Soils Test Two Study Guide
Clod
a tightly compressed clump of soil
Andisols*
comes from volcanic ejecta; has high AL and humic content
Mollisols*
darker color and quality farming ground with upwards of 6 percent organic matter
Bulk Density
density of the soil as a whole
Forces that allow water to move through soils
gravity and capillary pressure
Soil order for organic soil
histisols
benefits of clay
holds onto water very well
Benefits of Sand
it is well drained
Ideal soil textural class for farming
loam
Most common soil textural class in Western Kentucky
Alford Silt Loam
Best soil order for farming
Mollisols
Difference between mollisols and alfisols
Mollisols are commonly darker in color and contain more organic matter than alfisols, which are older and lighter in color
Oxisols*
Oldest soils usually found in the tropics; highly weathered, red color, high iron content
Soil order common in forest
Oxisols
Gelisols*
Permafrost; cryoturbation occurs which is when freezing ad thawing turns the soils; this is sometimes called frost churning
Gravametric Water Content
the mass of the water in the soil measured in grams
Specific surface area of 1 gram of silt
1500 mm squared
Specific surface area of 1 gram of sand
30 mm squared
Specific surface area of 1 gram of clay
300000 mm squared
How much total water is on earth
400 billion billion gallons
What percent of water is used by agriculture
80%
Who much of the Earth's water is i the oceans?
97%
Alfisols*
Agrillic, natric, or kandic horizons with a high to medium base saturation
Twelve Soil Orders
Alfisols, Andisols, Aridisols, Entisols, Gelisols, Histols, Inceptisols, Mollisols, Oxisols, Spodosols, Ultisols, and Vertisols
Size of soil aggregates
Anything from 2 millimeters to 0.05 millimeters is sand. Things from 0.05 to 0.02 millimeters is silt. Anything below 0.02 millimeters is clay.
Ultisols
Argillic or kandic horizons with low base saturation
Bulk Density Calculation
Bulk density equals the weight of the soil in grams divided by the volume of the soil in centimeters cubed
Soil forming factor causing differences between aridisols and gelisols
Climate
Particle Densisty
Density of individual particles of of soil
Aridisols
Dry soil and common in desert conditions
Determining Available Water Content (AWC)
Field capacity minus wilting point
Water movement in loam soil over clay soil
The water would quickly fill all the pore space in the loam then slowly fill up the pore space in the clay
Vertisols
High swelliing in clay and deep cracks
Differences between Entisols, Inceptisols, and andisols
Inceptisols are the youngest with hardly any profile development. As they begin to develop horizons and organize, they become Entisols. Andisols are soils with volcanic material.
Mature Soils
Many layers and higher organic matter content. These soils are common around Kentucky
Soil Water Content at Field Capacity
Maximum amount of water that can be stored in a field
Porosity
Measure of how much of the soil is pore space and how much is soil particles
Spodosols
Spodic soils with high Fe, Al, and humus content
Components to Water Budget
Storage = Irrigation + Precipitation + Capillary Rise - runoff - evapotranspiration - deep percolation
Soil Texture's affect on bulk density and porosity
The larger the particles, the lower the bulk density and porosity. The vice versa is also true
Soil Structure
The manner in which soil particles are put together. In other words, it is how the different sand, silt, and clay particles are out together to form the soil structure.
Relationship between textural classes and available water content (AWC)
The sandier the soil the less the AWC and the more clay the soil has the higher the AWC
Water movement in loam soil over sandy soil
The water will completely fill the loam before it begins to drain through the sand. It will then quickly drain through the sand.
Soil forming factor responsible for difference between Inceptisol and Entisol
Time
Young Soils
Typically have less layers and low organic matter content with little plant life
Old Soils
Typically less layers than mature soil with a red color due to accumulation of iron oxide
Difference between alfisols and ultisols
Ultisols shrink and swell much more than aflisols due to a higher clay content; ultisols crack deeply when dry and swell up when wet much more than alfisols
Transpiration
Water loss from leaves into the atmosphere
Gravametric Water Content Calculations
Wet soil minus dry soil divided by dry soil times 100 and your answer is a percent
Histosols*
peat or bog wih over 20 percent organic matter
permanent wilting point
point at which plants are so short of water that they cannot recover
benefits of silt
ready holds onto and releases water
Entisols
second youngest soils with little profile development
Most important soil property affecting water movement in soil
size of soil pores
Ped
smallest coherent structure of soil
Soil Order with high sand content
spodosols
Adhesion of soil water
tendency of soil water to be attracted to itself
Cohesion of soil water
tendency of soil water to stay together and resist being torn apart
Volumetric Water Content
the space the water in the soil takes up measured in
Inceptisols*
the youngest soils with hardly any horizons or other characteristics
maximum retentative capactiy
total water that can be held in soil
hygroscopic water content
water contained in pores
Capillary Water
water in between pores
available water for plants
water levels between field capacity and wilting point
