Photo illustrating permeable interlocking concrete pavement.
Bioinfiltration (rain garden) in a residential development. Photo courtesy of Katherine Sullivan.
Infiltration is the practice of draining water into soils, typically through engineered systems such as bioinfiltration (rain gardens), infiltration basins, dry swales with check dams, and permeable pavement. The practice of infiltration is beneficial for soils, maintaining natural hydrology, and has a significant water quality impact for downstream lakes, rivers, and ponds. Depending on design, stormwater infiltration practices can be a key component of GI to promote the health and well-being of animals, vegetation, and the people that rely upon these waters when designing sites.
Some of the more common infiltration practices include
- infiltration basins and trenches,
- rain gardens,
- vegetated swales,
- underground infiltration systems,
- permeable pavement, and
- tree trenches.
For further reading on different types of infiltration, see Stormwater infiltration Best Management Practices and BMPs for stormwater infiltration.
Green infrastructure and multiple benefits
Green infrastructure (GI) encompasses a wide array of practices, including stormwater management. Green stormwater infrastructure (GSI) encompasses a variety of practices primarily designed for managing stormwater runoff but that provide additional benefits such as habitat or aesthetic value.
There is no universal definition of GI or GSI (link here fore more information). Consequently, the terms are often interchanged, leading to confusion and misinterpretation. GSI practices are designed to function as stormwater practices first (e.g. flood control, treatment of runoff, volume control), but they can provide additional benefits. Though designed for stormwater function, GSI practices, where appropriate, should be designed to deliver multiple benefits (often termed "multiple stacked benefits". For more information on green infrastructure, ecosystem services, and sustainability, link to Multiple benefits of green infrastructure and role of green infrastructure in sustainability and ecosystem services.
Benefit |
Effectiveness |
Notes
|
Water quality |
● |
Most pollutants are retained in the engineered media, soil, or vadose zone. If transported to groundwater, concentrations of most pollutants are below water quality standards. Chloride is an exception.
|
Water quantity/supply |
◕ |
Can provide effective flood control for small- and medium-intensity storms.
|
Energy savings |
◔ |
|
Climate resiliency |
◔ |
Flood control. Impacts on carbon sequestration are uncertain.
|
Air quality |
◑ |
|
Habitat improvement |
◕ |
Use of perennial vegetation and certain media mixes promote invertebrate communities, pollinators, birds, and potentially small mammals.
|
Community livability |
◕ |
When vegetation is incorporated, aesthetically pleasing and can be incorporated into a wide range of land use settings.
|
Health benefits |
◔ |
|
Economic savings |
◔ |
Generally provide cost savings vs. conventional practices over the life of the practice.
|
Macroscale benefits |
◑ |
Macroscale effects depend on the size of the practice. Some infiltration practices, typically underground or tree trench systems, can be very large and have macroscale benefits.
|
Level of benefit: ◯ - none; ◔ - small; ◑ - moderate; ◕ - large; ● - very high
|
Green Infrastructure benefits of infiltration practices
- Water quality: Stormwater infiltration practices are excellent water quality treatment practices. Engineered media, soils, and the underlying vadose zone provide effective retention of most pollutants, as indicated in the accompanying table. Chloride and nitrate are exceptions, though concentrations of these are generally below water quality standards except for chloride during deicing season. Infiltration should be avoided in areas where contaminants in soil or groundwater may be mobilized by infiltrating water. For more information, see Surface water and groundwater quality impacts from stormwater infiltration
Minimum bioretention soil media depths recommended to target specific stormwater pollutants. From Hunt et al. (2012) and Hathaway et al., (2011). NOTE: The Construction Stormwater permit requires a 3 foot separation from the bottom of an infiltration practice and bedrock or seasonally saturated soils.
Link to this table
Pollutant |
Depth of Treatment with upturned elbow or elevated underdrain |
Depth of Treatment without underdrain or with underdrain at bottom |
Minimum depth |
Total suspended solids (TSS) |
Top 2 to 3 inches of bioretention soil media |
Top 2 to 3 inches of bioretention soil media |
Not applicable for TSS because minimum depth needed for plant survival and growth is greater than minimum depth needed for TSS reduction |
Metals |
Top 8 inches of bioretention soil media |
Top 8 inches of bioretention soil media |
Not applicable for metals because minimum depth needed for plant survival and growth is greater than minimum depth needed for metals reduction |
Hydrocarbons |
3 to 4 inch Mulch layer, top 1 inch of bioretention soil media |
3 to 4 inches Mulch layer, top 1 inch of bioretention soil media |
Not applicable for hydrocarbons because minimum depth needed for plant survival and growth is greater than minimum depth needed for hydrocarbons reduction |
Nitrogen |
From top to bottom of bioretention soil media; Internal Water Storage Zone (IWS) improves exfiltration, thereby reducing pollutant load to the receiving stream, and also improves nitrogen removal because the longer retention time allows denitrification to occur underanoxic conditions. |
From top to bottom of bioretention soil media |
Retention time is important, so deeper media is preferred (3 foot minimum) |
Particulate phosphorus |
Top 2 to 3 inches of bioretention soil media. |
Top 2 to 3 inches of bioretention soil media. |
Not applicable for particulate phosphorus because minimum depth needed for plant survival and growth is greater than minimum depth needed for particulate phosphorus reduction |
Dissolved phosphorus |
From top of media to top of submerged zone. Saturated conditions cause P to not be effectively stored in submerged zone. |
From top to bottom of bioretention soil media |
Minimum 2 feet, but 3 feet recommended as a conservative value; if IWS is included, keep top of submerged zone at least 1.5 to 2 feet from surface of media |
Pathogens |
From top of soil to top of submerged zone. |
From top to bottom of bioretention soil media |
Minimum 2 feet; if IWS is included, keep top of submerged zone at least 2 feet from surface of media |
Temperature |
From top to bottom of bioretention soil media; Internal Water Storage Zone (IWS) improves exfiltration, thereby reducing volume of warm runoff discharged to the receiving stream, and also improves thermal pollution abatement because the longer retention time allows runoff to cool more before discharge. |
From top to bottom of bioretention soil media |
Minimum 3 feet, with 4 feet preferred |
- Water quantity and hydrology:Infiltration practices reduce the volume of stormwater runoff and retard peak flow from rainfall events, thus reducing flood potential in areas downstream of the practice. They are most effective for small- and medium-intensity rain and runoff events unless sized to meet larger events. Infiltration promotes groundwater recharge, potentially increasing baseflow and/or recharge of deeper aquifers.
- Energy savings: Larger infiltration practices that incorporate trees and provide shade reduce air conditioning costs. Since infiltration reduces stormwater runoff, they help prevent road deterioration and reduce maintenance costs (Using Trees and Vegetation to Reduce Heat Islands;US EPA).
- Air quality: Benefits of infiltration practices are largely indirect, such as sequestration of carbon and other greenhouse gasses. Carbon sequestration is generally insignificant unless vegetation is incorporated into the practice and the soil or engineered media promotes biologic activity.
- Climate resiliency: Properly installed infiltration practices reduce the impact of flooding during rainfall events, particularly small- and medium-sized events. Vegetated infiltration systems promote photosynthesis and carbon sequestration. Incorporation of larger plants such as trees or vegetation that provides shade reduces effects of heat islands (Using Trees and Vegetation to Reduce Heat Islands;US EPA).
- Habitat improvement: Infiltration results in decreased runoff and erosion, which increases soil stability. This promotes vegetation growth that further stabilizes a site and creates habitat for birds, pollinator insects, and potentially small mammals. Soil or media may be engineered to promote invertebrate avtivity. Reduced runoff associated with increased infiltration reduces adverse effects of elevated temperatures that harm coldwater organisms.
- Community livability: Infiltration that results in groundwater recharge and improved baseflow provides increased recreational opportunities helps ensure safe and healthy access to water sources. Incorporating aesthetically pleasing landscaping when planning infiltration systems may help improve mental health of the site users (What are the physical and mental benefits of gardening? - Michigan State University Extension). Large infiltration practices that incorporate trees into the design provide shade that can reduce air temperatures (Reducing Urban Heat Islands: Compendium of Strategies: Trees and Vegetation; EPA).
- Health benefits: Infiltration provides cleaner waterways through the reduction of nutrients, pathogens, metals, TSS, and phosphorus and provides healthier environments to the humans, wildlife, and vegetation that use these waters.
- Economic benefits and savings: In addition to water quality and flood control benefits (Braden and Johnston, 2004), properly designed infiltration can prevent downstream cleanup costs. Well maintained infiltration systems combined with vegetation may increase property aesthetics and property value. Properly designed and functioning infiltration systems reduce downstream infrastructure costs (Braden and Johnston, 2004).
Design considerations
Maximizing specific green infrastructure (GI) benefits of constructed areas requires design considerations prior to installation. While site limitations cannot always be overcome, the following recommendations for a designer are given to maximize the GI benefit. In addition to the following information, many design considerations applicable to bioretention should be considered for infiltration practices.
Note: Under the Minnesota Construction Stormwater Permit GI, particularly infiltration, must be considered first when selecting stormwater treatment methods. However, if Class D soils are present on the site infiltration practices cannot be used. Class A soils are the most desirable for infiltration but infiltration systems can also be successful with B or C soils. --- Maybe add a chart indicating soil penetrability of different HSG groups —
- Water quality
- Follow appropriate design guidance to maximize capture of runoff. Consider local climate characteristics (Gonzalez-Meler et al., 2013).
- Design infiltration basins to minimize short-circuiting that results in water bypassing the treatment zones in the practice. Deep macropores may lead to short-circuiting but may be desirable for maximizing infiltration. If macropore development is encouraged, ensure water preferentially transported vertically receives appropriate treatment by ensuring underlying soils can effectively treat pollutants.
- Infiltration systems with ecological diversity can help promote water quality treatment through effective uptake of pollutants (e.g. nutrients) or through breakdown of pollutants (e.g. promote microbiologic breakdown, such as by ensuring a food source (e.g. organic matter) and oxygenated environment). Diversifying the vegetation will remove a wider range of pollutants and maximize the water treatment
- Ensure adequate pretreatment
- Design the infiltration system to minimize effects of groundwater (e.g. elevated groundwater table), mounding beneath the system, and intersection with underlying sewer systems (Thompson et. al, 2021).
- Water quantity and hydrology:
- Follow appropriate design guidance to maximize capture of runoff. Consider local climate characteristics (Gonzalez-Meler et al., 2013).
- Promoting macropore development results in increased infiltration. Macropores are associated with vegetation and increased invertebrate activity. These can be enhanced through use of deep-rooted perennial vegetation and organic-rich engineered media or soil (Ossola et. al, 2015).
- Distributed infiltration systems throughout an area site typically provide increased hydrologic capacity, partly as a result of reducing the risk and impacts of system failure. One way to increase distribution of infiltration systems is to encourage infiltration on individual parcels (Cadavid and Ando, 2013; Shahzad et al., 2022).
- Maximize water storage by manipulating the media and incorporating internal storage.
- Increase the size of infiltration systems, if feasible, to maximize capture of runoff.
- Climate resiliency:
- To reduce heat island effects, select vegetation that reflects solar energy, absorbs solar energy and releases it slowly, or that maximizes evapotranspiration NYC Mayor’s Office of Recovery and Resiliency.
- Oversize bowl depth (storage) to account for increased precipitation. Winston (2016) recommends oversizing by 33-45% for bioretention in northern Ohio. Oversizing can also be accomplished by reducing loading to individual bioretention practices.
- Establish thicker media depths (Winston (2016) recommends 48 to 102 inches for northern Ohio) to enhance vegetation survival during wet or extended dry periods.
- Utilize internal water storage
- Select vegetation that can be easily established but also provides potential for carbon sequestration. This includes incorporation of trees and shrubs into the design.
- Habitat improvement:
- Providing a littoral shelf for the growth of macrophytes in an infiltration system promotes healthier wildlife populations
- Planting plants for pollinators in infiltration systems is an effective area to establish healthier pollinator colonies — link to pollinator page
- Community livability:
- Include recreational infrastructure and interpretative signs
- Construct the infiltration system in a way that ensures safety and perceived safety of the area. A few examples would be to use shallower infiltration systems to avoid child accidents, attracting pollinators that are appropriate for the nearby community, or planting shrubs, fencing, or vegetation that prevents people from entering the system
- Conduct surveys prior to and after development to identify community desires and construct features that enhance education, recreation, and other benefits of infiltration
- Develop conveyance systems in such a way to minimize changes in temperature that can be detrimental to wildlife such a temperature sensitive fish
- Health benefits:
- Infiltration that incorporates landscaping principles reduce heat stress associate with heat islands (Reducing Urban Heat Islands: Compendium of Strategies: Trees and Vegetation (epa.gov))
- Infiltration that incorporates landscaping principles increases the mental health of the communities that use the area (What are the physical and mental benefits of gardening? - MSU Extension)
- Infiltration systems naturally control mosquito habitats by going dry within a few days compared to stormwater ponds
- Economic benefits and savings:
- Properly designed infiltration can prevent downstream cleanup costs
- Infiltration systems that incorporate desired landscape vegetation may increase property aesthetics and value
Recommended reading
References
- Braden, J.B., and Douglas M. Johnston. Downstream Economic Benefits from Storm-Water Management. Journal of Water Resources Planning and Management. Volume 130 Issue 6. https://doi.org/10.1061/(ASCE)0733-9496(2004)130:6(498).
- Cadavid, C.L., A.W. Ando. 2013. Valuing preferences over stormwater management outcomes including improved hydrologic function. Volume 49, Issue 7, Pages 4114-4125. https://doi.org/10.1002/wrcr.20317.
- Darnton, J., and L. McGuire. 2014. What are the physical and mental benefits of gardening?. Michigan State University Extension.
- Gonzalez-Meler, M.A., L. A. Cotner, D. A. Massey, M. L. Zellner, and E. S. Minor. 2013. Ecology and Evolution Group, Department of Biological Scienc The Environmental and Ecological Benefits of Green Infrastructure for Stormwater Runoff in Urban Areas.
- Ossola, A., A. K. H. Hahs, S. J. Livesley. 2015. Habitat complexity influences fine scale hydrological processes and the incidence of stormwater runoff in managed urban ecosystems. Journal of Environmental Management. https://doi.org/10.1016/j.jenvman.2015.05.002.
Volume 159, Pages 1-10
Related pages
Additional References from the Minnesota Stormwater Manual