| [[File:Geothermal cooling exchange system.PNG|thumb|600px|A simplified 3D cross section of a geothermal cooling system used in a SWM pond in Brampton, Ontario. The system contains a closed hydronic circuit where piping connected a surface water heat exchanger (SHX) to a ground heat exchanger (GHX). A pump continuously circulates a cool hydronic fluid around the circuit. The SHX (placed in the path of the pond outflow) has the water pass through it. The hydronic fluid circulating through the SHX is cooler than warm stormwater outflows. This temperature difference forces heat energy from the stormwater into the hydronic fluid, thus cooling the stormwater leaving the pond. Read more about the system [https://www.chijournal.org/C483 Here]. Photo Source: (Janssen and Van Seters,2022.)<ref>Janssen, E. and Van Seters, T. 2022. Thermal Mitigation of Stormwater Management Pond Outflows Using Geothermal Cooling. Journal of Water Management Modeling. https://www.chijournal.org/Content/Files/C483.pdf</ref>]] | | [[File:Geothermal cooling exchange system.PNG|thumb|660px|A simplified 3D cross section of a geothermal cooling system used in a SWM pond in Brampton, Ontario. The system contains a closed hydronic circuit where piping connected a surface water heat exchanger (SHX) to a ground heat exchanger (GHX). A pump continuously circulates a cool hydronic fluid around the circuit. The SHX (placed in the path of the pond outflow) has the water pass through it. The hydronic fluid circulating through the SHX is cooler than warm stormwater outflows. This temperature difference forces heat energy from the stormwater into the hydronic fluid, thus cooling the stormwater leaving the pond. Read more about the system [https://www.chijournal.org/C483 Here]. Photo Source: (Janssen and Van Seters,2022.)<ref>Janssen, E. and Van Seters, T. 2022. Thermal Mitigation of Stormwater Management Pond Outflows Using Geothermal Cooling. Journal of Water Management Modeling. https://www.chijournal.org/Content/Files/C483.pdf</ref>]] |