m
 
(22 intermediate revisions by the same user not shown)
Line 1: Line 1:
{{alert|This page is in development|alert-under-construction}}
 
 
 
Erodibility describes or is a measure of the inherent resistance of geologic materials (soils and rocks) to erosion. Highly erodible geologic materials are readily displaced and transported by water. This page provides basic information about soil erodibility.
 
Erodibility describes or is a measure of the inherent resistance of geologic materials (soils and rocks) to erosion. Highly erodible geologic materials are readily displaced and transported by water. This page provides basic information about soil erodibility.
  
 
==Types of soil erosion==
 
==Types of soil erosion==
[[File:Erodibility.png|300px|thumb|alt=image of soil erosion|<font size =3>Illustration of four types of soil erosion.</font size>]]
+
[[File:Erodibility.png|400px|thumb|alt=image of soil erosion|<font size =3>Illustration of four types of soil erosion.</font size>]]
  
There are four types of soil erosion.
+
There are four types of <span title="the wearing away of a field's topsoil by the natural physical forces of water and wind"> '''soil erosion'''</span>.
#Sheet erosion: the uniform removal of soil in thin layers by the forces of raindrops and overland flow. It can be a very effective erosive process because it can cover large areas of sloping land and go unnoticed for quite some time [https://milford.nserl.purdue.edu/weppdocs/overview/sheet.html National Soil Erosion Research Laboratory].
+
#Sheet erosion: the uniform removal of soil in thin layers by the forces of raindrops and overland flow. It can be a very effective erosive process because it can cover large areas of sloping land and go unnoticed for quite some time ([https://milford.nserl.purdue.edu/weppdocs/overview/sheet.html National Soil Erosion Research Laboratory]).
#Rill erosion:  the removal of soil by concentrated water running through little streamlets, or headcuts. Detachment in a rill occurs if the sediment in the flow is below the amount the load can transport and if the flow exceeds the soil's resistance to detachment [https://milford.nserl.purdue.edu/weppdocs/overview/sheet.html National Soil Erosion Research Laboratory].
+
#Rill erosion:  the removal of soil by concentrated water running through little streamlets, or headcuts. Detachment in a rill occurs if the sediment in the flow is below the amount the load can transport and if the flow exceeds the soil's resistance to detachment ([https://milford.nserl.purdue.edu/weppdocs/overview/sheet.html National Soil Erosion Research Laboratory]).
#Gully erosion: the removal of soil along drainage lines by surface water runoff. Once started, gullies will continue to move by headward erosion or by slumping of the side walls unless steps are taken to stabilise the disturbance [http://agriculture.vic.gov.au/agriculture/farm-management/soil-and-water/erosion/gully-erosion Agriculture Victoria].
+
#Gully erosion: the removal of soil along drainage lines by surface water runoff. Once started, gullies will continue to move by headward erosion or by slumping of the side walls unless steps are taken to stabilise the disturbance ([http://agriculture.vic.gov.au/agriculture/farm-management/soil-and-water/erosion/gully-erosion Agriculture Victoria]).
 
#Dispersive soils: dispersive soils are structurally unstable, which makes them vulnerable to the forms of erosion described above. Dispersive soils are typically clay soils with an <span title=" The exchangeable sodium percentage (ESP) is calculated as follows: ESP = Exchangeable {(Na)/(Ca + Mg + K + Na)} x 100"> '''exchangeable sodium percent'''</span> greater than 5%.
 
#Dispersive soils: dispersive soils are structurally unstable, which makes them vulnerable to the forms of erosion described above. Dispersive soils are typically clay soils with an <span title=" The exchangeable sodium percentage (ESP) is calculated as follows: ESP = Exchangeable {(Na)/(Ca + Mg + K + Na)} x 100"> '''exchangeable sodium percent'''</span> greater than 5%.
  
 
==Calculating soil loss - Universal Soil Loss Equation==
 
==Calculating soil loss - Universal Soil Loss Equation==
[[File:Erodibility table 2.png|400px|thumb|alt=table with soil erodibility|<font size=3>Soil erodibility index</font size>
+
[[File:Erodibility table 2.png|300px|thumb|alt=table with soil erodibility|<font size=3>Soil erodibility index</font size>]]
  
 
The Universal Soil Loss Equation (USLE) and it's update, the Revised Universal Soil Loss Equation (RUSLE) are used to predict sheet and rill erosion. These equations do not apply to gully erosion and dispersive soils. The annual soil loss, in tons per acre, is given by the following formula.
 
The Universal Soil Loss Equation (USLE) and it's update, the Revised Universal Soil Loss Equation (RUSLE) are used to predict sheet and rill erosion. These equations do not apply to gully erosion and dispersive soils. The annual soil loss, in tons per acre, is given by the following formula.
Line 26: Line 24:
 
*P = erosion control practice factor
 
*P = erosion control practice factor
  
RUSLE factors are observable in the field and fairly simple to derive. The R and K variables are generally out of the hands of the construction site operator. Slope (S) and slope length (L) can sometimes be managed or impacted during the design phase of project development. Two RUSLE variables which can be controlled at active construction sites – the cover and practices factors (i.e., variables C and P) – are the focus of the erosion prevention measures. Erosion prevention practices, which mostly include soil preparation, vegetation, and the application of a mulch, blanket, mat, or other cover on bare soil, are the easiest, cheapest, and most effective approach for addressing runoff from construction sites. Sediment control – settling soil particles from temporarily ponded runoff water or filtering it using silt fencing or other materials – is more difficult, more expensive, and requires much more maintenance.
+
RUSLE factors are observable in the field and fairly simple to derive. The R and K variables are generally out of the hands of the construction site operator. Slope (S) and slope length (L) can sometimes be managed or impacted during the design phase of project development. Two RUSLE variables which can be controlled at active construction sites – the cover and practices factors (i.e., variables C and P) – are the focus of the erosion prevention measures. <span title="practices designed to prevent or minimize erosion> [https://stormwater.pca.state.mn.us/index.php?title=Erosion_prevention_practices '''Erosion prevention''']</span> practices, which mostly include soil preparation, vegetation, and the application of a <span title="Mulch products are intended to reduce raindrop (splash) erosion, decrease sheet erosion, promote rain/snowmelt infiltration, increase soil moisture retention, regulate soil temperature, and in most cases, improve soil texture and increase organic matter. Mulch products include natural materials such as straw and other grasses, coconut fiber, and bark."> [https://stormwater.pca.state.mn.us/index.php?title=Erosion_prevention_practices_-_natural_and_synthetic_mulches '''mulch''']</span>, <span title="typically biodegradable, open-weave blankets that provide temporary cover and support for establishing vegetation on bare soil areas."> [https://stormwater.pca.state.mn.us/index.php?title=Erosion_prevention_practices_-_erosion_control_blankets_and_anchoring_devices '''blanket''']</span>, mat, or other cover on bare soil, are the easiest, cheapest, and most effective approach for addressing runoff from construction sites. <span title="practices designed to prevent or minimize loss of eroded soil at a site"> [https://stormwater.pca.state.mn.us/index.php?title=Sediment_control_practices '''Sediment control''']</span> – settling soil particles from temporarily ponded runoff water or filtering it using silt fencing or other materials – is more difficult, more expensive, and requires much more maintenance.
  
 
For more information on the USLE and RUSLE, see the following.
 
For more information on the USLE and RUSLE, see the following.
 
*[https://www.ars.usda.gov/ARSUserFiles/50201000/USLEDatabase/AH_537.pdf Predicting Rainfall Erosion Losses]
 
*[https://www.ars.usda.gov/ARSUserFiles/50201000/USLEDatabase/AH_537.pdf Predicting Rainfall Erosion Losses]
 
*[https://www.ars.usda.gov/midwest-area/west-lafayette-in/national-soil-erosion-research/docs/usle-database/research/ About the Universal Soil Loss Equation] - National Soil Erosion Research: West Lafayette, IN
 
*[https://www.ars.usda.gov/midwest-area/west-lafayette-in/national-soil-erosion-research/docs/usle-database/research/ About the Universal Soil Loss Equation] - National Soil Erosion Research: West Lafayette, IN
*[https://www.nrcs.usda.gov/wps/PA_NRCSConsumption/download?cid=stelprdb1247540&ext=pdf Revised Universal Soil Loss Equation - Version 2]
+
*[https://fargo.nserl.purdue.edu/rusle2_dataweb/RUSLE2_Index.htm Revised Universal Soil Loss Equation - Version 2]
 
*[https://www.sciencedirect.com/topics/earth-and-planetary-sciences/revised-universal-soil-loss-equation Revised Universal Soil Loss Equation]
 
*[https://www.sciencedirect.com/topics/earth-and-planetary-sciences/revised-universal-soil-loss-equation Revised Universal Soil Loss Equation]
 +
 +
==Soil erodibilty==
 +
Soil erodibility ( K ) is the intrinsic susceptibility of a soil to erosion by runoff and raindrop impact. In general, the following affect K. See adjacent table.
 +
*Increasing amounts of soil <span title="carbon-based compounds, originally derived from living organisms"> '''organic matter'''</span> result in decreasing values of K
 +
*[https://stormwater.pca.state.mn.us/index.php?title=Soil_texture_and_structure Soil type] effect on K: <span title="Fine-grained soil particles with a diameter between 0.002 mm and 0.075 mm (ASTM basis)."> '''silt'''</span> > silt loam = fine sand > <span title="a soil with roughly equal proportions of clay, silt, and sand"> '''loam'''</span> > clay loam > <span title="fine-grained soil particles with a particle  diameter less than 0.002 mm"> '''clay'''</span> > coarse sand. Note that wet clay soils that have expanded have increased risk.
 +
*Coarse sand particles are too large to transport
 +
*Clays are cohesive with good soil structure and it is difficult to dislodge soil particles
 +
*Silts and fine sands are not cohesive and are easily transported
 +
*Texture is the principal factor affecting Kfact, but structure, organic matter, and permeability also contribute
 +
*The soil erodibility factor ranges in value from 0.02 to 0.69
 +
 +
==Tools for assessing soil erodibility at construction sites==
 +
[[File:Soil structure 2.jpg|300px|thumb|alt=image soil structure|<font size=3>Types of soil structure</font size>]]
 +
 +
*Use [https://websoilsurvey.nrcs.usda.gov/app/ NRCS Soil mapping tool] in advance of site visit.
 +
*Determine the most erodible soil at a site. Soils with silt and fine or very fine sand are highly erodible. [https://www.youtube.com/watch?v=fufeaLBLGlk See this Youtube].
 +
*Identify the <span title="Soil structure describes the arrangement of the solid parts of the soil and of the pore space located between them. It is determined by how individual soil granules clump, bind together, and aggregate, resulting in the arrangement of soil pores between them."> '''soil structure'''</span>. General erodibility is Platy > Massive > Blocky > Aggregated. You likely will not encounter columnar structure. Granular structure varies. Fine and very <span title="soil with a diameter of 0.063 mm to 0.2 mm"> '''fine sands'''</span> are granular but highly erosive, while medium to coarse sands are less erosive. Certain practices at a site may change the structure, especially soils with appreciable amounts of clay. See adjacent image.
 +
*Examine the soil for organic matter content. Organic matter imparts a black color to soil. Organic matter binds soil and reduces the risk of erosion.
 +
*If subsoils are exposed, this might increase erodibility since subsoils generally lack organic matter and disturbance may destroy the soil structure.
 +
*Determine if rills and gullies are starting to form. These can lead to significant soil losses.
 +
 +
==Suggested references and links==
 +
*[https://stormwater.pca.state.mn.us/index.php?title=General_principles_for_erosion_prevention_and_sediment_control_at_construction_sites_in_Minnesota Soil Erodibility On Construction Areas]
 +
*[https://dnr.wi.gov/topic/stormWater/documents/constructionSiteSoilLossSedimentDischarge.pdf Wisconsin Construction Site Soil Loss and Sediment Discharge Calculation Guidance]
 +
*[https://stormwater.pca.state.mn.us/index.php?title=Soils_and_geology Soil surveys and other resources]
 +
*[https://dec.vermont.gov/watershed/stormwater/permit-information-applications-fees/stormwater-construction-discharge-permits Vermont Soil Erodibility Evaluation for General Permit 3-9020 Stormwater Runoff From Construction Activities]
 +
*[https://mepas.pnnl.gov/mepas/formulations/source_term/5_0/5_32/5_32.html#targetText=The%20soil%20erodibility%20factor%20(K,transport%20by%20rainfall%20and%20runoff. Soil erodibility factor]
 +
*[[General principles for erosion prevention and sediment control at construction sites in Minnesota]]
 +
*[[Erosion prevention practices]]
 +
*[[Sediment control practices]]
 +
 +
<noinclude>
 +
 +
==Related links==
 +
*Soil concepts
 +
**[[Soil classification]]
 +
**[[Soil physical properties and processes]]
 +
**[[Soil erodibility]]
 +
**[[Soil infiltration]]
 +
*Soil properties
 +
**[[Soil water storage properties]]
 +
**[[Specific yields for geologic materials]]
 +
**[[Design infiltration rates]]
 +
*Determining soil infiltration
 +
**[https://stormwater.pca.state.mn.us/index.php?title=Determining_soil_infiltration_rates Determining soil infiltration rates]
 +
**[[Understanding and interpreting soils and soil boring reports for infiltration BMPs]]
 +
*Soil management
 +
**[[Alleviating compaction from construction activities]]
 +
**[[Erosion prevention practices]]
 +
**[[Sediment control practices]]
 +
 +
[[Category:Level 2 - Technical and specific topic information/soils and media]]
 +
</noinclude>

Latest revision as of 17:53, 30 January 2023

Erodibility describes or is a measure of the inherent resistance of geologic materials (soils and rocks) to erosion. Highly erodible geologic materials are readily displaced and transported by water. This page provides basic information about soil erodibility.

Types of soil erosion

image of soil erosion
Illustration of four types of soil erosion.

There are four types of soil erosion.

  1. Sheet erosion: the uniform removal of soil in thin layers by the forces of raindrops and overland flow. It can be a very effective erosive process because it can cover large areas of sloping land and go unnoticed for quite some time (National Soil Erosion Research Laboratory).
  2. Rill erosion: the removal of soil by concentrated water running through little streamlets, or headcuts. Detachment in a rill occurs if the sediment in the flow is below the amount the load can transport and if the flow exceeds the soil's resistance to detachment (National Soil Erosion Research Laboratory).
  3. Gully erosion: the removal of soil along drainage lines by surface water runoff. Once started, gullies will continue to move by headward erosion or by slumping of the side walls unless steps are taken to stabilise the disturbance (Agriculture Victoria).
  4. Dispersive soils: dispersive soils are structurally unstable, which makes them vulnerable to the forms of erosion described above. Dispersive soils are typically clay soils with an exchangeable sodium percent greater than 5%.

Calculating soil loss - Universal Soil Loss Equation

table with soil erodibility
Soil erodibility index

The Universal Soil Loss Equation (USLE) and it's update, the Revised Universal Soil Loss Equation (RUSLE) are used to predict sheet and rill erosion. These equations do not apply to gully erosion and dispersive soils. The annual soil loss, in tons per acre, is given by the following formula.

Annual soil loss = R * K * LS * C * P

where

  • R = rainfall erosivity factor
  • K = soil erodibility factor
  • LS = slope length and gradient factor
  • C = cover management factor
  • P = erosion control practice factor

RUSLE factors are observable in the field and fairly simple to derive. The R and K variables are generally out of the hands of the construction site operator. Slope (S) and slope length (L) can sometimes be managed or impacted during the design phase of project development. Two RUSLE variables which can be controlled at active construction sites – the cover and practices factors (i.e., variables C and P) – are the focus of the erosion prevention measures. Erosion prevention practices, which mostly include soil preparation, vegetation, and the application of a mulch, blanket, mat, or other cover on bare soil, are the easiest, cheapest, and most effective approach for addressing runoff from construction sites. Sediment control – settling soil particles from temporarily ponded runoff water or filtering it using silt fencing or other materials – is more difficult, more expensive, and requires much more maintenance.

For more information on the USLE and RUSLE, see the following.

Soil erodibilty

Soil erodibility ( K ) is the intrinsic susceptibility of a soil to erosion by runoff and raindrop impact. In general, the following affect K. See adjacent table.

  • Increasing amounts of soil organic matter result in decreasing values of K
  • Soil type effect on K: silt > silt loam = fine sand > loam > clay loam > clay > coarse sand. Note that wet clay soils that have expanded have increased risk.
  • Coarse sand particles are too large to transport
  • Clays are cohesive with good soil structure and it is difficult to dislodge soil particles
  • Silts and fine sands are not cohesive and are easily transported
  • Texture is the principal factor affecting Kfact, but structure, organic matter, and permeability also contribute
  • The soil erodibility factor ranges in value from 0.02 to 0.69

Tools for assessing soil erodibility at construction sites

image soil structure
Types of soil structure
  • Use NRCS Soil mapping tool in advance of site visit.
  • Determine the most erodible soil at a site. Soils with silt and fine or very fine sand are highly erodible. See this Youtube.
  • Identify the soil structure. General erodibility is Platy > Massive > Blocky > Aggregated. You likely will not encounter columnar structure. Granular structure varies. Fine and very fine sands are granular but highly erosive, while medium to coarse sands are less erosive. Certain practices at a site may change the structure, especially soils with appreciable amounts of clay. See adjacent image.
  • Examine the soil for organic matter content. Organic matter imparts a black color to soil. Organic matter binds soil and reduces the risk of erosion.
  • If subsoils are exposed, this might increase erodibility since subsoils generally lack organic matter and disturbance may destroy the soil structure.
  • Determine if rills and gullies are starting to form. These can lead to significant soil losses.

Suggested references and links


Related links

This page was last edited on 30 January 2023, at 17:53.