Example Mississippi River natural levee showing different soils at different
positions on the levee.
Soils may be formed in place from rock
or formed in weathered rock and minerals that have been transported from
where the original rock occurred
Rocks
Consist of mixtures of minerals.
Igneous
Metamorphic
Sedimentary
Igneous rocks are formed from molten magma
and contain primary minerals. Sedimentary rocks are formed by deposition
and cementation of weathered products. Metamorphic rocks are formed from
igneous or sedimentary rocks by high pressure and temperature.
Weathering
Physical disintegration
Chemical decomposition
Physical disintegration causes decrease in size without appreciably altering composition. Differential stresses due to heating and cooling or expansion of ice break the rock. Abrasion due to water containing sediment or wind carrying debris is another type of physical weathering.
Chemical decomposition and synthesis alter
chemical composition. Four types of chemical weathering reactions are:
hydrolysis, hydration, acid dissolution and redox (particularly, Fe2+
/ Fe3+).
Five Factors of Soil Formation
Parent material
Climate
Organisms
Topography
Time
Soils defined -dynamic natural bodies having
properties derived from the combined effect of climate and biotic activities,
as modified by topography, acting on parent material over time.
Parent Material
Geologic material in which a soil forms.
Residual sedentary
Transport agent (site or type of deposit)
Colluvial
gravity
Alluvial
water (alluvial fan, flood plain and delta)
Marine
water (ocean)
Lacustrine
water (lake)
Glacial
ice
Eolian
wind
Residual
Develops in place from the underlying rock. If soil is young, properties tend to reflect effect of parent material. For example,
Igneous and metamorphic rock, if
Siliceous (granite and granite gneiss)
acid and sandy
Ferromagnesian (basalt and diorite)
nonacid and clayey
Sedimentary, if
Limestone
sand or clay impurities important
Sandstone
shallow if SiO2 is cementing agent but deep if CaCO3
Shale
clay minerals lead to clayey soil
Colluvial
Consists of coarse and stony debris detached from rocks and carried downslope by gravity.
Alluvial
These deposits occur as alluvial fans, flood plains and deltas.
Alluvial fan occurs at the discharge of an upland stream into a broader valley below. Coarse textured material.
Flood plains are adjacent to streams
and rivers. During floods, coarse sediment is deposited nearest the existing
channel and fine sediment further away, resulting in a natural levee.
Changes in the course of the stream result in a complex spatial pattern
of alternating coarse and fine sediments throughout the flood plain. If
there is a change in grade, the stream may cut through existing deposits,
thereby forming terraces.
Example Mississippi River
natural levee showing different soils at different
positions on the levee.
Complex soilscape on a flood
plain.
A delta occurs at the mouth of river and marks the downstream extent of a flood plain.
Marine Sediments
Unconsolidated marine sediments deposited
by streams emptying into oceans may undergo uplift. Common along Atlantic
and Gulf coasts. Vary from sandy to clayey.
Glacial Deposits
From a series of glaciations during the Pleistocene epoch. Each advancing ice sheet accumulated a great mass of unconsolidated material which was deposited as glacial drift when the glacier melted and retreated. Material directly deposition from the ice is called glacial till and occurs in formations called moraines. Streams originating in a glacier transported sediment away and produced outwash plains. Where regional topography impounded glacial melt, lakes formed and lacustrine deposits accumulated. Deltas of coarser materials occur in what was the inflow region whereas finer materials were deposited further away.
Ice sheet melt and resulting
topographical features.
Eolian
Deposits consisting of silt and some fine sand plus clay (loess) blanketed regions along the Mississippi and Missouri Rivers.
Organic Materials
Accumulate in wet places where plant growth
exceeds the rate of residue decomposition. Such organic deposits are known
as peat. Typical pattern of peat accumulation: 1) sedimentary (limnic)
peat, from aquatic plants, 2) herbaceous (telmatic) peat, from sedges
and so forth, then 3) woody (terrestic) peat, from trees.
Climate
Through effects of precipitation and temperature, climate affects the rates of biological, chemical and physical processes involved in soil formation. Effects of climate on soil formation include:
High precipitation and low temperature
increase organic matter in soil.
Leaching of soluble materials such as
CaCO3 increases with increasing precipitation.
Movement of clay in soil profile increase
with increasing precipitation.
Silicate clay and Al and Fe oxide formation
increase with increasing temperature.
In general, high rainfall and high temperature leads to deep weathering and soil leaching. Just contrast weathered profile of humid tropical soils with profile of arid soils from which soluble salts have not been leached.
Climate also indirectly influences soil
formation by its effect on natural vegetation. For example, trees under
humid climate, grasses under semiarid climate and brush under arid climate.
Organisms
Living organisms are responsible for accumulation of organic matter, nutrient cycling and profile mixing.
Difference in profiles of soils developed under grassland and forest vegetation include:
1) development of a high organic matter surface horizon under grass and 2) leached subsurface horizon (E) overlying a more clayey horizon (Bt) under forest.
Idealized prairie - forest
transition.
Forest type, deciduous versus coniferous also affects soil development because the higher rate of nutrient cycling in deciduous forest retards leaching of basic cations and soil acidification. For example, compare two soils from a biosequence in Louisiana that developed in loess:
Calhoun Jeanerette
Cover
pine and hardwood prairie
Solum
175 cm
125 cm
Clay
weathered
less weathered
pH
4.5
6.5
Topography
Landscape relief modifies the effects of organisms and climate on soil development. Effects of topography on soil formation include:
Thinner sola and less mature profile development on steeper slopes in humid region because profile development is retarded by erosion or reduced water infiltration.
Effect of a shallow water table (approximately parallel to the soil surface) on restricting drainage and, therefore, soil development.
Lower organic matter content and more shallow sola on southern slopes due to higher temperature and lower moisture.
In humid regions, greater wetness in depressional areas leads to accumulation of organic matter.
In arid regions, salt accumulation may occur in depressional areas.
Relative elevation and aspect also affect vegetation. For example, trees tend to occur in lower positions of prairie-forest transition zone and species composition is different on southern (prairie) and northern (forest) facing slopes.
Effect of slope on soil
development.
Effect of topography on
depth to shallow
ground water table and soil
drainage.
Time
Effects of climate and living organisms, modified by topography, on the development of soil from parent material takes time. Effect of time can be seen by looking at chronosequences in Mississippi and Red River alluvium.
The sequence of soils, Severn, Roxanna and Gallion (natural levees of the Red River) exhibits increasing extent of profile development including depth to CaCO3.
Soil Channel Age Depth to CaCO3
Severn
recent
< 50 cm
Roxanna
older
> 50 cm
Gallion
older
leached
Convent, Bruin and Dundee (natural levees of increasingly older channels of the Mississippi River) range from 3,000 to 6,000 years old.
Convent
Bruin
Dundee
Meander belt 5
5 - 3
4 - 2
Age
< 3000
> 3000
> 4000
Solum depth 15
cm
45 +
60 +
Meader belts of the Mississippi
River in Louisiana.
Processes of Soil Formation
The five factors of soil formation control four general processes responsible for soil formation:
Transformation -weathering / synthesis of minerals and decomposition / synthesis of organic matter.
Translocation -movement of mineral and organic soil constituents in the developing soil profile.
Addition -as of organic matter or by deposition.
Loss -as by leaching of soluble
constituents or due to erosion.
Example of Soil Genesis
Assume uniform parent material (loess) at time zero.
1. Production of organic matter by plants. Roots proliferate in the soil and organic debris litters the surface of parent material. Addition.
2. Nonliving organic matter is biochemically altered by microorganisms and physically incorporated into the surface as by earthworms. Transformation.
50 years
3. Weathering and transport of weathering products takes longer. Soluble salts are dissolved and transported downward by percolating water. Depending on rainfall and internal drainage, salts may be lost or precipitated at a lower depth. Organic acids accelerate weathering of minerals and secondary minerals are formed. Accumulation of organic matter extends deeper into the surface soil. Clay minerals are moved by water from near the soil surface to deeper in the developing profile. Transformation and translocation.
2,500 years
4. With sufficient secondary accumulation of clay, structure develops
10,000 years
Designations of Soil Profile Horizons
Besides the five master horizons there are subordinate and transitional horizons.
Subordinate horizons include:
Ap Plow layer
Bt Accumulation
of silicate clay
Bs Accumulation
of organic matter and Al and Fe oxides
Bx Fragipan (dense,
partially cemented and brittle)
Transitional horizons are gradations from
one master horizon to another such as AE, EB, BE and BC.