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Line 142: − [[File:Screenshot 2025-09-22 113355.png|600px|thumb|right|Peak flow reductions of different LID types during frequent rain events. Top left: Grey and green roof at York University; bottom left: permeable pavement, bioretention and asphalt at Seneca College; right: Kortright permeable pavement and asphalt.]] − Line 254:
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→Case Studies
Flood mitigation strategies that incorporate Low Impact Development (LID), traditional stormwater management, and hybrid infrastructure can manage stormwater effectively and reduce flood impacts.
Flood mitigation strategies that incorporate Low Impact Development (LID), traditional stormwater management, and hybrid infrastructure can manage stormwater effectively and reduce flood impacts.
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==Types of flooding==
==Types of flooding==
! Pluvial (surface) flooding
! Pluvial (surface) flooding
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[[File:Reflecting-on-the-devastating-2013-storm-mississauga-takes-lead-in-municipal-flood-resilience-the-pointer-be39ea9b.jpg|300px|thumb|right|Street flooding in Mississauga (The Pointer, 2023)<ref>The Pointer. 2013. Reflecting on the devastating 2013 storm, Mississauga takes lead in municipal flood resilience. https://thepointer.com/article/2023-07-30/reflecting-on-the-devastating-2013-storm-mississauga-takes-lead-in-municipal-flood-resilience</ref>.]]
[[File:Reflecting-on-the-devastating-2013-storm-mississauga-takes-lead-in-municipal-flood-resilience-the-pointer-be39ea9b.jpg|400px|frameless|center]] Street flooding in Mississauga (The Pointer, 2023)<ref>The Pointer. 2013. Reflecting on the devastating 2013 storm, Mississauga takes lead in municipal flood resilience. https://thepointer.com/article/2023-07-30/reflecting-on-the-devastating-2013-storm-mississauga-takes-lead-in-municipal-flood-resilience</ref>.
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* Caused by intense rainfall that exceeds soil infiltration and storm sewer capacity, especially in urban areas with impervious surfaces.
* Caused by intense rainfall that exceeds soil infiltration and storm sewer capacity, especially in urban areas with impervious surfaces.
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! Fluvial (riverine) flooding
! Fluvial (riverine) flooding
| [[File:Screenshot 2025-09-22 100405.png|300px|thumb|right|Don River floods DVP (City News, 2024)<ref>City News. 2024. From the scene: Don Valley River floods section of DVP, stranding drivers. https://www.youtube.com/watch?v=fbyaYZy0d0A&t=68s</ref>]]
| [[File:Screenshot 2025-09-22 100405.png|400px|frameless|center]]Don River floods DVP (City News, 2024)<ref>City News. 2024. From the scene: Don Valley River floods section of DVP, stranding drivers. https://www.youtube.com/watch?v=fbyaYZy0d0A&t=68s</ref>.
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* Occurs when rivers exceed their capacity due to heavy rain or snowmelt, resulting in water overtopping the banks and flowing into adjacent areas.
* Occurs when rivers exceed their capacity due to heavy rain or snowmelt, resulting in water overtopping the banks and flowing into adjacent areas.
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! Coastal (shoreline) flooding
! Coastal (shoreline) flooding
|[[File:Screenshot 2025-09-19 115121.png|300px|thumb|right|Lake Ontario floods Toronto Island (Toronto Life, 2017)<ref>Toronto Life. 2017. Flooding on the Toronto Islands is terrible—but also weirdly beautiful. https://torontolife.com/life/flooding-toronto-islands-terrible-also-weirdly-beautiful/</ref>]]
|[[File:Screenshot 2025-09-19 115121.png|400px|frameless|center]]Lake Ontario floods Toronto Island (Toronto Life, 2017)<ref>Toronto Life. 2017. Flooding on the Toronto Islands is terrible—but also weirdly beautiful. https://torontolife.com/life/flooding-toronto-islands-terrible-also-weirdly-beautiful/</ref>.
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* Driven by storm surges and lake-level rise due to storm surges or seiches.
* Driven by storm surges and lake-level rise due to storm surges or seiches.
==Mitigative strategies==
==Mitigative strategies==
[[File:Western beaches storage tunnel.jpg|300px|thumb|right|The 4km long West Beaches Storage Tunnel in Toronto stores and treats combined sewer overflows and stormwater to prevent untreated sewage from entering Lake Ontario. It is a grey infrastructure solution which helps prevent localized flooding by collecting and storing water and uses [[sedimentation]] and UV disinfection to improve water quality (McNally, 2017) <ref>McNally. 2017. Western Beaches Tunnel – Toronto, ON. http://mcnally.ca/tunneling-projects/western-beaches-tunnel-toronto/#:~:text=Project%20Outline,pump%20station%20at%20Strachan%20Avenue.</ref>.]]
[[File:Western beaches storage tunnel.jpg|400px|thumb|right|The 4km long West Beaches Storage Tunnel in Toronto stores and treats combined sewer overflows and stormwater to prevent untreated sewage from entering Lake Ontario. It is a grey infrastructure solution which helps prevent localized flooding by collecting and storing water and uses [[sedimentation]] and UV disinfection to improve water quality (McNally, 2017) <ref>McNally. 2017. Western Beaches Tunnel – Toronto, ON. http://mcnally.ca/tunneling-projects/western-beaches-tunnel-toronto/#:~:text=Project%20Outline,pump%20station%20at%20Strachan%20Avenue.</ref>.]]
[[File:FEMA P-259 Engineering Principles and Practices for Retrofitting Flood-Prone Residential Structures Structure protected by levee and floodwall 520px (1).png|300px|thumb|right|Floodwall and levee protects building from flood water (Reduce Flood Risk, 2022)<ref>Reduce Flood Risk. 2022. Construct a floodwall barrier. https://www.reducefloodrisk.org/mitigation/construct-a-floodwall-barrier/</ref>.]]
[[File:FEMA P-259 Engineering Principles and Practices for Retrofitting Flood-Prone Residential Structures Structure protected by levee and floodwall 520px (1).png|400px|thumb|right|Floodwall and levee protects building from flood water (Reduce Flood Risk, 2022)<ref>Reduce Flood Risk. 2022. Construct a floodwall barrier. https://www.reducefloodrisk.org/mitigation/construct-a-floodwall-barrier/</ref>.]]
Effective flood mitigation strategies fall into three categories: grey infrastructure (traditional engineered solutions), green infrastructure (nature-based solutions), and grey-green hybrids. Cities typically combine measures based on local flood risks, scale, and desired co-benefits such as water quality improvement and urban cooling.
Effective flood mitigation strategies fall into three categories: grey infrastructure (traditional engineered solutions), green infrastructure (nature-based solutions), and grey-green hybrids. Cities typically combine measures based on local flood risks, scale, and desired co-benefits such as water quality improvement and urban cooling.
===Hybrid approaches===
===Hybrid approaches===
[[File:Corktown3-2048x-q60.jpg|450px|thumb|right|Corktown Common in Toronto is a levee designed with sustainable stormwater management, recreation, and biodiversity in mind. The previous brownfield site was a gateway for Don River floodwaters that put 500 acres of the city at risk. A series of trails lined with native vegetative, playground, and splash pad and were built on top of the 13 foot clay levee. A marsh was constructed on the west side of the levee which collects rainwater for park irrigation, conserving up to 145,000 gallons per day (Michael Van Valkenburgh Associates Inc, ND)<ref>Michael Van Valkenburgh Associates Inc. ND. Corktown Common. https://www.mvvainc.com/projects/corktown-common </ref>.]]
[[File:Corktown3-2048x-q60.jpg|400px|thumb|right|Corktown Common in Toronto is a levee designed with sustainable stormwater management, recreation, and biodiversity in mind. The previous brownfield site was a gateway for Don River floodwaters that put 500 acres of the city at risk. A series of trails lined with native vegetative, playground, and splash pad and were built on top of the 13 foot clay levee. A marsh was constructed on the west side of the levee which collects rainwater for park irrigation, conserving up to 145,000 gallons per day (Michael Van Valkenburgh Associates Inc, ND)<ref>Michael Van Valkenburgh Associates Inc. ND. Corktown Common. https://www.mvvainc.com/projects/corktown-common </ref>.]]
Combining green and grey infrastructure enhances flood resilience. Examples include:
Combining green and grey infrastructure enhances flood resilience. Examples include:
==Modelling Flood Mitigation Potential of Conventional LIDs==
==Modelling Flood Mitigation Potential of Conventional LIDs==
[[File:Screenshot 2025-09-22 113355.png|700px|thumb|right|Peak flow reductions of different LID types during frequent rain events. Top left: Grey and green roof at York University; bottom left: permeable pavement, bioretention and asphalt at Seneca College; right: Kortright permeable pavement and asphalt.]]
TRCA conducted [[modeling]] to evaluate the capacity of different stormwater management measures (LID and Ponds) to mitigate impacts of development on the peak flow and runoff volume. A sub-catchment in Humber River was selected that has an area of 35.7 ha. The existing land use in the sub-catchment is agriculture and the proposed future land use is employment land with 91% total imperviousness.
TRCA conducted [[modeling]] to evaluate the capacity of different stormwater management measures (LID and Ponds) to mitigate impacts of development on the peak flow and runoff volume. A sub-catchment in Humber River was selected that has an area of 35.7 ha. The existing land use in the sub-catchment is agriculture and the proposed future land use is employment land with 91% total imperviousness.
===Peak Flow===
===Peak Flow===
*The 25 mm on-site retention using LID measures reduced post-development peak flows generated from 2 to 5 year design storms by over 26%,
*The 25 mm on-site retention using LID measures reduced post-development peak flows generated from 2 to 5 year design storms by over 26%,
*For 50 and 100 year design storms it reduces only 4% and 1% respectively.
*For 50 and 100 year design storms it reduces only 4% and 1% respectively.
===Example 4. [https://sustainabletechnologies.ca/app/uploads/2020/12/SmartBlueRoofSTEPTechBrief_Dec2020.pdf Smart Blue Roof System at CVC Head Office]===
===Example 4. [https://sustainabletechnologies.ca/app/uploads/2020/12/SmartBlueRoofSTEPTechBrief_Dec2020.pdf Smart Blue Roof System at CVC Head Office]===
[[File:Blue roof schematic.png|400px|thumb|right|Smart blue roof schematic (City of Missisauga, 2024)<ref>City of Mississauga. 2024. Mississauga is home to Canada’s first CSA-compliant smart blue roof.https://www.mississauga.ca/city-of-mississauga-news/news/mississauga-is-home-to-canadas-first-csa-compliant-smart-blue-roof/</ref>]]
[[File:Screenshot 2025-11-14 140403.png|400px|thumb|right|Glendale Public School rain garden (STEP, 2020)<ref name = Glen>STEP. 2020. Glendale Public School Rain Garden: Design and Build Overview. https://sustainabletechnologies.ca/app/uploads/2020/09/CVC-Glendale-Rain-Garden-Case-Study.pdf.</ref>.]]
[[File:Screenshot 2025-11-14 140956.png|400px|thumb|right|Glendale Public School rain garden study area (STEP, 2020)<ref name = Glen></ref>.]]
Glendale Public School area in Brampton faced increased urbanization, limited stormwater controls, and on-site drainage issues that were harming aquatic health in nearby Fletchers Creek, particularly the endangered Redside Dace. To address these concerns, CVC designed a large-scale rain garden using a treatment-train approach, incorporating three swales, conveyance pipes, an underdrain system, and a flow-control valve.
[[Blue roofs]] are emerging as an innovative rooftop stormwater management solution that provides flood protection and drought resistance. Instead of quickly conveying stormwater away from a property, blue roof systems temporarily capture rainwater until it either evaporates from the rooftop or is sent to rainwater harvesting storage tanks. A [https://sourcetostream.com/2024-track-1-day-1-cowan/ Smart Blue Roof was piloted at the CVC head office in Mississauga]. Smart roofs are fitted with weather forecasting algorithms via internet connectivity and automated valves to regulate water discharge from the roof.
[[Blue roofs]] are emerging as an innovative rooftop stormwater management solution that provides flood protection and drought resistance. Instead of quickly conveying stormwater away from a property, blue roof systems temporarily capture rainwater until it either evaporates from the rooftop or is sent to rainwater harvesting storage tanks. A [https://sourcetostream.com/2024-track-1-day-1-cowan/ Smart Blue Roof was piloted at the CVC head office in Mississauga]. Smart roofs are fitted with weather forecasting algorithms via internet connectivity and automated valves to regulate water discharge from the roof.