horizons that are impermeable to roots, soil is as deep
as the deepest horizon. More commonly soil grades at its
lower margin to hard rock or to earthy materials
virtually devoid of roots, animals, or marks of other
biologic activity. The lower limit of soil, therefore,
is normally the lower limit of biologic activity, which
generally coincides with the common rooting depth of
native perennial plants” (Soil Survey Staff,
1975).
The “natural bodies” of this definition
include all genetically related parts of the soil. A
given part, such as a cemented layer, may not contain
living matter or be capable of supporting plants. It is,
however, still a part of the soil if it is genetically
related to the other parts and if the body as a unit
contains living matter and is capable of supporting
plants.
The definition includes as soil all natural bodies that
contain living
matter and are capable of supporting plants even
though they do not have genetically differentiated
parts. A fresh deposit of alluvium or earthy constructed
fill is soil if it can support plants. To be soil, a
natural body must contain living matter. This excludes
former soils now buried below the effects of organisms.
This is not to say that buried soils may not be
characterized by reference to taxonomic classes. It
merely means that they are not now members of the
collection of natural bodies called soil; they are
buried paleosols.
Not everything “capable of supporting plants
out-of-doors” is soil. Bodies of water that
support floating plants, such as algae, are not soil,
but the sediment below shallow water is soil if it can
support bottom-rooting plants such as cattails or reeds.
The above-ground parts of plants are also not soil,
although they may support parasitic plants. Rock that
mainly supports lichens on the surface or plants only in
widely spaced cracks is also excluded.
The time transition from not-soil to soil can be
illustrated by recent lava flows in warm regions under
heavy and very frequent rainfall. Plants become
established very quickly in such climates on the
basaltic lava, even through there is very little earthy
material. The plants are supported by the porous rock
filled with water containing plant nutrients. Organic
matter soon accumulates; but, before it does, the
dominantly porous broken lava in which plant roots grow
is soil. (Soil Survey Staff, 1993)
Soil components and processes
Minerals in soil are obtained from a variety of
sources, but the process which delivers the bulk is weathering
of rocks.
Weathering is the actions of wind, rain, ice, sunlight,
and biological processes on rocks that break them down
into smaller particles.
Weathering also releases ions
such as K+ and Mg2+ into the soil
solution. Some of these ions are taken up by plants, but
the majority not left in solution are absorbed through ion
exchange by clays
such as montmorillonite.
When the level of ions is low in the soil an equilibrium
process forces ions back into solution, where they can
be used by plants.
However if acid
is introduced into soil, hydrogen
ions bind in preference to clays, forcing ions out where
they can be washed away during rain. Acidity also
encourages the weathering of clays, releasing toxic
aluminium ions (of which clays are composed) into the
solution. To stop this occurring farmers apply alkalic
materials such as slaked-lime.
Although there exist plenty of elements such as nitrogen,
potassium
and phosphorus
necessary for plant growth in soil, very little of this
is in a form which plants can use. In processes such as nitrification
and mineralisation,
bacteria
and other organisms convert unusable forms (such as NH4+)
in to usable forms (such as NO3-).
The raw products are initially present as gases in the
atmosphere. Processes such as the nitrogen
cycle and carbon
cycle continually exchange nutrients
between the soil and atmosphere.
The organic store in soil is made up of plant debris,
animal excreta and other decomposing materials. A lot of
the carbon compounds react to form humus,
which is composed of very large molecules including
esters of carboxylic acid, phenolic compounds and
derivatives of benzene.
Organic material in soil provides nutrients necessary
for plant growth.
If oxygen enters the soil, e.g. due to lowering the ground
water table, organic matter in the soil will be
oxidised and this may lead to subsidence,
also due to increased ground pressure.
References
See also:
Suggested addition from Household Cyclopedia of 1881
The following text is taken from the Household
Cyclopedia of 1881,
and should be updated and integrated with the above
article:
Soils consist mostly of sand, lime, and clay, with
certain saline and organic substances in smaller and
varying proportions; but the examination of the ashes of
plants shows that a fertile soil must of necessity
contain an appreciable quantity of at least eleven
different substances, which in most cases exist in
greater or less relative abundance in the ash of
cultivated plants; and of these the proportions are not
by any means immaterial. In general, the soils which are
made up of the most various materials are called
alluvial; having been formed from the depositions of
floods and rivers. Many of them are extremely fertile.
Soils consist of two parts; of an organic part, which
can readily be burned away when the surface-soil is
heated to redness; and of an inorganic part, which
remains fixed in the fire, consisting of earthy and
saline substances from which, if carbonic acid or any
elastic gas be present, it may, however, be driven by
the heat. The organic part of soils is derived chiefly
from the remains of vegetables and animals which have
lived and died in and upon the soil, which have been
spread over it by rivers and rains, or which have been
added by the industry of man for the purposes of
increased fertility.
This organic part varies much in quantity, as well as
quality, in different soils. In peaty soils it is very
abundant, as well as in some rich, long cultivated
lands. In general, it rarely amounts to one-fourth, or
25 per cent. even in our best arable lands. Good wheat
soils contain often as little as eight parts in the
hundred of organic animal or vegetable matter; oats and
rye will grow in a soil containing only 1 1/2 per cent.;
and barley when only two or three parts per cent. are
present.
The inorganic portion of any given soil, again, is
divisible into two portions; that part which is soluble
in water, and thus easily taken up by plants, and a much
more bulky portion which is insoluble.
Sir Humphry
Davy found the following to be the composition of a
good productive soil.
-
In every 9 parts, 8 consisted of siliceous sand;
-
the remaining (one-ninth) part was composed, in
100 parts, as follows:
-
Carbonate
of lime (Chalk)
63 grains.
-
Pure silex 15 grains.
-
Pure alumina,
or the earth of clay 11 grains.
-
Iron
oxide (rust) of iron 3 grains.
-
Vegetable and other saline matter 5 grains.
-
Moisture and loss 3 grains.
Thus the whole amount of organic matter in this
instance is only 1 part in 200, or one-half of one per
cent.; a fact which, in itself, would demonstrate the
fallacy of supposing that decomposed animal and
vegetable matter in the soil form the exclusive supply
to growing plants.
Clayey soil
A clayey soil, though distinguished by the color
which it bears, namely black, white, yellow and red,
differs from all other soils, being tough, wet, and
cold, and consequently requiring a good deal of labor
from the husbandman before it can be sufficiently
pulverized, or placed in a state for bearing artificial
crops of corn or grass. Clay land is known by the
following qualities, or properties.
It holds water like a cup, and once wetted does not
soon dry. In like manner, when thoroughly dry, it is not
soon wetted; if we except the varieties which have a
thin surface, and are the worst of all to manage. In a
dry summer, clay cracks and shows a surface full of
small chinks, or openings. If ploughed in a wet state,
it sticks to the plough like mortar, and in a dry
summer, the plough turns it up in great clods, scarcely
to be broken or separated by the heaviest roller.
Clayey soils, when sufficiently enriched with
manures, are naturally well qualified for carrying crops
of wheat, oats, beans, and clover; but are not fitted
for barley, turnips, potatoes, etc., or even for being
kept under for grass longer than one year. Such soils
ought to be regularly summer-fallowed once in six, or at
least once in eight years, even when they are
comparatively in a clean state, as they contract a
sourness and adhesion from wet ploughing, only to be
removed by exposure to the sun and wind during the dry
months of summer. Soils of this kind receive little
benefit from winter ploughing, unless so far as their
surface is thereby presented to the frost, which mellows
and reduces them in a manner infinitely superior to what
could be accomplished by all the operations of man.
Still they are not cleaned or made free of weeds by
winter ploughing; and therefore this operation can only
be considered as a good means for producing a seed-bed,
in which the seeds of the future crop may be safely
deposited. Hence the necessity of cleansing clay soils
during the summer months, and of having always a large
part of every clay farm under summer fallow. All clayey
soils require great industry and care, as well as a
considerable portion of knowledge in dressing or
management to keep them in good condition; yet when
their natural toughness is got the better of, they
always yield the heaviest and most abundant crops. One
thing requisite for a clayey soil, is to keep it rich
and full of manure; a poor clay being the most
ungrateful of all soils, and hardly capable of repaying
the expense of labor, after being worn out and
exhausted. A clayey soil also receives, comparatively,
smell benefit from grass; and when once allowed to get
into a sterile condition, the most active endeavors will
with difficulty restore fertility to it after the lapse
of many years.
Upon light soils the case is very different. These
flourish under the grass husbandry; and bare summer
fallow is rarely required, because they may be cleaned
and cropped in the same year with that valuable
esculent, turnip. Upon light soils, however, wheat can
seldom be extensively cultivated; nor can a crop be
obtained of equal value, either in respect to quantity
or quality, as on clay sand loams. The best method of
procuring wheat on light lands, is to sow upon a clover
stubble, when the soil has got an artificial solidity of
body and is thereby rendered capable of sustaining the
grain till it arrives at maturity. The same observation
applies to soils of a gravelly nature; and upon both
barley is generally found of as great benefit as wheat.
Thin clays and peat earths are more friendly to the
growth of oats than of other grains, though in favorable
seasons a heavy crop of wheat may be obtained from a
thin clayey soil, when it has been completely
summer-fallowed and enriched with dung. A first
application of calcareous manure is generally
accompanied with great advantage upon these soils; but
when once the effect of this application is over, it can
hardly be repeated a second time, unless the land has
been very cautiously managed after the first dressing.
Neither of these soils is friendly to grass, yet there
is a necessity of exercising this husbandry with them,
because they are incapable of standing the plough more
than a year or two in the course of a rotation.
Wheat ought to be the predominant crop upon all the
rich clays and strong loams, and light soils of every
kind are well qualified for turnips, barley, etc. Upon
the thin and moorish soils, oats must necessarily
preserve a prominent rank, and grass seeds may be
cultivated upon every one of them, though with different
degrees of advantage, according to the natural and
artificial richness of each soil, or to the qualities
which it possesses for encouraging the growth of clover,
in the first instance, and preserving the roots of the
plant afterwards.
See also
Suggested reading
Logan, W. B., Dirt: The ecstatic skin of the earth.
1995 ISBN
1-57322-004-3
Faulkner, William. Plowman's Folly. New York, Grosset
& Dunlap. 1943. ISBN
0-93328-051-3
Jenny, Hans, Factors of Soil Formation: A System of
Quantitative Pedology 1941 ASIN B0006APBY4
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