soil physical properties chapter 4
DESCRIPTION
SOIL PHYSICAL PROPERTIES Chapter 4. Color. Color. Thus, red = oxidized = aerated but gray = reduced = anoxic, poorly aerated. The oxidation state of Fe in Fe 2 O 3 and Fe 2 O 3 H 2 O is + 3. Color. This surface horizon is dark due to enrich- ment in organic matter from grass roots and - PowerPoint PPT PresentationTRANSCRIPT
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SOIL PHYSICAL PROPERTIES
Chapter 4
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Color
Texture
Structure
Consistence
Particle density
Bulk density
Pore space
Water content
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COLOR
Measured in reference to standard colorchips (Munsell Color Book)
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Huedominant spectralcolor
Valuerelative blacknessor whiteness
Chromaamount ofpigment mixedwith gray value
Color
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Interpretation color
Brown Organic matterBlack
Red Hematite, Fe2O3
Yellow Goethite, Fe2O3 · H2O
Gray Fe3+ Fe2+, reduced iron
Color
Thus, red = oxidized = aerated but gray = reduced = anoxic, poorly aerated.The oxidation state of Fe in Fe2O3 and Fe2O3 H2O is + 3.
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Color
This surface horizonis dark due to enrich-ment in organic matterfrom grass roots andsurface residue.
Common feature ofprairie soils is highorganic matter contentto appreciable depth(see inches).
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Good or bad drainage and aeration?
Red
Yellow
Gray
Color
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Green blue Gley horizon
EXTREMELY POOR drainage
Color
These colors, certainly, but also gray color generally indicate poor drainageand aeration. Colors of chroma 2 or 1 indicate gley.
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Mottling Varied colors
Mottles Drainage and aeration
None Good
Brown ModerateYellowGray
Gray PoorBlue
Color
These secondary colors modify one’s interpretation based on the main(matrix) color –like yellow or gray within an otherwise oxidized matrix saydrainage and aeration are not uniformly good. And visa-versa –red mottlesagainst gray matrix = some veins that are well drained / aerated.
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TEXTURE
Proportion of different size particles
USDA classification system
2.0 to 1.0 mm sand very coarse1.0 to 0.5 coarse0.5 to 0.25 medium0.25 to 0.10 fine0.10 to 0.05 very fine
0.05 to 0.002 silt
0.002 to smaller clay
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Texture
Illustration of howsurface area increaseswith decreasing size.
If you prefer algebra,for a cube, A = 6s2 andV = s3, so A / V = 6 / s.The smaller the cubes,the greater the surfacearea per volume (or permass, since mass isproportional to volumethrough density).
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As surface area increases
Chemical adsorption Increase or DecreaseWeathering rateParticle coherenceWater holding capacity
Tillage ease
Texture
All these are surface phenomena, therefore,increase with increasing particle surface area.
On the other hand, pulling an implement througha clayey soil is much harder than through asandy soil, no?
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Textural Classes
Coarse Medium Fine
Sandy soils Loamy soils Clayey soils
Sand Sandy loam Sandy clayLoamy sand Loam Silty clay
Silt loam ClaySiltSandy clay loamSilty clay loamClay loam
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What’s thetextural class of a soil that’s
50 % sand10 % silt
Answer,sandy clay.
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Determination of Textural Class
Feel methodMechanical analysis
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Mechanical analysis
Based on Stokes’ law
Settling rate of spherical particles in a viscous liquid
Texture
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FUP = Bouyant + Drag
FDOWN = Gravity
FBouyant = 1/6 π d3 ρL g
FDrag = 3 π d μ V
FGravity = 1/6 π d3 ρS g
At equilibrium, i.e., terminal velocity, forces balance
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v = g( s - l)d2/18
Settling velocity decreases as d2 decreases
Texture
Smaller d means smaller v, no? So comparing the largest clay (d = 0.002 mm) to largest sand (d = 2 mm), vclay / vsand = 0.0022 / 22 = 1 / 1,000,000.
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Pipette method
v = z / t
t = 18 z / [g ( s - l) d2]
Find t for particlesdiameter d
Texture
Express velocity as distance / time,rearrange and find time need for smallestsand to settle a prescribed distance. So,aliquot taken above this depth contains no sand, only silt and clay. Do samecalculation for smallest silt, take aliquot at that time and it contains only clay.
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Separate Minimum size Time to settle 10cm
Sand d > 0.05 mm < 1 minSilt d > 0.002 mm 8 hr
Texture
Your times may vary depending on density and viscosity of the medium (seeequation). Besides any solutes added to aid dispersion of particles, temperatureaffects these parameters.
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Must disperse clay particles
Some adsorbed cations like Ca2+ hold clayparticles together (flocculated)
Replace these with Na+ to disperse
Texture
Depending on the nature of the soil, more extensive methods may be necessaryto disperse particles.
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Soil texture may be considered a permanentproperty of a soil
Why so? Suggest a few ways by whichtexture can be changed.
Sure, erosion can change texture at a location but barring gross erosion, this is slow.Certainly, internal translocation of clay will make the topsoil more sandy but this isvery, very slow. Unless you move a lot of dirt around, texture is effectively a fixedproperty.
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STRUCTURE
Particles adhering together into aggregates or peds
Some soils are structureless
Single grain noncoherent
Massive cohesive mass
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Circle correct answer.
Some clay / sandy soils are singlegrain structureless soils.
Some clay / sandy soils are massivestructureless soils.
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Types of structural units
Spherical Crumb Granular
Common in surface soils
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Platy
Surface and subsurface
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Prism Columnar (tops of prismlike unitsrounded)
Prismatic (tops angular)
Subsoil
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Blocky Angular blocky(edges distinct)
Subangular blocky (rounded)
Usually subsoil
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Description of structure includes
Relative size class
Strength of cohesion grade
Structure
Munsell book give guide.
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Structure affects water movement
Easiest in soil with which structure?
A) massive, B) blocky, or C) platy
Probably blocky because the large pores between aggregates aremore vertically oriented than in soil with platy structure. Obviously,the tiny pores in a massive clay conduct water very slowly.
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How does structure develop?
Adhesive effect of organic substances
Flocculating cations
Shrink-swell clays
The organics jointly adhere to surfacesof adjacent mineral particles. Cations likeCa2+ tend to be closely associated withparticle surfaces, bridging adjacent minerals.Shrink-swell clays tend to give persistentinternal fissures.
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REVIEW QUESTIONS
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The B horizon of soil X is red andthe B horizon of soil Y is yellowwith gray mottles.
Which one is better drained?
What’s the gray color due to?
X is better drained. You know this because the color indicates oxidized Fe, Fe3+,which exists under a prevailing oxidized (oxic, aerated) environment. On theother hand, gray color is due to chemically reduced Fe, Fe2+, that occurs underanoxic conditions.
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The capacity to adsorb chemicals isgreatest in soils that have whichtexture?
ClayLoamSandy loamSand
And why? The one with the greatest surface area, clay, of course.
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Name the 4 general types of soilstructure (geometric shape types).
The four types of geometric structure are spherical (all dimensions about thesame with radial orientation, one dimension short compared to the other two, i.e., flat = platy, one dimension long compared to the other two, i.e., elongated =prism-like and all dimensions about the same but with x-y-z orientation, i.e.,cubic = blocky.
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Name the 2 types of prism-likestructure.
Name the 2 types of blocky structure.
It couldn’t hurt to remember these and the subtypes of spherical structure.
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Surface Structure Management
Aggregate stability favored by
Organic matter
Flocculating cations
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May be destroyed by rain or tillage andtraffic, leading to a crust
Infiltration slow and runoff fast
Structure
Crust = dense, i.e., low porosity and pores aresmall so that infiltration is greatly reduced. Bad.
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Puddled
Tillage when soil is too wet can puddle it
Especially clay soil
Structure
Sure, there are large pores between clods but the large pores that previously existed throughout are gone.Bad.
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Minimize tillage
Keep residues on soil
Use cover crops
Even add organic matter
Protect surface and addorganic matter
Structure
Protecting an otherwise bare surface from raindrop impact willpreserve surface aggregation, thus, preserve good infiltration, soilwater conservation and limit runoff, erosion and downhill degradation of surface water quality. Adding organic matter aids structure stabilityand redevelopment if degraded.
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SOIL CONSISTENCE
Resistance of soil to mechanical stresses
Judged at different moisture contents
Besides color, texture and structure, this is another feature included in horizondescriptions.
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Moist soils
LooseVery friableFriableFirmVery firm
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PARTICLE DENSITY
ρs = mass soil solids / volume solids(g / cm3)
Depends on mineralogy to some extent
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So, how would you go aboutdetermining the particle density of asoil sample?
Use what is given on the next pageand pencil and paper.
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Doesn’t vary much
Average 2.65 g cm-3
Well, it can vary depending on whether a very low density mineral predominates,however, this is usually not the case and common soil minerals have densitiesthat are about 2.65 g cm-3.
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BULK DENSITY
ρb = mass of soil solids / total volumeoccupied by solids (g / cm3)
Is ρb greater than or less than ρs?
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Remove a core of known volume
Mass of solids is determined afterwater is evaporated (105 C)
Why 105 C? The boiling point ofwater is 100 C, isn’t it?
You are dealing with a solution. Recall that solutes elevate the boiling point.
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Bulk density depends on
TextureDepth in profileTillage
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Small porous aggregates
Solid grains
Higher in coarse textured soils?
This is the usual explanation –internal porosityof small aggregates that exist in finer texturesoil compared with sand, which tends to lackmuch aggregation.
Clayey soils are considered heavy by virtueof their typically higher water content. Strictlybased on bulk density (oven-dry mass), theyshould be considered light.
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Higher in subsoil?
Compaction greater there?
Less organic matter there?If ‘yes,’ then is aggregation less there?
Yes to all, no?
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Higher in tilled soils?
Is compaction a possibility?
What effect does tillage have on theamount of organic matter in soil?
Well, the answer depends on your time of reference. Obviously, if you till asoil, you fluff it up, therefore, instantaneously reduce the bulk density. However,the fluff goes away and the soil reconsolidates. The long-term effect pertains todestruction of organic matter with consequent loss of porosity, especially the larger pores. So, in the long-term density increases. Heavy equipment tendsto compact the soil. Plowing also tends to increase subsurface density (lifting thesurface soil up, pushes the soil below it down).
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This is the classic observation. Many studies, many places.However, this can be, to various extent, reversed by reducingtillage and adding organic matter.
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High bulk density is a good thingbecause water, air and roots movemore easily through a very dense,low porosity soil than through a lessdense, high porosity soil.
True / False
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Related terms
Hectare-furrow slice mass of hectare to 15cm
2200 Mg
Acre-furrow slice mass of acre to6 in
1000 tons
Obviously, these are expressions for bulk density.Let’s see what density is implied on a g cm-3 basis.
ρB = 2,200 Mg x 1000 kg Mg-1 x 1000 g kg-1 /10,000 m2 ha-1 x 0.15 m x 1,000,000 cm3 m-3
1.47 g cm-3
These density units are useful in production-scale calculations. By the way,what is the bulk density (g cm-3) assumed when saying an AFS weighs 1000 tons?
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PORE SPACE
Occupied by air or soil water
Vp = Vt - Vs
If you know bulk density and particledensity you can calculate pore space.Show how.
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If this volume wascompletely filled withsolid particles it wouldhave a mass = Vt s
But it has a mass = Vt b
So this volume is only b / s filled with solids
So
ρs
ρb
ρb / ρs
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Vp = Vt - Vt ( b / s)
or, as a fraction,
Vp / Vt = 1 - b / s
Pore space and bulk density are inverselyrelated
(ρb / ρs)
(ρb / ρs)
If you don’t think this is an intuitive approach, try algebra. The volume of solidsVs = ms / ρS (from definition of ρS) so Vp = Vt - ρB x ms. The mass of solids,ms = ρB x Vt (from definition of ρB), so Vp = Vt – (ρB / ρS) x Vt. Now divide by Vt.
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OK, you’ve got a core of soil that has abulk density of 1.30 g / cm3 and aparticle density of 2.60 g / cm3.
What fraction of it is pore space?
How much water would be in 1 m3 ofthis soil if it was completely saturatedwith water?
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Are all pores in a soil the same size?
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True or False?
Macropores rapid water flow and goodaeration
Micropores slow and poor
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Distribution of pore sizes is affected by
TextureStructureManagement
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Sandy soils mostly have _____pores
Clay soils have macropores (between / inside) aggregates
Massive clays mostly have _____pores
macro-
micro-
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What effect does tillage have on porespace?
Increase it or decrease it?
Decrease it?
Why?Native soil
This is directly related toeffect of tillage on bulk density.Tillage increases density inthe long-term because of loss oforganic matter that results in lossof inter-aggregate porosity. Again,the effect is primarily on macro-porosity.
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Water Content
gravimetric water content
mass of water / mass of oven-dry soil
volumetric water content
volume of water / volume of soil
Know these two definitions. By the way,which one of these can you always measure?
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Note on air-dry moisture content
mair-dry soil = msoil solids + mwater
let mwater / msoil solids = gw
mair-dry soil = msoil solids (1 + gw )
The basis for most soil chemical data is dry soil solid mass (i.e., oven-dry), however, you can’t maintain soil in an oven-dry state unless it’s in a dessicatorand when you remove it to do something with it, it starts to immediately adsorbwater from the atmosphere. So, you correct to oven-dry moisture. Here, gwis gravimetric water content .
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What You Now Know AboutSoil Physical Properties
And With Such Amazing Ease
Color
Munsell chart and parametersWhat soil colors usually indicate
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Texture Definitions of separates How to use a textural triangle Basis and method of mechanical analysis Importance of texture to other soil properties
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Structure TypesEffects on aeration and water movementFormation and stability of surface structureManagement ideas for preserving
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Particle density DefinitionHow to measure it
Bulk density DefinitionHow to measure itInfluences of texture, structure and management on it
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Porosity How to calculate itInfluence of texture, structure and management on it
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Water content GravimetricVolumetricAir-dry soil contains adsorbed water and that’s a nasty little inconvenience