Soil Properties Lecture Notes PDF

Summary

These lecture notes cover soil properties, focusing on physical aspects such as texture, particle size, pores, density, and permeability. They discuss how these properties relate to soil functions and usage.

Full Transcript

Physical Properties of
Soil
Chapter 4
 Objectives

After completing this chapter, you should be
able to:
Describe the concept of soil texture and its
importance
Identify the texture of a sample of soil
Describe soil permeability and related properties
Describe structure and its formation and
importance
Explain other physical properties
Discuss soil compaction and tilth
Physical Properties of
Soil
Soil characteristics: grower can
see or feel
Neither chemical nor biological,
but both affect them
Greatly affect how soils are used
to grow plants or other activities
 Soil Texture
Affects soil traits
Water-holding capacity
aeration

Most fundamental soil property
Determined by the proportion of soil
particles
Sand (large)
Silt (medium)
Clay (small)
Soil Particle Size
Effects of Particle Size
Affects two important
features
Specific surface area
Soil pores: Number and Size
Macropores (aeration pores):
large
Micropores: small
 Specific Surface Area
Is the total surface area of all the soil
particles in a volume of soil.

Why important?
Reactions on particle surfaces
Increased surface area, more nutrients
Water is held as film around soil
particles
Increased surface area, more total water
films
Surface Area
Surface Area
 Soil Pores
Macropores (aeration pores): large
Twisted nature slows movement of
water and air
As water drains, pulls air with it,
occupying macropores
Micropores: small
Retains some water after draining
Water films merge, excluding
oxygen
Difficult pathway for water
movement
Soil Pores
Soil particle size
affects pore size
Small particles create
many pores
Large particles create
fewer but larger pores

Micropores usually
hold water
Macropores usually
hold air
 Soil Separates
Division of mineral particles
Used by soil scientists

Consists of three broad classes
Sand (divided into four subcategories)
Silt
Clay

Makes up fine earth fraction
portion of the mineral particles of soil
smaller than 2 millimeters.
Determines soil texture
 Sand
Characteristics
Largest of the soil separates
Composed mainly of weathered grains of
quartz or other minerals
Particles range in size
Enough sand in a soil creates large pores,
so sand improves water infiltration (rate at
which water enters the soil) and aeration
Large amounts of sand lower the ability of
the soil to retain water and nutrients
 Silt
Characteristics
Medium-sized soil separate
Silt particles are silky or powdery to the
touch, like talc
Best ability to hold large amounts of water
in a form plants can use
Erodes readily in moving water and wind
 Clay
Characteristics
Smallest of the soil separates
Consists of tiny, sheet-like crystals
Results from chemical reactions
between weathered minerals to form
tiny particles of new minerals
USDA System of Soil Separates
Comparison of Soil Separate Size
 What about the other “big stuff”?
Large particles (larger than 2 mm i.e. gravel)
not part of soil texture
Add little specific surface area and no pores
Reduces water- and nutrient-holding
capacity
Especially if >15% of soil volume
 Textural Classification
Soil usually consists of more than
one soil separate
All three separates are found in most soils
Actual % is called soil texture
12 textural classes shown in the soil
triangle

Determining soil texture
Amount of sand, silt, and clay in a soil can
be measured by mechanical analysis
 Soil
Triangle
 Textural Classification
Largest class: Clay
Why?
As little as 40% clay
Loam
Mischaracterized as equal sand, silt, and clay
But portions are close in %
Sand
Particle size greatly influences soil properties
Note dominant sand fraction (coarse sandy loam,
loamy fine sand)
 Textural Classification

Soils can
generally be
classified as fine,
medium, or
coarse
 Characteristics of Textural Classes
– Indicative of several soil properties
Infiltration
Downward entry of water into the soil
Percolation
Downward movement of water through the soil
profile
Water-holding capacity

Example: Fine soils retain nutrients better
Rapid percolation in coarse soils leaches nutrients
Clay particles retain nutrient chemicals
 Soil Density and Permeability

Particle density (PD)
Density with no pore spaces
Varies due to mineral type and organic matter
Average 2.65 grams per cubic centimeter, low
variation

Bulk density (BD)
Actual density of a soil is less than the PD (includes
pore space)
More pore space – lower BD
Variation due to volume of pore space
Indicator of soil quality – higher or lower better?

BD = weighted dry soil/volume dry soil = g/cm3
 Porosity
Soil porosity
Measure of the soil volume that holds air and
water
Total pore space – measure of the soil volume
that holds air and water
Porosity = (wet weight (g) – dry weight
(g)) X 100
soil volume
Porosity from BD and PD:
Porosity = BD/PD X100
Which is more porous – sand or clay?
Texture Affects Soil Pores
 Permeability
Permeability
Ease with which air, water, and roots
move through
the soil
Depends on number of pores, but mostly
size and continuity of pores
Descriptive term with no numerical value
– can’t be directly measured
Movement of water can be measured –
hydraulic conductivity
“perc test”
 Soil Structure
How soil clumps together to form soil
aggregates
Peds: naturally occurring aggregates
Sand grain to several inches
more aggregated soil – better air and water flow
Clods: clumps of soil caused by tillage

Soil aggregation improves soil fertility and
quality of its functions

Classification traits
Grade: ped distinctiveness and strength
Class: ped size
Type: shape
Soil Structure: Class
Soil Structure: Type
Soil Structure: Type
Example:
Strong fine granular structure
 Structureless Soil
Single-grain
Sandy soils and soils without structure
Massive soils
Fine textured soils that lack structure
or function as a soil mass
Lack permeability
 Types of Soil Structure

Granular structure
Commonly found in A horizons
Platy structure
Usually found in E horizons
Blocky structure
Typical of many B horizons
Prismatic structures
Tend to occupy lower B and C
horizons
 Formation of Soil Structure

Two-step process
Soil creates a loose ped and the second cements
it
Weak aggregates are cemented to make them
distinct and strong
Large aggregates often contain smaller units
Smaller units held together by calcium ions that
bridge adjacent soil particles (flocculation)
When sodium displaces calcium (deflocculation),
structure degrades
Structure is not a permanent soil feature
Can be degraded by mismanagement
 Soil Consistence
Behavior of soil when pressure is
applied
Relates to the degree that soil
particles stick to one another or
other objects
Depends on how moist a soil is
Soils types and characteristics
Wet soil: stickiness and plasticity
Moist soil: loose, friable, and firm
Dry soil: determined by trying to
crush an air-dried mass of soil in the
hand
moisture levels.

Consistence Terms for Soil
Wet
Stickiness Plasticity Moist Dry

Nonsticky Nonplastic Loose Loose

Slightly sticky Slightly plastic Very friable Soft

Sticky Plastic Friable Slightly hard

Very sticky Very plastic Firm Moderately hard

Very firm Hard
Extremely firm Very hard
 Soil Tilth
Physical condition of tilled soil
Suggests how easy the soil is
to till
How easily a good seedbed can be made
How easily seedlings can come up
Ease of root growth
Combination of physical properties:
texture, structure, permeability, and
consistence
Tillage
Improves soil tilth for a time, improving soil
air–water relations for new seedling
Possible negative impacts?
 Injuries to Soil Tilth: Compaction
Results when pressure is applied to the soil
surface
– Primarily alters soil traits related to pores and soil strength
(degree that a soil can resist movement owing to pressure)
Can create:
– Reduced porosity and permeability
– Reduced air exchange and potassium uptake
– Decreased infiltration rates
– Increased erosion and evolution of nitrous oxide
– Reduced percolation and oxygen availability
– Tillage pan – compacted layers just below depth of tillage
– If soil particles cement together - hardpan
 Soil Compaction Measurement
Compare bulk density with
nearby unaffected soil BD
Most accurate

Cone penetrometer
 Injuries to Soil Tilth: Direct
Aggregation Destruction
Plowing tends to create large aggregates
Rototiller crushes soil aggregates
Favored by gardeners for workability
Structure degraded over time

How tillage destroys aggregates
Stirring in oxygen – increase organic matter
oxidation
Decreasing organic glue holding peds together
Smashes non-weakened peds
 Injuries to Soil Tilth: Puddling
and Clods
Working wet soil – bad…especially soils
high in clay
When pressure is applied to wet soil
aggregates, they fall apart
Puddling – conversion of aggregates soil into
massive soil
Decreased water movement
Puddling on purpose?
Rice paddies, canals, and reservoirs
Reduces water leaking away
 Injuries to Soil Tilth: Surface
Crusts
Raindrops hit bare soil and destroy aggregates
Small particles fill pores between large
particles
Dries into hardened crust
Higher clay content worsens effect
Irrigation can increase crust formation

Result in:
Reduced water infiltration and soil aeration
Reduced seed emergence
Irrigation must be applied slower
 Improving Tilth
Based on texture, structure, permeability,
and consistence

Texture and consistence usually can’t be
changed
Improving structure and avoiding
compaction
 Improving Tilth: few BMPs
Never work wet or very dry soil
Avoid unnecessary traffic
Reduce number of tillage operations
Use modern tillage practices
Deep plowing or subsoiling
 Physical Property Management:
Overview
Considerations
– Avoid aggregate destruction
– Avoid puddling and clods
– Minimize surface crusting
– Improve tilth
 Soil Channels and Pans
Channels
– Large, continuous pores extending from the surface and leading
deeper into the soil
– Channels created by soil life - biopores
Any hardened layer of soil is a pan
 Types of Pans
– Claypans
Occur where extreme illuviation has caused a very high clay content in a
subsoil layer
– Fragipans
Like claypans, result from clay accumulation.
Clay combines into hard, brittle layer
– Plinthite
Layers cemented by special clay common to tropics
Hardens to brick-like substance and cannot be reversed by wetting
– Caliche and duripans
Layers of soils in which chemicals cement soil particles together
Lime cements caliche
– American Southwest common issue
 Soil Temperature

Critical for plant growth and development
3 Important factors
– Sunlight and air energy inputs
– Absorption and conductance of heat
– Loss of heat at the surface
Temperature effects
– seed germination
– root growth
– water and nutrient availability
– biological activity
 Managing Soil Temperature

Natural conditions with no control
– Light intensity and air temperature
Watering and soil manipulations
– Watering can cool
– Plowing in fall can raise spring soil temperatures
– Mulching most effective
Fire and Soil Temperature
– After a fire, vegetation is gone (allow light penetration)
– Black ash absorbs more heat
– Mineral resources recycled back to soil
 Soil Color
Indicates:
– Nutrient composition
– Organic matter
– Drainage of soils
Color as a guide to soil use
– Used to classify soils according to color

Describing Soil Color
– Munsell color system – matches color chips
Hue – color (i.e. red or yellow)
Value – lightness or darkness of color
Chroma – purity of a dominant color – denoted as a number
Munsell Color System