Lecture 3B - Principles of Soil Science PDF

Summary

This lecture provides an overview of soil science, focusing on soil development, formation, and soil-forming processes. The lecture explores different processes including transformations, translocations, additions, and losses/removals. It also contains information on weathering and includes specific examples such as wetting and drying.

Full Transcript

AGRI 51
PRINCIPLES OF SOIL SCIENCE
 SOIL DEVELOPMENT AND
FORMATION
SOIL-FORMING PROCESSES

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 Soil Formation
Synonymous to soil genesis
The process of creating soil from “not soil”.
Scientific name for “not soil” is parent material

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 Soil Forming Processes
1. Transformations
2. Translocations
3. Additions
4. Losses/Removals

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 Soil Forming Processes

Diagrams illustrating some common
additions, removals, translocations and
transformations in soils, and how these
are useful in interpreting soil
development.

After Dijkerman (1974) and Simonson
(1978).

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 Soil Forming Processes
Transformations
Occur when soil constituents are chemically or physically
modified or destroyed and others are synthesized
Include:
Weathering of primary minerals
Decomposition of organic residues
Synthesis of organic acids, humus, and other products
Change in the size/ arrangement of mineral particles

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 Soil Forming Processes
Transformations
Parent materials are transformed into silicate clays
through chemical and physical weathering
These silicate clays and decomposition products
recombine to form new minerals, such as hydrous
oxides of iron and aluminum (or sesquioxides)

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 Soil Forming Processes
Transformations
Organic materials decompose and are incorporated
into the mineral aspect of soils
Other organic products, such as organic acids and
humus are synthesized from organic materials

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 Soil Forming Processes
Transformations
Weathering of large particles can cause the
formation of smaller particles
Particles can be arranged and built into aggregates

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 Soil Forming Processes
Transformations
Weathering
Any of the chemical or physical processes by which rocks
undergo chemical decomposition and physical disintegration.
Weathering usually occurs at the earth's surface, but it can also
occur at significant depths, for example, the percolation of
groundwater through fractures in bedrock.
It usually results in changes in color, texture, composition, or
hardness of the affected rocks

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 Soil Forming Processes
Transformations
Weathering
Controlled largely by climate
More water available, the more likely that chemical processes
can proceed
In arid climates, weathering processes move very slowly
Physical weathering will be the dominant process, but since it
relies on chemical weathering, it will also be quite slow

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
the breakdown of rock and mineral
particles by physical forces

This Photo by Unknown Author is licensed under CC
BY-SA-NC

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
a. Wetting and Drying
– soils that are wetted up may be prone to swelling, then shrink
when they dry out
– these seasonal effects are termed shrinkage and swelling
– subsidence is based upon such shrinkage and swelling of clays
under foundations
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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
b. Freezing and Thawing/Melting
– water expands when frozen and literally pushes the soil apart,
breaking it down
– when the ice thaws the soil can slump back again
– the overall process is rather like a very slow “churning”

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
c. Heating and Cooling
– extremes of temperature can cause the soil to expand and
contract
– the effect is less pronounced than that of freezing and thawing
but over time this can become significant

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
d. Grinding or Rubbing
– grinding of particles against each other leads to particle
disintegration, most obvious on the beach (evidence of abrasion
by water)
– Windblown dust and sand can also wear down rocks by abrasion

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
e. Unloading
– when pressure is placed upon soil, i.e. glacier on soil, it becomes
compressed
– when ice melts a huge weight is lifted and the soils may react
accordingly by uplifting and expanding

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 Soil Forming Processes
Transformations
Weathering
1. Physical Weathering
Factors and Processes Associated with Physical Weathering
f. Organisms
– if plant roots can push through concrete, soil presents little
obstacle
– Worms burrow their way through soil, mixing and aerating it all
through their lives

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
the process by which rocks are
decomposed, dissolved or
loosened by chemical processes
to form residual materials

This Photo by Unknown Author is licensed under CC BY

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Takes place in almost all types of rocks. Smaller rocks are
more susceptible, however, because they have a greater
amount of surface area
Chemical weathering is much more common in locations
where there is a lot of water

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
a. Hydration
– process where minerals in the rock absorb water and expand,
creating stress which causes the disintegration of rocks
– softer, more stressed, and more easily decomposed mineral
– E.g. CaSO4 + 2H2O → CaSO4.2H2O
anhydrite gypsum

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
b. Hydrolysis
– chemical reaction between the minerals in the rock and
hydrogen in rain water
– Water molecules split = H+ & OH- components; the H+ often
replaces a cation from the mineral structure

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
c. Carbonation
– dissolved carbon dioxide in rainwater or moisture
in surrounding air forms carbonic acid and reacts with the
minerals in the rock
– this process weakens the rock thus breaking it down in the
process.
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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
d. Dissolution
– process by which minerals in the rocks dissolve directly in water
– when the rocks dissolve, become ions in solution in the water,
and are carried away with it
– Ex. Gypsum dissolving in water (CaSO4.2H2O + 2H2O → Ca2+ + SO42- + 4H2O)
– Ex. Halite dissolving in water (NaCl + H2O → Na+ + Cl− + H2O)
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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
e. Oxidation
– takes place when oxygen combines with other elements in rocks to
form new types of rock
– these new substances are usually much softer, and thus easier for
other forces to break apart
– change in rock color is an indication of oxidation. One common
example is oxidation rust
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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
e. Oxidation
Examples:
4FeO (Ferrous oxide) + O2 → 2Fe2O3 (Ferric oxide)
4Fe3O4 (Magnetite) + O2 → 6Fe2O3 (Hematite)
2Fe2O3 (Hematite) + 3H2O → 2Fe2O3 · 3H2O (Limonite)

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
f. Reduction
- is the reverse of oxidation; it is equally important in changing soil color
to grey, blue, as ferric iron is converted to ferrous iron compounds.
Under the conditions of excess water, or water-logged conditions (less
or no oxygen), reduction takes place.
Fe2O3(s) + 6H+(aq) + 2e-→ 2Fe2+(aq) + 3H2O Fe(OH)3(s) + 3H+(aq) + e- → Fe2+(aq) + 3H2O
Hematite Bernalite

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 Soil Forming Processes
Transformations
Weathering
2. Chemical Weathering
Factors and Processes Associated with Chemical Weathering
f. Reduction
- Iron(III) oxide is reduced by hydrogen in a two-step process.

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 Soil Forming Processes
Translocations
Transfer of soil constituents
Involve the movement of inorganic and organic
materials laterally within a horizon or vertically
(up/down)from one horizon to another

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 Soil Forming Processes
Translocations
The downward translocation of ions, clay and mineral
fragments such as silica is important to the formation of
subsoil horizons
Over time, this process is one of the more visibly noticeable
as alterations in color, texture, and structure become
apparent
Downward translocation stops where the wetting front
stops. Maybe at the shallow depths in arid and semi-arid
regimes and maybe mostly out of the profile in humid areas
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 Soil Forming Processes
Translocations
Upward translocation of salts is important to the formation of
the saline and alkali soils of arid and semi-arid regions
Upward translocation stops at the soil surface when water
evaporates
When the water stops moving, then evaporates, salts are left
behind
Soil layers with calcium carbonate or other salt accumulations,
form this way
If this cycle occurs several times, a calcareous hardpan can
31 form
 Soil Forming Processes
Translocations

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https://www.fao.org/3/R4082E/r4082e08.htm
 Soil Forming Processes
Translocations
Hardpan
a hard, usually clay-rich layer of soil, lying at or just
below the ground surface, in which soil particles are
cemented together by silica, iron oxide, calcium
carbonate, or organic matter that has precipitated from
water percolating through the soil.
Hardpans do not soften when exposed to water

The duripan is a root-restrictive subsoil
layer that is primarily cemented by illuvial
silica.
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 Soil Forming Processes
Translocations
Soil organisms such as earthworms, incorporate
organic litter into the A and B horizons of the soil
Mound-building organisms, such as termites,
transport materials from deeper in the soil (B and
C horizons) to the surface
Burrowing of rodents also transport materials
through the soil

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 Soil Forming Processes
Translocations
Chelation also helps in translocation
Metal ions such as Fe and Al combine with organic
molecules released during humus formation
The organic-metal chelate is more soluble than the Fe or Al
minerals and is readily transported through the pedon

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 Soil Forming Processes
Additions
Inputs of materials to the soil profile from outside sources are
considered additions
Both human activity and natural processes could result in the
addition of materials to the soil
The most obvious is addition of organic matter

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 Soil Forming Processes
Additions
As soon as plant life begins to grow
in fresh parent material, organic
matter begins to accumulate
Dead organisms, plant foliage, roots,
etc., add organic materials to the
soil

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 Soil Forming Processes
Additions
By causing rivers to flood, rainfall is
indirectly responsible for the
addition of new sediment to the soil
on a flood plain
On the average, rainfall adds about
5 pounds of nitrogen per acre per
year

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 Soil Forming Processes
Additions
Minerals and other particles can be
carried to and added to a
developing soil (or any soil) by wind,
as wind-blown or aeolian material

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 Soil Forming Processes
Losses/Removals
Most losses occur by leaching
Leaching can remove water, salts or silica dissolved in
water, and organic acids and materials
Water moving through the soil dissolves certain minerals
and transports them into deeper layers
Erosion removes particles such as humus, clay, and silt from
the surface of the soil
Such losses can be serious because the material lost is
usually the most productive part of the soil profile
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 Soil Forming Processes
Losses/Removals
Evaporation and transpiration causes the soil to lose water
that is used by microorganisms and vegetation
Decomposition by microbes can remove organic matter
from the soil
Grazing and harvesting by animals and humans
causes nutrient losses and organic matter losses from the
soil

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 Soil Forming Processes
Losses/Removals
Oxygen is released into the atmosphere by growing plants
Carbon dioxide is consumed by growing plants, but lost to
the soil as fresh organic matter decays
When soil is wet, nitrogen can be changed to a gas and lost
to the atmosphere.

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Some processes of soil formation that are complexes of subprocesses and
reactions
Term Fourfold Brief Description
Categorization*
1a. Eluviation 3 Movement of material out of a portion of a soil profile

1b. Illuviation 3 Movement of material into a portion of soil profile

2a. Leaching (depletion) 2 General term for washing out or eluviating soluble materials from the
solum.

2b. Enrichment 1 General term for addition of material to a soil body.
3a. Erosion, surficial 2 Removal of material from the surface layer of a soil

3b. Cumulization 1 Aeolian, hydrologic and man-made additions of mineral particles to the
surface of a soil solum.
4a. Decalcification 3 Reactions that remove calcium carbonate from one or more soil horizons

4b. Calcification 3 Processes including accumulation of calcium carbonate in Ck and possibly
other horizons of a soil
5a. Salinization 3 The accumulation of soluble salts such as sulfates and chlorides of
calcium, magnesium, sodium, and potassium in salty (salic) horizons

5b. Desalinization 3 The removal of soluble salts from salic soil horizons
*The four categories are (1) additions, (2) losses, (3) translocation, and (4) transformation of material

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Some processes of soil formation that are complexes of subprocesses and
reactions
Term Fourfold Brief Description
Categorization*
6a. Alkalization (solonization) 3 The accumulation of sodium ions on the exchange sites in a soil

6b. Dealkalization
(solodization) 3 The leaching of sodium ions and salts from nitric horizons
7a. Lessivage 3 The mechanical migration of small mineral particles from the A to the B
horizons of a soil, producing in B horizons relative enrichment in clay (argillic
horizons)
7b. Pedoturbation 3 Biologic, physical (freeze-thaw and wet-dry cycles) churning and cycling of
soil materials, thereby homogenizing the solum in varying degrees

8a. Podzolization 3,4 The chemical migration of aluminum and iron and/or organic matter,
resulting in the concentration of silica (i.e. silication) in the layer eluviated

8b. Desilication 3,4 The chemical migration of silica out of the soil solum and thus the
concentration of sesquioxides in the solum (goethite, gibbsite, etc.), with or
without formation of ironstone (laterite; hardened plinthite) and concretions

8c. Resilication 4 Formation of kaolinite from gibbsite in presence of excess Si(OH)4 in
solution or formation of smectite from kaolinite in presence of large amounts
of Si(OH)4 at higher pH values
*The four categories are (1) additions, (2) losses, (3) translocation, and (4) transformation of material

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Some processes of soil formation that are complexes of subprocesses and
reactions
Term Fourfold Brief Description
Categorization*
9a. Decomposition 4 The breakdown of mineral and organic materials
9b. Synthesis 4 The formation of new particles of mineral and organic species
10a. Melanization 1,3 The darkening of light-colored mineral initial unconsolidated materials by
admixture of organic matter (as in a dark A or mollic or umbric horizons)
10b. Leucinization The paling of soil horizons by disappearance of dark organic materials either
3 through transformation to light-colored ones or through removal from the
horizons.
11a. Littering 1 The accumulation on the mineral soil surface of organic litter and associate
humus to a depth of less than 30 cm

11b. Humification 4 The transformation of raw organic material into humus

11c. Paludization 4 Processes regarded by some workers as geogenic rather than pedogenic,
including the accumulation of deep (>30 cm) deposits of organic matter as in
muck and peats (Histosols)

11d. Ripening 4 Chemical, biological, and physical changes in organic soil after air
penetrates previously waterlogged material.

11e. Mineralization 4 The release of oxide solids through decomposition of organic matter

45 *The four categories are (1) additions, (2) losses, (3) translocation, and (4) transformation of material
Some processes of soil formation that are complexes of subprocesses and
reactions
Term Fourfold Brief Description
Categorization*
12a. Braunification, 3,4 Release of iron from primary minerals and the dispersion of particles of iron
Rubification, Ferrugination oxide in increasing amounts; their progressive oxidation or hydration, giving
the soil mass brownish, reddish brown, and red colors, respectively

12b. Gleization 3,4 The reduction of iron under anaerobic “waterlogged” soil conditions, with the
production of bluish to greenish gray matrix colors, with or without yellowish
brown, brown, and black mottles, and ferric and manganiferous concretions
13a. Loosening 4 Increase in volume of voids by activity of plants, animals, and humans and
by freeze-thaw or other physical processes and by removal of material by
leaching.

13b. Hardening 4 Decrease in volume of voids by collapse and compaction and by filling of
some voids with fine earth, carbonates, silica and other materials.
*The four categories are (1) additions, (2) losses, (3) translocation, and (4) transformation of material

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