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'''Management'''
 
'''Management'''
 
Organic matter (e.g. compost) can be added to a soil to increase water holding capacity.
 
Organic matter (e.g. compost) can be added to a soil to increase water holding capacity.
 +
 +
'''Recommended reading'''
 +
*[https://www.nrcs.usda.gov/Internet/FSE_DOCUMENTS/nrcs142p2_053288.pdf Soil Quality Indicators - Available Water Capacity] - USDA-NRCS
 +
*[http://soilquality.org/indicators/available_water_capacity.html Available Water Capacity] - Soil Quality for Environmental Health
 +
*[https://cpb-us-e1.wpmucdn.com/blogs.cornell.edu/dist/f/5772/files/2016/12/05_AWC_Fact_Sheet_040517-1gxdfuo.pdf Available Water Capacity] - Cornell University
 +
*[http://soilquality.org.au/factsheets/water-availability Fact sheets - water availability] - Healthy Soils for Sustainable Farms
 +
*[https://soilhealthnexus.org/resources/soil-properties/soil-physical-properties/available-water-capacity/ Available Water Capacity - What is Available Water Capacity?] - Soil Health Nexus
 +
*[http://www.fao.org/3/r4082e/r4082e03.htm Soil and water] - FAO
  
 
===Organic matter and organic carbon===
 
===Organic matter and organic carbon===

Revision as of 18:53, 29 June 2021

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Indicators for determining soil health
Indicator Function Type of indicator Test Management strategies
Compaction/bulk density H/E P FL Amend with organic matter; tillage
Water stable aggregates P
Infiltration H P F Amend soil with organic matter to increase (clayey soils) or decrease (sandy soils) infiltration rates
Soil structure H P F Tillage; amend with organic matter
Available water capacity H P Amend soil
Nutrient status N C Amend with organic matter or fertilize
pH N C Add lime for acidic soils, sulfur compound for basic soils
Soil contamination C Remediate or avoid contaminated areas if feasible
Soil electrical conductivity C
Organic matter and organic carbon N C Add organic matter
Soil respiration B B
Soil enzymes B B
Biotic assessment (diversity) B B
Plant roots B B
  • 1 B=biologic function; N=nutrient cycling function; H=hydrologic function; E=erosion control function
  • 2 P=physical; C=chemical; B=biologic
  • 3 F=field test; L=lab test; FL=field and lab test; O=office evaluation; () indicates test can be done but is not recommended (e.g. F(L) means test can be done in lab but field is recommended
  • 4 management strategies focus on the primary function but are generally applicable to all functions

Soil health is an assessment of how well soil performs all of its functions now and how those functions are being preserved for future use. The assessment of soil health depends on the desired functions of the soil. In agricultural applications, for example, soil health is determined by assessing properties that affect plant crop growth, such nutrient status, pH, and bulk density.

For stormwater applications, soil health can be assessed for the following functions.

  • Ability to support biologic function, including plant growth, soil biota, and species diversity (B)
  • Ability to support nutrient cycling, pollutant attenuation (N)
  • Ability to support hydraulic/hydrologic function (H)
  • Ability to minimize erosion (E)

Assessments of soil health are typically done by using indicators. Indicators are measurable properties of soil or plants that provide clues about how well the soil can function. Indicators can be physical, chemical, and biological properties or processes. The adjacent table illustrates which indicators are useful in evaluating the four functions identified above. This page provides a discussion for several soil health indicators and links to summary sheets for each indicator.

Links to individual indicator sheets

Discussion of soil indicators

Soil compaction (bulk density)

curve showing relationship of root penetration and penetration resistance
Curve showing relationship of root penetration and penetration resistance. Source: Penn State University Extension.

Importance: Soil compaction results from repeated traffic, generally from machinery, or repeated tillage at the same depth, which results in a compacted layer at the tillage depth. Compaction inhibits infiltration, gas and water movement, may impede root growth, disrupts habitat for soil biota, and affects nutrient cycling. See Soil physical properties and processes for a discussion of bulk density.

Assessment There are multiple methods for measuring bulk density and compaction (resistance). See methods for measuring and methods for measuring compaction. Recommended methods of assessment include the following.

  • Penetrometer - a penetrometer is a portable, easy to use tool. The penetrometer is pushed into a soil and a gauge shows the resistance. Readings greater than 300 psi indicate conditions restrictive to root growth. If more than 50 percent of readings from a field exceed 300 psi, compaction is considered moderate; severe if more than 75 percent of readings exceed 300 psi. Typical cost of a penetrometer is about $200.
  • Bulk density - bulk density is a relatively easy to perform measurement but requires determining the water (moisture) content of the soil. Relationships of bulk density to root growth are shown in the adjacent table.

Management If a soil is compacted based on penetrometer readings, or if bulk density for a particular soil type exceed the value in the table, the soil should be amended. Addition of organic matter is recommended for reducing compaction and bulk density, with tillage as another option. For information on soil compaction and alleviating compaction, link here.

General relationship of soil bulk density to root growth based on soil texture
Link to this table

Soil texture Ideal bulk densities (g/cm3) Bulk densities that may affect plantgrowth (g/cm3) Bulk densities that restrict root growth (g/cm3)
sands, loamy sands <1.60 1.69 >1.80
sandy loams, loams <1.40 1.63 >1.80
sandy clay loams, loams, clay loams <1.40 1.60 >1.75
silts, silt loams <1.30 1.60 >1.75
silt loams, silty clay loams <1.40 1.55 >1.65
sandy clays, silty clays, clay loams with 35-45% clay <1.10 1.49 >1.58
clays (>45% clay) <1.10 1.39 >1.47


Water stable aggregates

Importance: Stable soil aggregates, in the presence of water, is important for water and air transport, root growth, habitat for soil biota, minimizing soil erodibility, protecting soil organic matter, and nutrient cycling.

Assessment: Methods for assessing aggregate stability are somewhat qualitative and different methods do not correlate well. The method selected should simulate field processes likely to affect aggregate stability (e.g. rainfall impact, ponded (flooded) conditions, tillage). For more information about aggregate stability tests, link here.

  • Sieve or strainer method: Aggregate stability is assessed by moving a sieve with aggregates up and down in a bucket of water. This method may represent stability under rainfall. Soil stability is evaluated by measuring the mass of soil remaining, as a percent of initial soil mass, on the sieve after a specified number of dipping cycles (e.g. 5 cycles). Soils with high aggregate stability will typically retain 50 percent or more of the initial soil mass.
  • Slake test: Dried aggregates are placed into a container filled with water and aggregates are assessed after specified times (e.g. 20 minute intervals). This method may represent stability under flooded (water immersed) conditions. This is a qualitative test.
  • Vibration methods: An ultrasonic probe immersed in water containing soil aggregates vibrates at different vibration amplitudes. This method may represent stability under tillage conditions. Vibration methods relate stability to the energy needed to break down aggregates.

Management Aggregate stability can be improved through a combination of reduced tillage, addition of organic matter (e.g. compost), increasing the amount of crop residues in the soil, and providing soil cover.

Infiltration

Importance: affects water storage and transport of solutes and pollutants; adequate infiltration is required for certain stormwater practices.

Assessment: Direct measurement is recommended (e.g. permeameter, double ring infiltrometer)

  • Permeameter: An Initial soil moisture content measurement is determined, then the permeameter cylinder is filled with water. As the permeameter drains, measurements of stage and time are taken. Then, a final measurement of soil moisture content is aggregated into a post-processing spreadsheet, where saturated hydraulic conductivity is calculated.
  • Double ring infiltrometer: Two rings (e.g. 20 and 30 cm diameter) are driven into the soil. A constant water level is maintained in the outer ring. The water level in the inner ring may be maintained at a constant level or a falling level. Saturated conductivity is achieved when the rate of infiltration in the inner ring reaches a constant.
  • Textural analysis: Soil borings or pits are used to determine soil texture.

Multiple measurements are highly recommended since the infiltration rate can vary by orders of magnitude over very short distances, even within a single soil series. The adjacent table can be used to assess suitability of a soil for stormwater infiltration bmps, with A and B soils suitable for infiltration and C soils suitable for partial infiltration.

For more information, see Determining soil infiltration rates. Links to videos demonstrating direct measurements can be found here.

Management If infiltration is limited due to compaction, then amending the soil with organic matter or tillage are recommended. For soils with naturally low (e.g. clay) or high (sand) infiltration rates, amend with organic matter (e.g. compost). Long-term infiltration can be enhanced with deep-rooted vegetation and enhancing biologic activity, both which promote macroporosity.


Caution: The table for design infiltration rates has been modified. Field testing is recommended for gravelly soils (HSG A; GW and GP soils; gravel and sandy gravel soils). If field-measured soil infiltration rates exceed 8.3 inches per hour, the Construction Stormwater permit requires the soils be amended. Guidance on amending these soils can be found here.

Design infiltration rates, in inches per hour, for A, B, C, and D soil groups. Corresponding USDA soil classification and Unified soil Classifications are included. Note that A and B soils have two infiltration rates that are a function of soil texture.*
The values shown in this table are for uncompacted soils. This table can be used as a guide to determine if a soil is compacted. For information on alleviating compacted soils, link here. If a soil is compacted, reduce the soil infiltration rate by one level (e.g. for a compacted B(SM) use the infiltration rate for a B(MH) soil).

Link to this table

Hydrologic soil group Infiltration rate (inches/hour) Infiltration rate (centimeters/hour) Soil textures Corresponding Unified Soil ClassificationSuperscript text
A
Although a value of 1.63 inches per hour (4.14 centimeters per hour) may be used, it is Highly recommended that you conduct field infiltration tests or amend soils.b See Guidance for amending soils with rapid or high infiltration rates and Determining soil infiltration rates.

gravel
sandy gravel

GW - Well-graded gravels, fine to coarse gravel
GP - Poorly graded gravel
1.63a 4.14

silty gravels
gravelly sands
sand

GM - Silty gravel
SW - Well-graded sand, fine to coarse sand

0.8 2.03

sand
loamy sand
sandy loam

SP - Poorly graded sand

B
0.45 1.14 silty sands SM - Silty sand
0.3 0.76 loam, silt loam MH - Elastic silt
C
0.2 0.51 Sandy clay loam, silts ML - Silt
D
0.06 0.15

clay loam
silty clay loam
sandy clay
silty clay
clay

GC - Clayey gravel
SC - Clayey sand
CL - Lean clay
OL - Organic silt
CH - Fat clay

OH - Organic clay, organic silt

1For Unified Soil Classification, we show the basic text for each soil type. For more detailed descriptions, see the following links: The Unified Soil Classification System, CALIFORNIA DEPARTMENT OF TRANSPORTATION (CALTRANS) UNIFIED SOIL CLASSIFICATION SYSTEM

  • NOTE that this table has been updated from Version 2.X of the Minnesota Stormwater Manual. The higher infiltration rate for B soils was decreased from 0.6 inches per hour to 0.45 inches per hour and a value of 0.06 is used for D soils (instead of < 0.2 in/hr).

Source: Thirty guidance manuals and many other stormwater references were reviewed to compile recommended infiltration rates. All of these sources use the following studies as the basis for their recommended infiltration rates: (1) Rawls, Brakensiek and Saxton (1982); (2) Rawls, Gimenez and Grossman (1998); (3) Bouwer and Rice (1984); and (4) Urban Hydrology for Small Watersheds (NRCS). SWWD, 2005, provides field documented data that supports the proposed infiltration rates. (view reference list)
aThis rate is consistent with the infiltration rate provided for the lower end of the Hydrologic Soil Group A soils in the Stormwater post-construction technical standards, Wisconsin Department of Natural Resources Conservation Practice Standards.
bThe infiltration rates in this table are recommended values for sizing stormwater practices based on information collected from soil borings or pits. A group of technical experts developed the table for the original Minnesota Stormwater Manual in 2005. Additional technical review resulted in an update to the table in 2011. Over the past 5 to 7 years, several government agencies revised or developed guidance for designing infiltration practices. Several states now require or strongly recommend field infiltration tests. Examples include North Carolina, New York, Georgia, and the City of Philadelphia. The states of Washington and Maine strongly recommend field testing for infiltration rates, but both states allow grain size analyses in the determination of infiltration rates. The Minnesota Stormwater Manual strongly recommends field testing for infiltration rate, but allows information from soil borings or pits to be used in determining infiltration rate. A literature review suggests the values in the design infiltration rate table are not appropriate for soils with very high infiltration rates. This includes gravels, sandy gravels, and uniformly graded sands. Infiltration rates for these geologic materials are higher than indicated in the table.
References: Clapp, R. B., and George M. Hornberger. 1978. Empirical equations for some soil hydraulic properties. Water Resources Research. 14:4:601–604; Moynihan, K., and Vasconcelos, J. 2014. SWMM Modeling of a Rural Watershed in the Lower Coastal Plains of the United States. Journal of Water Management Modeling. C372; Rawls, W.J., D. Gimenez, and R. Grossman. 1998. Use of soil texture, bulk density and slope of the water retention curve to predict saturated hydraulic conductivity Transactions of the ASAE. VOL. 41(4): 983-988; Saxton, K.E., and W. J. Rawls. 2005. Soil Water Characteristic Estimates by Texture and Organic Matter for Hydrologic Solutions. Soil Science Society of America Journal. 70:5:1569-1578.



Recommended number of soil borings, pits or permeameter tests for bioretention design. Designers select one of these methods.
Link to this table

Surface area of stormwater control measure (BMP)(ft2) Borings Pits Permeameter tests
< 1000 1 1 5
1000 to 5000 2 2 10
5000 to 10000 3 3 15
>10000 41 41 202

1an additional soil boring or pit should be completed for each additional 2,500 ft2 above 12,500 ft2
2an additional five permeameter tests should be completed for each additional 5,000 ft2 above 15,000 ft2


Soil structure, crusting, and macroporosity

Importance: Soil functions related to soil structure include sustaining biological productivity, regulating and partitioning water and solute flow, cycling and storing nutrients, water and air exchange, plant root development, and habitat for soil organisms. Soil crusts can impede infiltration and water and air exchange and transport. Macropores can enhance air and water transport, but may result in short-circuiting (bypass) of water and solutes, including pollutants, to deeper depths within the soil profile.

Assessment:

  • Soil structure is a field qualitative study to assess the dominant type of soil ped. The assessment should be performed by a professional soil scientist or someone experienced in evaluating soil structure. The USDA-NRCS publication Field Book for Describing and Sampling Soils, version 3.0 (pages 2-52 to 2-61), or the USDA-NRCS Soil Field Test Guide (pages 24-26 and 76-77) provide descriptions, tables, and schematics that can be used to assess soil structure. Non-granular soils exhibiting weak platy or columnar structure indicate poor soil structure, versus strong blocky structures.
  • Surface soil crusts are qualitatively evaluated in the field. The assessment should be performed by a professional soil scientist or someone experienced in evaluating soils. The USDA-NRCS publication Field Book for Describing and Sampling Soils, version 3.0 (pages 2-77 to 2-79) provide descriptions, tables, and schematics that can be used to assess surface crusting. Surface crusts are often tested for their stability, similar to tests of aggregate stability. Crusts that are stable indicate conditions likely to restrict infiltration and water and air exchange.
  • Macroporosity: Soil macroporosity can be quantified in the field and expressed as a percent of surface area or soil volume. Typical methods include measuring the number and area of soil macropores (pores > 75 microns in diameter) in different soil layers, which can then be converted to a soil volume or a percent of soil volume. Examples of field techniques are described in several papers ([1], [2], [3], [4], [5]). Desirable values for macroporosity are not well defined in the literature, though a value of 10 percent or greater is cited in the literature ([6], [7]). Higher values are more desirable in clay soils or soils with poor structure, where water and air transport can be restricted.

Management: Amending soil with organic matter (e.g. compost) is recommended for soils with poor structure. Organic matter may also stimulate biologic activity that results in increased macroporosity. Tillage can alleviate surface crusting and improve soil structure in the tillage layer, but will disrupt macropores. Utilizing deep rooted vegetation increases macroporosity over time.

Available water capacity

water holding capacity for different soils
General relationship between soil moisture and texture. Ohio Agronomy Guide, 14th edition, Bulletin 472-05.

Importance: Available water capacity is the amount of water available between a soil's field capacity and wilting point, or the maximum plant available water that a soil can hold. For areas subject to periodic dry spells or regions where seasonal evapotranspiration can exceed rainfall, a soil's ability to store water is critical to plant growth. Loam soils have the highest water holding capacity.

Assessment To calculate water holding capacity, a soil's water content at field capacity and wilting point must be determined. These are typically determined in the lab, though field measurement is possible using methods such as near-infrared reflectance. Field collection of undisturbed cores is preferred, but soils are sometimes repacked in the lab. Measurement at field capacity involves saturating a soil column and then allowing it to drain for 48 hours. A pressure membrane is required to determine the soil wilting point. Water contents are measured after drainage (field capacity) and at -15 bars pressure (pressure plate), with the difference being water holding capacity.

Management Organic matter (e.g. compost) can be added to a soil to increase water holding capacity.

Recommended reading

Organic matter and organic carbon

Importance: Soil organic matter (SOM) is the organic matter component of soil, consisting of plant and animal material, including cells, tissues, and substances produced or synthesized by soil organisms. Organic matter exists at varying levels of decomposition. Organic carbon is a component of soil organic matter, making up about 60 percent of soil organic matter. Organic matter provides numerous benefits to soil function, including improvement of soil structure, aggregation, water retention, soil biodiversity, absorption and retention of pollutants, buffering capacity, and the cycling and storage of plant nutrients. Soil organic carbon is the primary food (energy) source for soil microbes.

Assessment: Soil organic matter and carbon are generally determined in the laboratory. Because organic matter varies with depth, it may be important to determine soil organic matter at discrete depths. Preferred ranges for soil organic matter are 4-8 percent by weight, with 2 percent being a recommended lower limit. Common methods of analysis are provided below.

Management: Although soil organic matter can be increased by simply adding organic material to a soil, the choice of material is important since materials vary in their rate of decomposition, nutritional value, effects on pH, and other factors. Below are some commonly used organic amendments.

  • Compost: Aged compost is recommended. Compost has moderate hydrologic, physical, and nutrient benefit.
  • Manure: Manure must be composted prior to use to reduce pathogen and ammonia concerns. Composted manure has good nutrient benefit and low to moderate hydrologic and physical benefit.
  • Biosolids: Class A biosolids have been treated to reduce concerns with pathogens. These biosolids provide moderate hydrologic and nutrient benefits. Heavy metals are a concern.
  • Wood products: These provide hydrologic and structural benefits to soil but can tie up nitrogen. To avoid nutrient deficiency compost these before using and consider adding a nitrogen fertilizer.

For more information, see [8], [9], [10], and [11].

  • Peat: Peat has very good hydrologic benefits. It has limited nutrient benefit, can acidify soils. Most importantly, it is considered a nonrenewable resource.

Further reading

Soil electrical conductivity

Biotic assessment (diversity)

Soil Enzymes

Soil Respiration

Plant roots

Nutrient status (fertility)

Information: An excellent resource applicable to a wide variety of vegetated stormwater BMPs, including bioretention BMPs, is Plants for stormwater design by Shaw and Schmidt (2003).

Evaluating the nutrient status of a soil focuses on determining if a soil is deficient in one or more macronutrients (nitrogen (N), potassium (K), sulfur (S), calcium (Ca), and magnesium (Mg)) or micronutrients (boron (B), zinc (Zn), manganese (Mn), iron (Fe), copper (Cu), molybdenum (Mo), and chloride (Cl)). Additional parameters may include organic matter, pH, soluble salts, and cation exchange capacity.

Importance: Soil nutrients are essential for plant growth and soil biotic processes essential to plant growth. Soil pH of 5-8 is typically acceptable for plant growth and biotic processes, but outside this range metals may be mobilized and other biologic processes adversely affected. Cation exchange capacity is a measure of a soils ability to retain nutrients that can be used by soil biota, including plants. Soluble salts may build up in soils after excess fertilizer applications, leading to drought stress in plants. Soil organic matter serves many functions in soil, including supplying nutrients, improving water storage and transport, improving soil structure and aggregation, and providing habitat for soil biota.

Assessment: Most Minnesota soils with organic matter are not deficient in soil micronutrients, Ca, Mg, or S. Thus, testing for organic matter, pH, N, P, and K is generally sufficient. Organic matter is analyzed in a laboratory, while the other parameters can be tested in the field. For purposes of assessing soil nutrient status or fertility, field tests are generally adequate. Lab tests provide more accurate results and some labs offer standard soil tests that assess soil fertility. Links to videos discussing and demonstrating field testing are provided below.

  • Organic matter content: Generally determined in the lab. See here for methods. A field method is described here. Organic matter concentrations between 4 and 6 percent, by weight, are ideal, with 2 to 8 percent being good. Soils with less than 2 percent organic matter may require fertilizer additions or organic amendments. Excess organic matter can lead to leaching of nutrients and in some cases, soil acidification.
  • pH: test strips or field meters are adequate. For lab analysis, link here. Soil pH should be 5-8, with a pH of about 6.5 optimum for most plants.

Video links for field testing

Further reading

pH

Importance: Soil pH generally refers to the degree of soil acidity or alkalinity. Soil pH affects many soil processes, such as nutrient cycling, mobility of metals, and biological activity. In acid soils, calcium, magnesium, nitrate-nitrogen, phosphorus, boron, and molybdenum are deficient, while aluminum and manganese may occur at levels toxic to some plants. Phosphorus, iron, copper, zinc, and boron may be deficient in alkaline soils.

Assessment: While pH may be measured in a laboratory, field tests are simple and reasonably accurate. Field tests are therefore recommended. Field tests include the use of test strips or portable meters. If measured with a meter, ensure the meter is properly calibrated. Optimal pH for most plants and soil biota is 5.5-8.0, with 6.0-7.5 generally preferred. Soil plants (e.g. roses, azaleas) prefer acidic soils. If selecting vegetation, ensure the soil pH is appropriate.

Management: Liming is typically recommended for increasing soil pH. Ash or some organic residues rich in basic cations may also be used to raise soil pH. Soil pH can be lowered by adding organic matter (e.g. compost, peat, acid moss, pine needles, sawdust) or applying ammonium based fertilizers, urea, or sulfur/ferrous sulfate. Increasing organic matter increases buffering capacity, which helps prevent rapid fluctuations in soil pH.

Recommended reading

Soil contamination

Importance: Soils may contain concentrations of certain chemicals that are toxic to plants. Pollutants of greatest concern include metals (copper, lead, cadmium, nickel, zinc), sodium and chloride from road salt application, pesticides, and some hydrocarbons (e.g. oil, PAHs). Sites with known contamination may contain other pollutants, such as arsenic, but these soils are generally not suitable for stormwater applications without remediation.

Assessment: Risk assessments for metals concentrations in soil are generally based on human exposure, and there is limited information on toxic concentrations for different plants. Nevertheless, most urban soils do not contain chemicals at concentrations which restrict plant growth, although concentrations of these chemicals are typically greater than natural background ([12], [file:///C:/Users/franc/Downloads/environments-07-00098-v2.pdf], [13], [14], [15], [16], [17]). Chemical sampling is expensive, particularly for organic contaminants. An assessment of soil contamination should therefore begin with a site investigation to identify the presence of contaminant sources or historical activities that may have resulted in soil contamination.

  • Site visit: Conduct a site visit and determine if any of the following exist at the site - soil stockpiles, tanks or drums, odor(s), visual staining of soils, dead or dying vegetation, and debris that may be a source of contaminants.
  • Site review: Conduct a site review consisting of a search for nearby contaminated sites, site historical search to identify past uses, and review of historical aerial photos. Link here for more information and sources.
  • Assessment: If a site visit or assessment indicate potential contamination at a site, sampling may be warranted.

Regardless of the results for a site visit and site review, soil sampling is warranted for certain land use settings. The adjacent table provides a summary of potential pollutant concerns for specific land uses. If sampling is warranted, use appropriate sampling and test methods, described on this page.

Pollutants of Concern from Operations (adapted from CWP, 2005).
Link to this table.

Pollutant of concern Vehicle operations Waste management Site maintenance practices Outdoor materials Landscaping
Nutrients X X X
Pesticides X X
Solvents X X
Fuels X
Oil and grease X X
Toxic chemicals X X
Sediment X X X X
Road salt X X
Bacteria X X
Trace metals X X
Hydrocarbons X X


Soil health - additional reading