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− | [[File:Native landscaping.jpg|thumb|300px|alt=photo of a rain garden planted with native vegetation|<font size=3>Example of a rain garden planted with native vegetation.</font size>]] | + | [[File:Native landscaping.jpg|thumb|left|300px|alt=photo of a rain garden planted with native vegetation|<font size=3>Example of a rain garden planted with native vegetation.</font size>]] |
+ | [[File:Pdf image.png|100px|thumb|right|alt=pdf image|<font size=3>[https://stormwater.pca.state.mn.us/index.php?title=File:Green_Infrastructure_benefits_of_bioretention_-_Minnesota_Stormwater_Manual.pdf Download pdf]</font size>]] | ||
+ | [[File:General information page image.png|right|100px|alt=image]] | ||
− | + | <span title="Bioretention, also called rain gardens, is a terrestrial-based (up-land as opposed to wetland) water quality and water quantity control process. Bioretention employs a simplistic, site-integrated design that provides opportunity for runoff infiltration, filtration, storage, and water uptake by vegetation. Bioretention areas are suitable stormwater treatment practices for all land uses, as long as the contributing drainage area is appropriate for the size of the facility. Common bioretention opportunities include landscaping islands, cul-de-sacs, parking lot margins, commercial setbacks, open space, rooftop drainage and street-scapes (i.e., between the curb and sidewalk). Bioretention, when designed with an underdrain and liner, is also a good design option for treating Potential stormwater hotspots. Bioretention is extremely versatile because of its ability to be incorporated into landscaped areas. The versatility of the practice also allows for bioretention areas to be frequently employed as stormwater retrofits."> '''Bioretention practices'''</span>, often called rain gardens, are small vegetated landscape practices designed to <span title="Filtration Best Management Practices (BMPs) treat urban stormwater runoff as it flows through a filtering medium, such as sand or an organic material. They are generally used on small drainage areas (5 acres or less) and are primarily designed for pollutant removal. They are effective at removing total suspended solids (TSS), particulate phosphorus, metals, and most organics. They are less effective for soluble pollutants such as dissolved phosphorus, chloride, and nitrate."> [https://stormwater.pca.state.mn.us/index.php?title=Filtration '''filter''']</span> or <span title="Infiltration Best Management Practices (BMPs) treat urban stormwater runoff as it flows through a filtering medium and into underlying soil, where it may eventually percolate into groundwater. The filtering media is typically coarse-textured and may contain organic material, as in the case of bioinfiltration BMPs."> [https://stormwater.pca.state.mn.us/index.php?title=Stormwater_infiltration_Best_Management_Practices '''infiltrate''']</span> stormwater runoff. They have a relatively simplistic design that can be incorporated into a wide variety of landscaped areas. Common bioretention opportunities include landscaping islands, cul-de-sacs, parking lot margins, commercial setbacks, open space, rooftop drainage and street-scapes (i.e., between the curb and sidewalk). | |
− | + | ==Green infrastructure and multiple benefits== | |
+ | <span title="Green stormwater infrastructure is designed to mimic nature and capture rainwater where it falls. Green infrastructure reduces and treats stormwater at its source while while also providing multiple community benefits such as improvements in water quality, reduced flooding, habitat, carbon capture, etc."> '''Green infrastructure'''</span> (GI) encompasses a wide array of practices, including stormwater management. <span title="Green stormwater infrastructure (GSI) describes practices that use natural systems (or engineered systems that mimic or use natural processes) to capture, clean, and infiltrate stormwater; shade and cool surfaces and buildings; reduce flooding, create wildlife habitat; and provide other services that improve environmental quality and communities’ quality of life. (City of Tucson)"> '''Green stormwater infrastructure'''</span> (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 ([https://stormwater.pca.state.mn.us/index.php?title=Green_infrastructure_and_green_stormwater_infrastructure_terminology link here for 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]]. | |
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+ | ==Green Infrastructure benefits of bioretention== | ||
Because of their diversity and use of vegetation, bioretention practices provide multiple green infrastructure benefits. | Because of their diversity and use of vegetation, bioretention practices provide multiple green infrastructure benefits. | ||
− | *[https://stormwater.pca.state.mn.us/index.php?title=Water_quality_benefits_of_Green_Stormwater_Infrastructure Water quality]: Bioretention is an excellent stormwater treatment practice due to the variety of pollutant removal mechanisms, including vegetative filtering, settling, evaporation, infiltration, transpiration, biological and microbiological uptake, and soil adsorption. Bioretention can be designed as an effective [https://stormwater.pca.state.mn.us/index.php?title=Stormwater_infiltration_Best_Management_Practices infiltration] / recharge practice, particularly when parent soils have high permeability (> ~ 0.5 inches per hour). Bioretention designed for infiltration (bioinfiltration) removes 100 percent of pollutants for the portion of runoff water that is infiltrated, although there [https://stormwater.pca.state.mn.us/index.php?title=Surface_water_and_groundwater_quality_impacts_from_stormwater_infiltration may be impacts to shallow groundwater]. Bioretention designed as filtration (biofiltration) employs engineered media that is effective at removing solids, most metals, and most organic chemicals. Removal of phosphorus depends on the media ([https://stormwater.pca.state.mn.us/index.php?title=Design_criteria_for_bioretention#Addressing_phosphorus_leaching_concerns_with_media_mixes link here]). Links to water quality information for bioretention - [https://stormwater.pca.state.mn.us/index.php?title=Pollutant_removal_percentages_for_bioretention_BMPs]; [https://stormwater.pca.state.mn.us/index.php?title=Pollutant_concentrations_for_bioretention_BMPs] | + | *[https://stormwater.pca.state.mn.us/index.php?title=Water_quality_benefits_of_Green_Stormwater_Infrastructure '''Water quality''']: Bioretention is an excellent stormwater treatment practice due to the variety of pollutant removal mechanisms, including vegetative filtering, settling, evaporation, infiltration, <span title="The loss of water as vapor from plants at their surfaces, primarily through stomata."> '''transpiration'''</span>, biological and microbiological uptake, and soil adsorption. Bioretention can be designed as an effective [https://stormwater.pca.state.mn.us/index.php?title=Stormwater_infiltration_Best_Management_Practices infiltration] / recharge practice, particularly when parent soils have high permeability (> ~ 0.5 inches per hour). Bioretention designed for infiltration (<span title="A bioretention practice in which no underdrain is used. All water entering the bioinfiltration practice infiltrates or evapotranspires."> '''bioinfiltration'''</span>) removes 100 percent of pollutants for the portion of runoff water that is infiltrated, although there [https://stormwater.pca.state.mn.us/index.php?title=Surface_water_and_groundwater_quality_impacts_from_stormwater_infiltration may be impacts to shallow groundwater]. Bioretention designed as filtration (<span title="A bioretention practice having an underdrain. All water entering the practice is filtered through engineered media and filtered water is returned to the storm sewer system."> [https://stormwater.pca.state.mn.us/index.php?title=Bioretention '''biofiltration''']</span>) employs <span title="Engineered media is a mixture of sand, fines (silt, clay), and organic matter utilized in stormwater practices, most frequently in bioretention practices. The media is typically designed to have a rapid infiltration rate, attenuate pollutants, and allow for plant growth."> [https://stormwater.pca.state.mn.us/index.php?title=Design_criteria_for_bioretention#Materials_specifications_-_filter_media '''engineered media''']</span> that is effective at removing solids, most metals, and most organic chemicals. Removal of phosphorus depends on the media ([https://stormwater.pca.state.mn.us/index.php?title=Design_criteria_for_bioretention#Addressing_phosphorus_leaching_concerns_with_media_mixes link here]). Links to water quality information for bioretention - [https://stormwater.pca.state.mn.us/index.php?title=Pollutant_removal_percentages_for_bioretention_BMPs]; [https://stormwater.pca.state.mn.us/index.php?title=Pollutant_concentrations_for_bioretention_BMPs] |
− | *[https://stormwater.pca.state.mn.us/index.php?title=Water_quantity_and_hydrology_benefits_of_Green_Stormwater_Infrastructure Water quantity and hydrology]: Bioretention can be designed as an effective infiltration / recharge practice when parent soils have high permeability. For lower permeability soils an [https://stormwater.pca.state.mn.us/index.php?title= | + | *[https://stormwater.pca.state.mn.us/index.php?title=Water_quantity_and_hydrology_benefits_of_Green_Stormwater_Infrastructure '''Water quantity and hydrology''']: Bioretention can be designed as an effective infiltration / recharge practice when parent soils have high permeability. For lower permeability soils an <span title="An underground drain or trench with openings through which the water may percolate from the soil or ground above"> '''underdrain'''</span> is typically used and some infiltration and rate control can be achieved. |
− | + | *[https://stormwater.pca.state.mn.us/index.php?title=Climate_benefits_of_Green_Stormwater_Infrastructure '''Climate resiliency''']: It is unclear if bioretention provides benefits for climate resiliency. Carbon may be <span title="to remove or withdraw"> '''sequestered'''</span>, particularly if shrubs and trees exist in the practice. Bioretention also provides some reduction in peak flow. Carbon emissions for construction and maintenance may offset carbon benefits ([https://www.researchgate.net/publication/276100905_Predicting_the_carbon_footprint_of_urban_stormwater_infrastructure Moore and Hunt], 2013). [http://www.ohiowea.org/docs/OWEA_BRC+PP_Winston.pdf Winston (2016)] provides a detailed analysis of resiliency of bioretention systems based on different design considerations, such as bowl depth and vegetation utilized in the practice. | |
− | *Habitat improvement: Properly designed bioretention practices provide good habitat for invertebrates ([https://stormwater.pca.state.mn.us/index.php?title=Green_Infrastructure_benefits_of_bioretention#References Kazemi et al., 2009]; [http://www.sciencedirect.com/science/article/pii/S092585741630516X Mehring et al., 2016]). Beneficial effects are improved considerably when multiple bioretention practices exist over a landscape, as opposed to isolated bioretention practices. | + | *[https://stormwater.pca.state.mn.us/index.php?title=Wildlife_habitat_and_biodiversity_benefits_of_Green_Stormwater_Infrastructure '''Habitat improvement''']: Properly designed bioretention practices provide good habitat for invertebrates ([https://stormwater.pca.state.mn.us/index.php?title=Green_Infrastructure_benefits_of_bioretention#References Kazemi et al., 2009]; [http://www.sciencedirect.com/science/article/pii/S092585741630516X Mehring et al., 2016]). Beneficial effects are improved considerably when multiple bioretention practices exist over a landscape, as opposed to isolated bioretention practices. |
− | *Community livability: Bioretention is an aesthetically pleasing practice that can easily be incorporated into various landscapes. A variety of vegetation can also be used, including perennial plants, shrubs, and trees. | + | *[https://stormwater.pca.state.mn.us/index.php?title=Social_benefits_of_Green_Stormwater_Infrastructure '''Community livability''']: Bioretention is an aesthetically pleasing practice that can easily be incorporated into various landscapes. A variety of vegetation can also be used, including perennial plants, shrubs, and trees. |
− | *Health benefits: Green spaces may also improve mental and physical health for residents and reduce crime ([https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5663018/ Barton and Rogerson], 2017). | + | *[https://stormwater.pca.state.mn.us/index.php?title=Social_benefits_of_Green_Stormwater_Infrastructure '''Health benefits''']: Green spaces may also improve mental and physical health for residents and reduce crime ([https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5663018/ Barton and Rogerson], 2017). |
− | *Economic savings: Properly designed and integrated bioretention practices provide life cycle cost savings. Well designed and maintained bioretention practices increase property values. | + | *[https://stormwater.pca.state.mn.us/index.php?title=Social_benefits_of_Green_Stormwater_Infrastructure '''Economic savings''']: Properly designed and integrated bioretention practices provide life cycle cost savings. Well designed and maintained bioretention practices increase property values. |
[[File:Finished basin with simple groupings of shrubs grasses and trees.png |right|thumb|300 px|alt=This picture shows a finished basin with simple groupings of shrubs grasses and trees|<font size=3>Bioretention practices can be incorporated into a wide variety of landscapes.</font size>]] | [[File:Finished basin with simple groupings of shrubs grasses and trees.png |right|thumb|300 px|alt=This picture shows a finished basin with simple groupings of shrubs grasses and trees|<font size=3>Bioretention practices can be incorporated into a wide variety of landscapes.</font size>]] | ||
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==Design considerations== | ==Design considerations== | ||
Maximizing specific green infrastructure (GI) benefits of bioretention practices requires design considerations prior to constructing the practice. While site limitations cannot always be overcome, the following recommendations maximize the GI benefit of bioretetnion. | Maximizing specific green infrastructure (GI) benefits of bioretention practices requires design considerations prior to constructing the practice. While site limitations cannot always be overcome, the following recommendations maximize the GI benefit of bioretetnion. | ||
+ | |||
+ | {{alert|The following discussion focuses on design considerations. All benefits delivered by the practice require appropriate construction, operation, and maintenance of the practice. O&M considerations should be included during the design phase of a project. For information on O&M for GSI practices, see [[Operation and maintenance of green stormwater infrastructure best management practices]]|alert-warning}} | ||
+ | |||
*Water quality | *Water quality | ||
**Maximize infiltration by designing with the maximum ponded depth that can be infiltrated in 48 hours, up to 1.5 feet (to protect vegetation). Where space allows, surface area can also be increased. Utilize multiple bioretention practices in series. On lower permeability soils where an underdrain is used, raise the underdrain to the maximum extent possible, allowing water stored in the bioretention media below the underdrain to drain in 48 hours. Use an upturned elbow in underdrained systems. | **Maximize infiltration by designing with the maximum ponded depth that can be infiltrated in 48 hours, up to 1.5 feet (to protect vegetation). Where space allows, surface area can also be increased. Utilize multiple bioretention practices in series. On lower permeability soils where an underdrain is used, raise the underdrain to the maximum extent possible, allowing water stored in the bioretention media below the underdrain to drain in 48 hours. Use an upturned elbow in underdrained systems. | ||
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*Water quantity/supply | *Water quantity/supply | ||
**Maximize infiltration | **Maximize infiltration | ||
− | **Utilize [ | + | **Utilize [https://epa.ohio.gov/static/Portals/41/storm_workshop/lid/IWS.Dec10.pdf internal water storage] |
**Maximize water storage in media | **Maximize water storage in media | ||
*Climate resiliency | *Climate resiliency | ||
**To reduce heat island effects, select vegetation that reflects solar energy, absorbs solar energy and releases it slowly, or that maximizes evapotranspiration [http://www1.nyc.gov/assets/orr/images/content/header/ORR_ClimateResiliencyDesignGuidelines_PRELIMINARY_4_21_2017.pdf NYC Mayor’s Office of Recovery and Resiliency] | **To reduce heat island effects, select vegetation that reflects solar energy, absorbs solar energy and releases it slowly, or that maximizes evapotranspiration [http://www1.nyc.gov/assets/orr/images/content/header/ORR_ClimateResiliencyDesignGuidelines_PRELIMINARY_4_21_2017.pdf NYC Mayor’s Office of Recovery and Resiliency] | ||
− | **Oversize bowl depth (storage) to account for increased precipitation. | + | **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 ( | + | **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 [ | + | **Utilize [https://epa.ohio.gov/static/Portals/41/storm_workshop/lid/IWS.Dec10.pdf internal water storage] |
*Habitat | *Habitat | ||
**Utilize native, perennial vegetation, including shrubs and trees if space allows. For more information, see [[Minnesota plant lists]]. | **Utilize native, perennial vegetation, including shrubs and trees if space allows. For more information, see [[Minnesota plant lists]]. | ||
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**Choose the correct BMP. There is no comprehensive guidance on this, but an important factor in selecting BMPs is cost per unit treatment. This depends on the goal of the project, but examples of costs may be dollars per cubic foot of water treated or per pound of pollutant. Barr Engineering [https://www.pca.state.mn.us/sites/default/files/p-gen3-13x.pdf completed a report] that provides information on construction costs, maintenance costs, and land requirements for several stormwater BMPs. The report includes references to other useful reports. Information in the report can be used to match the site goals (e.g. infiltration vs. filtration) and site conditions (e.g. large vs. small site) to the most cost-efficient BMP. | **Choose the correct BMP. There is no comprehensive guidance on this, but an important factor in selecting BMPs is cost per unit treatment. This depends on the goal of the project, but examples of costs may be dollars per cubic foot of water treated or per pound of pollutant. Barr Engineering [https://www.pca.state.mn.us/sites/default/files/p-gen3-13x.pdf completed a report] that provides information on construction costs, maintenance costs, and land requirements for several stormwater BMPs. The report includes references to other useful reports. Information in the report can be used to match the site goals (e.g. infiltration vs. filtration) and site conditions (e.g. large vs. small site) to the most cost-efficient BMP. | ||
**Factor in all benefits in evaluating the economic value of a BMP or multiple GI practices. For example, appropriate implementation of GI practices can enhance property values. Proper selection of vegetation provides energy savings. Utilizing captured rainwater as an indoor non-potable water source provides savings on energy and water use. | **Factor in all benefits in evaluating the economic value of a BMP or multiple GI practices. For example, appropriate implementation of GI practices can enhance property values. Proper selection of vegetation provides energy savings. Utilizing captured rainwater as an indoor non-potable water source provides savings on energy and water use. | ||
− | **Utilize multiple properly placed BMPs that work together. For example, permeable pavement can be integrated with | + | **Utilize multiple properly placed BMPs that work together. For example, permeable pavement can be integrated with bioretention practices to provide an aesthetically pleasing landscape that increases the value of the property while increasing the efficiency of stormwater treatment. |
==Recommended reading== | ==Recommended reading== | ||
+ | *[https://www.risc.solutions/wp-content/uploads/2021/08/Design-Guide-for-Green-Infrastructure-BMPs-RISC-Report-August-2021.pdf A Design Guide for Green Stormwater Infrastructure Best Management Practices]. Jack Eskin, Tom Price, Jason Cooper, William Schleizer; 2014. | ||
*[http://www.countyhealthrankings.org/policies/rain-gardens-other-bioretention-systems Rain gardens & other bioretention systems], County Health rankings | *[http://www.countyhealthrankings.org/policies/rain-gardens-other-bioretention-systems Rain gardens & other bioretention systems], County Health rankings | ||
*Meeting Hydrologic and Water Quality Goals through Targeted Bioretention Design. Journal of Environmental Engineering/Volume 138 Issue 6 - June 2012. William F. Hunt, M., Allen P. Davis, and Robert G. Traver | *Meeting Hydrologic and Water Quality Goals through Targeted Bioretention Design. Journal of Environmental Engineering/Volume 138 Issue 6 - June 2012. William F. Hunt, M., Allen P. Davis, and Robert G. Traver | ||
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==References== | ==References== | ||
*Adger, W. Neil. 2006. [https://www.geos.ed.ac.uk/~nabo/meetings/glthec/materials/simpson/GEC_sdarticle2.pdf Vulnerability]. Global Environmental Change 16:268–281. | *Adger, W. Neil. 2006. [https://www.geos.ed.ac.uk/~nabo/meetings/glthec/materials/simpson/GEC_sdarticle2.pdf Vulnerability]. Global Environmental Change 16:268–281. | ||
− | *Barton, S. 2009. [ | + | *Barton, S. 2009. [https://www.udel.edu/academics/colleges/canr/cooperative-extension/fact-sheets/human-benefits-of-green-spaces/ Human benefits of green spaces]. University of Delaware Bulletin #137. 2009. |
*Folke C. 2006. [http://www.sciencedirect.com/science/article/pii/S0959378006000379 Resilience: the emergence of a perspective for social–ecological systems analyses]. Global Environ Change. 16:253–267. | *Folke C. 2006. [http://www.sciencedirect.com/science/article/pii/S0959378006000379 Resilience: the emergence of a perspective for social–ecological systems analyses]. Global Environ Change. 16:253–267. | ||
*Kazemi, F., S. Beecham, J. Gibbs, and R. Clay. 2009. [http://www.sciencedirect.com/science/article/pii/S0169204609001029 Factors affecting terrestrial invertebrate diversity in bioretention basins in an Australian urban environment]. Landscape and Urban Planning. Vol. 92:3-4:304-313. | *Kazemi, F., S. Beecham, J. Gibbs, and R. Clay. 2009. [http://www.sciencedirect.com/science/article/pii/S0169204609001029 Factors affecting terrestrial invertebrate diversity in bioretention basins in an Australian urban environment]. Landscape and Urban Planning. Vol. 92:3-4:304-313. | ||
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*Moore, T., and W.F. Hunt. 2013. [http://www.sciencedirect.com/science/article/pii/S092585741300222X Predicting the carbon footprint of urban stormwater infrastructure]. Ecological Engineering. Volume 58, September 2013, Pages 44-51. | *Moore, T., and W.F. Hunt. 2013. [http://www.sciencedirect.com/science/article/pii/S092585741300222X Predicting the carbon footprint of urban stormwater infrastructure]. Ecological Engineering. Volume 58, September 2013, Pages 44-51. | ||
*New York City Mayor’s Office of Recovery and Resiliency. 2017. [http://www1.nyc.gov/assets/orr/images/content/header/ORR_ClimateResiliencyDesignGuidelines_PRELIMINARY_4_21_2017.pdf Preliminary Climate Resiliency Design Guidelines]. | *New York City Mayor’s Office of Recovery and Resiliency. 2017. [http://www1.nyc.gov/assets/orr/images/content/header/ORR_ClimateResiliencyDesignGuidelines_PRELIMINARY_4_21_2017.pdf Preliminary Climate Resiliency Design Guidelines]. | ||
+ | *Winston, Ryan J., Jay D Dorsey, William F Hunt. 2016. Quantifying volume reduction and peak flow mitigation for three bioretention cells in clay soils in northeast Ohio. Sci Total Environ. 553:83-95. doi: 10.1016/j.scitotenv.2016.02.081. | ||
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+ | |||
+ | <noinclude> | ||
+ | [[Category:Level 3 - Best management practices/Structural practices/Bioretention]] | ||
+ | [[Category:Level 2 - Management/Green infrastructure]] | ||
+ | </noinclude> |
Bioretention practices, often called rain gardens, are small vegetated landscape practices designed to filter or infiltrate stormwater runoff. They have a relatively simplistic design that can be incorporated into a wide variety of landscaped areas. Common bioretention opportunities include landscaping islands, cul-de-sacs, parking lot margins, commercial setbacks, open space, rooftop drainage and street-scapes (i.e., between the curb and sidewalk).
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 for 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 | Benefits are maximized for bioinfiltration. Biofiltration may export phosphorus if not designed properly. | |
Water quantity/supply | Bioinfiltration helps mimic natural hydrology. Some rate control benefit. | |
Energy savings | ||
Climate resiliency | Provides some rate control. Impacts on carbon sequestration are uncertain. | |
Air quality | ||
Habitat improvement | Use of perennial vegetation and certain media mixes promote invertebrate communities. | |
Community livability | 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 | Individual bioretention practices are typically microscale, but multiple bioretention practices, when incorporated into a landscape design, provide macroscale benefits such as wildlife corridors. | |
Level of benefit: ◯ - none; ◔; - small; ◑ - moderate; ◕ - large; ● - very high |
Because of their diversity and use of vegetation, bioretention practices provide multiple green infrastructure benefits.
Maximizing specific green infrastructure (GI) benefits of bioretention practices requires design considerations prior to constructing the practice. While site limitations cannot always be overcome, the following recommendations maximize the GI benefit of bioretetnion.
This page was last edited on 26 January 2023, at 10:35.