Compost is the product resulting from the controlled biological decomposition of organic materials that has been sanitized through the generation of heat and stabilized to the point that it is beneficial to plant growth. It is an organic matter resource that has the unique ability to improve the chemical, physical, and biological characteristics of soil.
Healthy, undisturbed soils provide important stormwater management functions including efficient water infiltration and storage, adsorption of excess nutrients, filtration of sediments, biological decomposition of pollutants, and moderation of peak stream flows and temperatures. In addition, healthy soils support vigorous plant growth that intercepts rainfall, returning much of it to the sky through evaporation and transpiration. Common development practices include removal of topsoil during grading and clearing, compaction of remaining soil, and planting into unimproved soil or shallow depths of poor quality imported topsoil. These conditions typically produce unhealthy plants that require excessive water, fertilizers and pesticides, further contaminating runoff.
To maintain the natural soil qualities, impacts to undisturbed soils should be avoided and minimized during the construction process. When impacts are unavoidable and soils have been compacted or otherwise disturbed, compost can be used as an amendment to regain some of the characteristics of undisturbed soils.
Figure 1 shows the effect that compaction of soils has on infiltration of water into sandy and clay soils. Uncompacted sandy soils will infiltrate up to 12 inches of water per hour. When compacted, the infiltration rate decreases to 1 inch or less per hour or a 90% reduction in the infiltration of water. Uncompacted clay soils are able to infiltrate up to 9 in per hour. However, when compacted, the infiltration rate drops to less than a ½ inch per hour or a 95% reduction in the infiltration of water. This illustrates how compacted soils contribute a significantly greater volume of runoff to the storm water system. Later discussion shows how compost can help to off-set the effect of compaction.
Establishing soil quality and depth regains greater stormwater function in the post development landscape, provides increased treatment of pollutants and sediments that result from development and habitation, and minimizes the need for some landscaping chemicals, thus reducing pollution through prevention. Establishing a minimum soil quality and depth is not the same as preservation of naturally occurring soil and vegetation. However, establishing a minimum soil quality and depth will provide improved onsite management of stormwater flow and water quality.
Compost can be used as a soil amendment to:
Guide to developing a soil management plan
Step 1 - Determine soil conditions
Step 2: Develop site and grading plans, which:
Step 3 – Develop soil management plan that determines:
Step 4: Identify available material source
Step 5: Select amendment options & application
Step 6: Calculate application volumes
Step 7: Specify as-built testing procedures
When amending disturbed soils with compost, it is important to use a compost product that fits the specific situation. In Minnesota, compost is made from a variety of feed-stocks, including yard and leaf debris, residential or commercial food residuals, and animal manure. Each type of feedstock produces a slightly different compost. Examples would be, a yard and leaf compost is low in nutrients (N-P-K) and the particle size is generally a little more coarse than a manure compost which is higher in N-P-K and has a finer, more uniform particle size. These are important factors, as a yard - leaf compost would be more appropriately used when applying compost to a project site that is close to a water source. In addition, yard – leaf compost is more coarse and is a better choice for a blanket, filter sox or berm to control erosion.
Both yard – leaf compost and the manure compost could be used for turf applications. However, if using manure compost, the fertilizer application may need to be adjusted downward so as to not over fertilize the turf and inadvertently create nutrient runoff.
Compost maturity is another important factor. Using compost that has been properly aged as a post-construction soil amendment promotes healthy root and plant growth and will prevent damage to turf and plantings. When immature compost is applied to soils it continues to decompose and the process of decomposition robs nitrogen from the plants and stunts plant growth, possibly even killing the plant.
To facilitate the creation of consistent compost products throughout the United States, the U.S. Composting Council (USCC) created the Seal of Testing Assurance Program (STA). This voluntary program requires participating compost facilities to perform a uniform set of tests on their compost products. Composters who are STA participants are required to furnish test information to compost buyers. This gives the purchaser of the compost the agronomic information needed (such as pH, particle size and test results from a number of other parameters) to successfully use the compost.
When purchasing compost to be used for turf establishment or incorporation into soil as a post-construction soil amendment, look for the specifications listed in Table 1.
The goal in amending compacted soils with compost is to reach or exceed the stormwater management benefits of naturally occurring soil and vegetation. Compost amended soils will improve on-site stormwater management and reduce long term operation and maintenance costs for off-site water treatment best management practices. Developing a Soil Management Plan is an important first step in minimizing and mitigating impacts to native soils and maximizing onsite stormwater management benefits.
In areas where remaining topsoil or subsoil will be amended in place, it is important that, at a minimum, certain soil quality and depth improvements are achieved, as follows:
Soil Quality: For soils in planting areas, a minimum dry weight organic matter content of 10% is recommended. For soils in turf areas, a minimum dry weight organic matter content of 5% is recommended. Soil pH should range from 6.0 to 8.0 or match the pH of the original topsoil (WDOE, 2005).
Depth: Within the construction limits, a minimum, uncompacted depth of 12 inches is recommended (Kunz and Jurries, 2001, WDOE, 2005). In high traffic areas, a minimum uncompacted depth of 18 inches is recommended. Table 1 summarizes how to achieve these depths in planting areas and turf areas.
When leaching of nutrients could be harmful to a receiving water, is it important to take the compost source into consideration. Because compost made from biosolids or animal manure tends to be higher in nutrients, there is the possibility of nutrient leaching. In general, adequately composted tree and grass material presents less of a problem than animal waste or mixed municipal compost. These types of compost are less appropriate for certain uses in areas in close proximity to water bodies. Note that the use of potential nutrient leaching compost as a filter material in such things as compost socks or filter bags should be avoided whenever excess nutrient (see previous section on Materials Specification) content of water flowing through the filter and into a receiving water would cause a problem. Specification of compost without extractable phosphorus is recommended in cases when nutrients are a receiving water concern.
In addition to improving the stormwater management functions of compacted soils, compost has several other beneficial uses. The first part of this Fact Sheet addressed soil compost for uses as a post-construction BMP. Because there are so many benefits for compost, its use in construction runoff control is also discussed in the following paragraphs. Many of the uses of compost certainly overlap and can serve both construction and post-construction purposes.
When purchasing compost to be used for turf establishment or incorporation into soil as a postconstruction soil amendment, look for these specifications.
Link to this table
Parameter | Parameter Definition | Range (Provided by G. Black, MPCA, 2007) |
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Source Material/Nutrient Content | Compost typically comes from biosolids/animal manure or yard wastes. Compost made from biosolids and animal manure typically contains more nutrients.1 |
|
Maturity | Maturity refers to the level of completeness of the composting process. Composts that have not progressed far enough along the decomposition process may contain phytotoxic compounds that inhibit plant growth.2 | Seed emergence and seed vigor = minimum 80% relative to positive control |
Stability | Compost stability refers to the biological activity in the composted material. Unstable composts may use available nitrogen in the soil and stunt plant growth. | CO2 Evolution rate: < 8 mg CO2-C/g-OM/day |
pH | pH is a measure of acidity/alkalinity. Amending soil with compost can alter soil pH, which in turn can improve plant growth. | 5.5 – 8.5 |
Soluble salts | The term “soluble salts” refers to the amount of soluble ions in a solution of compost and water. Because most plant nutrients are supplied in soluble form, excess non-nutrient soluble salts can inhibit plant growth. | Varies widely according to source materials for compost, but should be < 10 dS/m (mmhos/cm) |
Organic matter | Organic matter is a measure of the amount of carbon-based materials in compost. There is no ideal range of organic matter for compost, but knowing the amount of organic matter in compost may help determine application rates for specific applications. | 30-65% dry weight basis |
Particle size | It is helpful to know the size of particles in a compost product. There is no ideal range, but particle size does influence the usability of a compost product for a specific application. | Pass through 1-inch screen or less; 3/4 inch is preferable per MnDOR Specification 3890 |
Biological contaminants (weed seeds and pathogens) | Biological contaminants consist of pathogens (disease causing organisms) and weed seeds. High temperatures will inactivate both types of biological contaminants. Minnesota State composting rules require commercial composting operations to hold temperatures over 55 degrees C over an extended period of time to destroy pathogens. In addition, compost operations must monitor the process to prove that these conditions have been met. | Meet or exceed US EPA Class A standards, 40 CFR §503.32(a) levels |
Physical contaminants (inerts)* | Inerts are man-made materials (like pieces of plastic or glass) that do not decompose. There is no ideal range but they may be aesthetically unpleasing and add no value to the compost. | < 1% dry weight basis3 |
Trace metals | Trace metals are elements that can be toxic to humans, animals, or plants at elevated concentrations | Meet or exceed US EPA Class A standards, 40 CFR §503.32(a) levels |
* Inert material should not be present in adequately screened, vegetated waste compost. Caution should be used when the compost originates as mixed municipal or unscreened compost. |
1 MnDOT Grade 1 compost is derived from animal material; Grade 2 compost is derived from leaves and yard wastes. See MnDOT Specification 3890
2MnDOT Specification 3890 states: "Considered mature and useable when 60 percent decomposition has been achieved as determined by an ignition-loss analysis test method and any one additional test method including the Solvita test value of equal to or greater than 5. This means that the compost product has no offensive smell, no identifiable organic materials, and will not reheat to more than 20 °F [11 °C] above the ambient temperature."
3 MnDOT Specification 3890 states: "< 3% at 0.15 in [4 mm]"
Application guidelines for compost.
Link to this table
Planting areas | Turf areas | |
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High-traffic areas | (18 inch uncompacted depth) Incorporate 3 inches of compost into the top 5 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 10 inches. | Incorporate 1.75 inches of compost into the top 6.25 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 10 inches |
Construction limits | (12 inch uncompacted depth) Incorporate 3 inches of compost into the top 5 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 4 inches | Incorporate 1.75 inches of compost into the top 6.25 inches of compacted soil to create a topsoil layer with a minimum depth of 8 inches. Soils below the top soil layer should be scarified to at least 4 inches |
If you are considering using compost as a “blanket” to reduce or prevent erosion (See Table 3), the soil blanket should be a composted, weed free organic matter source derived from: agricultural, food, or industrial residuals; yard trimmings; or source-separated or mixed solid waste. Particle size shall be as described below in the product parameters table. The compost shall possess no objectionable odors, will be reasonably free (< 1% by dry weight) of foreign matter and will meet the product parameters outlined below.
Well-composted product will provide the best planting medium for grass, wildflower, legume seeding or ornamental planting. Very coarse composts may need to be avoided if the slope is to be landscaped or seeded, as it will make planting and crop establishment more difficult. Composts containing fibrous particles that range in size produce a more stable mat.
A. Construction Requirements:
Compost mulch shall be uniformly applied to a depth described below. Areas receiving greater precipitation (see Table 4), possessing a higher erosivity index, or which will remain unvegetated, will require greater application rates.
The compost should be spread uniformly on up to 1:2 slopes, then track (compact) the compost layer using a bulldozer or other appropriate equipment, if possible. Alternatively, apply compost using a pneumatic (blower) or slinger type spreader unit. Project compost directly at soil surface, thereby preventing water from moving between the soil-compost interface. Apply compost layer approximately 3 feet beyond the top of the slope or overlap it into existing vegetation. On highly unstable soils, use compost in conjunction with appropriate structural, stabilization and diversion measures. Follow by seeding or ornamental planting if desired.
A. Description:
This work consists of constructing a raised berm of compost on a soil surface to contain soil erosion, control the movement of sediment off site, and to filter storm water.
B. Materials:
Filter berm media should be a composted, weed free organic matter source derived from: agricultural, food, or industrial residuals; yard trimmings; source-separated or mixed solid waste. Particle size may vary widely. The compost shall possess no objectionable odors, will be reasonably free (< 1% by dry weight) of man-made foreign matter and will meet the product parameters outlined below.
Where seeding of the berm is planned, use only well composted product that contains no substances toxic to plants. Avoid coarse composts if the berm is to be seeded, as it will make establishment more difficult.
The Landscape Architect/Designer shall specify the berm dimensions depending upon specific site (e.g., soil characteristics, existing vegetation) and climatic conditions, as well as particular project related requirements. The severity of slope grade, as well as slope length, will also influence compost application.
C. Construction Requirements
Parallel to the base of the slope or other affected areas, construct a berm of compost to the size specifications outlined in Table 6.
In extreme conditions and where specified by the Landscape Architect/Designer, a second berm shall be constructed at the top of the slope or silt fencing shall be installed in conjunction with the compost berm. Where the berm deteriorates, it shall be reconstructed. Do not use filter berms in any runoff channels (concentrated flows).
In addition to improving the stormwater management functions of compacted soils, compost has several other beneficial uses
Compost can be used to reclaim highly disturbed and low quality soils on sites of old factories, landfills, and brownfields. Application rates in such situations often range from 25 to 175 tons per acre, much higher than typical compost application rates. Benefits include improved soil quality and enhanced plant establishment (Alexander, 1999).
Due to its similar physical and chemical properties to certain wetland soils, compost is being used to mimic hydrology, soil properties and plant community composition wetland functions.
Compost has been shown to be effective in degrading or immobilizing several types of contaminants, including hydrocarbons, solvents, and heavy metals (Alexander, 1999).
Compost has been included as a component of biofilters and bioswales to treat contaminated air and water with great success (Alexander, 1999). Compost treated areas have also be shown to be effective at reducing erosion and stormwater runoff (Glanville, et. al., 2003). Because contaminants adhere to soil particles, this limits the amount of sediment and contaminants reaching water bodies.
Minnesota Pollution Control Agency.
Washington Department of Ecology. 2005. Guidelines and Resources for Implementing Soil Quality and Depth BMP T5.13
Soils for Salmon (Washington).
U.S. Composting Council Seal of Testing Assurance Program.
USEPA, Construction Site Storm Water Runoff Controls; Compost Blankets and Berms:
USEPA, Bioretention Cells and Green Roof:
Alexander, R. 1999. Compost Markets Grow with Environmental Applications. BioCycle Vol. 40, No. 4, pp. 43-48.
Garland, G. and Grist, T.1995. The Compost Story:From Soil Enrichment to Pollution Remediation. BioCycle , Vol. 36, No. 10, pp. 53-56.
Glanville, T., Richard, T., and Persyn, R. 2003. Impacts of Compost Blankets on Erosion Control, Revegetation, and Water Quality at Highway Construction Sites in Iowa. Iowa State University.
Kunz, D. and Jurries, D. 2001. Restoring Soil Health. Oregon Department of Environmental Quality.
McDonald, D. 2005. Soil Restoration with Organics Enters Mainstream of Storm Water Practices. BioCycle, Vol. 46, No. 4, pp. 20-22.
Washington Department of Ecology. 2005. Guidelines and Resources for Implementing Soil Quality and Depth BMP T5.13.
Alexander, R. 1999. Compost markets grow with environmental applications. BioCycle 40(4): 43- 48. Summarizes uses of compost: erosion control, revegetation and reclamation of marginal and low quality soils, biofilters and bioswales, bioremediation, wetlands construction. The benefits of amending soil with compost include improved soil quality, reduced erosion, enhanced plant establishment, immobilization of toxic metals and supplying microbes.
Alexander, R. 2003. Landscape Architect Specifications for Compost Utilization. The LASCU, developed for the Clean Washington Center and the US Composting Council is a guide that give specifications for specific uses of compost. Topics include turf establishment (page 40-41), planting bed establishment, backfill mix, mulch, compost blanket for erosion control (pages 48-19), and compost filter berms for sediment control (pages 40-51).
Composting Council Research and Education Foundation. 2001. Compost Use on State Highway Applications. CCREF/USCC. Document focuses on compost use on state and local ‘roadside’ applications. Defines compost as “the product resulting from the controlled biological decomposition of organic material that has been sanitized through the generation of heat and stabilized to the point that it is beneficial to plant growth. Compost bears little physical resemblance to the raw material from which it originated. Compost is an organic matter resource that has the unique ability to improve the chemical, physical, and biological characteristics of soils or growing media” (p. 2) The addition of compost to soil provides the following benefits: improved structure, moisture management, modifies and stabilizes ph,increases cation exchange capacity, provides nutrients, provides soil biota, suppresses plant diseases, binds contaminants (p. 3). Includes info on State DOT compost specifications and a “Model DOT Compost Specification. Common specification parameters include pH, particle size, soluble salts, organic matter, moisture content, stability/maturity, pathogens, heavy metals, inerts (p. 55).The importance of each parameter is discussed on p. 61-62.
Garland, G. and Grist, T.1995. The compost story: From soil enrichment to pollution remediation. Bio-Cycle 36(10): 53-56. Defines compost as “a recycled product made from the organic portion of municipal solid waste” (p. 2). Compost is NOT peat or mulch. As organic wood mulch decays it tends to use the nitrogen already in the soil, reducing the amount available for plants. This lack of available nitrogen can retard the growth of young plants. Immature compost is nothing more than an organic mulch and does not provide the benefits of mature compost.
Beneficial uses of compost: soil enrichment (adds organic bulk, increases earthworm populations, humus, and cation exchange capacity), pollution prevention, and pollution reduction.
Ge, B., McCartney, D., and Zeb, J. 2006. Compost Environmental Protection standards in Canada. Journal of Environmental Engineering Science 5: 221-234. Canadian standards typically consider maturity, trace element (heavy metals), time-temperature requirements, microbial pathogens, and foreign matter.
Defines stability as “the rate or degree of organic matter decomposition” (p. 223). Stability can be determined by microbial activity and/or substrate availability (examples include microbial respiration and energy release).
Defines maturity as “the degree of decomposition of phytotoxic organic substances produced during decomposition” (p. 223). Can be determined by a plant biotest.
Maturity and stability are important considerations because “immature compost applied to the soil will continue to decompose and may produce odorous products and are often toxic to plants.
A trace element is a chemical element present in compost at a very low concentration (p. 224). States that there are three approaches to developing trace element standards: no net degradation, risk-based, and best achievable technology.
Microbial pathogens: Four major categories of pathogens: bacteria, enteric viruses, protozoa, and helminthes. Some pathogens may survive in finished compost if the compost is immature or if thermophilic conditions are not achieved throughout the composting mass.
Foreign matter: Defined as “any matter over 2 mm in dimension that results from human intervention and has organic or inorganic components such as metal, glass, synthetic polymers” (p. 230). Excludes mineral soil, woody material, and pieces of rock.
Glanville, T., Richard, T., and Persyn, R. 2003. Impacts of Compost Blankets on Erosion Control, Revegetation, and Water Quality at Highway Construction Sites in Iowa. Iowa State University. The primary objective of this research project is to compare the performance of compost treated and conventionally treated roadway embankments. Performance was measured using the following parameters: runoff quantity, runoff quality, rill and interrill erosion, and seasonal growth of planted species and weeds.
Study tested 3 types of compost: fine-textured biosolids compost, a coarse-textured mulch-like yard waste compost, and a medium-textured bio-industrial compost derived from paper mill and grain processing sludge (selected because of wide-spread availability in Iowa). Compost types were spread as blankets at 2 depths (5 cm and 10 cm) and were not incorporated into the underlying soil.
Results:
Kunz, D. and Jurries, D. 2001. Restoring Soil Health. Oregon Department of Environmental Quality. This document explains the link between land use planning, and building and road construction, and degraded surface water. It summarizes current research on the benefits of amending soil with compost and provides information on technical specifications for using and applying compost to building and road construction projects.
Suggests “tilling in about 4” of compost is a simple, cost-effective way to restore organic health to a site” (p. 5). Construction activities can increase stormwater runoff by compacting soil (p. 8). Discusses impacts of human activity on soils including compaction and degraded soils and suggests compost amendments to be a solution to the problems associated with compact and degraded soils. Compost amendments can increase the porosity of the soil and add beneficial organisms and nutrients back to the soil. Recommend applying four inches of compost on the surface and tilling it in to a depth of eight inches of compacted soil for a total depth of twelve inches (p. 13).
McDonald, D. 2005. Soil Restoration with Organics Enters Mainstream of Storm Water Practices. Bio-Cycle 46 (4): 20-22. Features the Soils for Salmon project. The project promotes BMPs for protecting native soil and vegetation where possible, and for restoring soil functions on disturbed sites through the incorporation of organic amendments. Amending the soil with compost provides the following benefits: “increases stormwater infiltration, reducing damaging runoff, and also helps filter out urban pollutants (oils and metals from roads, pesticides and fertilizers from landscapes) while creating more successful landscapes that need less chemicals and less summer irrigation” (p. 20).
Musick M, and Stenn, H. 2004. Best Management Practices for Post-Construction Soils. BioCycle 45 (2): 29. Summarizes new guidelines for soil quality and depth BMPs in Washington State Stormwater Manual. Benefits of undisturbed soils include: water infiltration and storage, nutrient and sediment adsorption, and pollutant biofiltration. Top priority is given to preservation of existing soils. For sites that must be cleared and graded, guidelines require that all disturbed and compacted soils shall be amended to mitigate for lost moisture infiltration and moisture holding capacity. Guidelines call for a minimum of 8 inches of topsoil over subsoil scarified to a depth of 4 inches.
Noble, R., and Coventry, E. 2005. Suppression of soil-borne plant diseases with composts: A review. Biocontrol Science and Technology 15(1): 3-20. Reviews several studies that show the suppressive effect of compost on soil-borne diseases.
Pitt, R., et al.1999. Infiltration Through Disturbed Urban Soils and Compost-Amended Soil Effects on Runoff Quality and Quantity. US EPA. Article examines the effects of urbanization on soil structure and how compaction affects infiltration of rainwater. Also looks at the effectiveness of using compost as a soil amendment to increase infiltration and reduce runoff. Found a “generally beneficial effect of the compost amendment in regards to nutrient content as well as soil physical properties known to affect water relations in soils” (p. 4-1). Found that “the use of compost amended soil resulted in significantly increase infiltration rates compared to soil alone” (p. 4-2). Found that “the growth rates of turf were also greater for the amended sites” (p. 4-4).
Risse, M. and Faucette, B. 2001. Compost Utilization for Erosion Control. Cooperative Extension Service, The University of Georgia college of Agricultural and Environmental Science. Defines composting as “the controlled biological process of decomposition and recycling of organic material into a humus rich soil amendment known as compost. Mixed organic materials (Example: manure, yard trimmings, food waste, biosolids) must go through a controlled heat process before they can be used as high quality, biologically stable and mature compost (otherwise it is just mulch, manure or byproduct)” (p. 1). Focuses on benefits of compost for erosion control such as increasing water infiltration, reducing runoff and soil particle transport in runoff, increasing plant growth and soil cover, reducing soil particle dislodging, increasing water holding capacity of soil, which reduces runoff, buffering soil ph which can increase vegetation establishment and growth, alleviates soil compaction by increasing soil structure, new vegetation can be established directly into compost (p. 3)
Includes recommended compost specifications for several parameters including particle size, moisture content, soluble salt, organic matter, ph, nitrogen content, human made inerts, application rate/size, maturity
Russell, S. and Best, L. 2006. Setting the Standards for Compost. BioCycle 47(6): 53-56. Summarizes UK standards for compost (feedstocks, stability tests, monitoring procedures, and certification methods). Includes guidelines for pathogens, potentially toxic elements, stability/maturity, plant response, weed seeds and propagules, physical contaminants, stones (see page 55).</P
Zabinski, C., et al. 2002. Restoration of Highly Impacted Subalpine Campsites in the Eagle Cap Wilderness, Oregon. Restoration Ecology 10(2): 275-281. Tested the use of compost in the restoration of highly impacted campsites in the Eagle Cap Wilderness. Plotes as four campsites were scarified, amended with compost, and planted to native species. Assessed the degree to which campsite activity altered soil chemical and microbial properties relative to undisturbed soils and the degree of recovery after compost application. Found that three years after compost amendments were applied, levels of total carbon, PMN, and microbial carbon utilization profiles on campsites were equivalent to those under vegetation on undisturbed sites. Compost amendments also supplied “a slow release of macro and micronutrients, improved water-holding capacity, reduced albedo, and increased heat absorption in the spring” (p. 279).