Runoff Reduction Benefits of Retrofitted Enhanced or Extended-Depressed Tree Pits of the Beasley and Landsdale Neighbourhoods in Hamilton, Ontario

Rawlins, Robert

January 2019

This research explores the potential of retrofitting enhanced or extended-depressed tree pits (ETPs/EDTPs) around existing street trees to bolster pre-development hydrological processes in two Hamiltonian neighbourhoods to help satisfy their social, economic, and environmental needs and work toward the Sustainable Development Goals (SDGs). Using QGIS and openly available data to create catchment areas, establish the feasibility of a 20:1 catchment to pit area ratio, and investigate the performance of five available structured soil cells, the innovative Analytical Probabilistic Model (APM) for Bioretention systems was adapted to conduct a parametric sensitivity analysis and subsequently compute the Road Runoff Reduction Efficiency (RRRE) of the designs under different climatic scenarios. The catchment to pit area ratio, design storage depth, and final infiltration rate were found to have a significant impact on the RRRE while the average evapotranspiration rate did not. Based on a 75% efficiency cut-off, and assuming a 20:1 catchment to pit area ratio, the shallowest two depths were deemed ineffective in all final infiltration rate scenarios while the largest depth provided efficiencies greater than 75% runoff reduction even when faced with the lowest rate of 6 mm hr-1. Comparing the RRRE during current climatic conditions to a simulated 2050s winter suggests that the RRRE of the deepest implementation is impacted only half as much as the shallowest; larger systems are more resilient. This research has reinforced the versatility and efficiency of the Analytical Probabilistic Model for modeling system performance of LIDs and ETPs, supports the prominent findings of the efficacy of enhanced tree pits to significantly contribute to urban stormwater management and re-establish more natural and sustainable hydrologic processes, and promotes them as a key to reaching the SDGs in Hamilton, Ontario. / Thesis / Master of Applied Science (MASc) / The Sustainable Development Goals call for action from every member of society. This research explores the potential Stormwater Management Engineers have to do so by retrofitting street trees with Enhanced or Extended-Depressed Tree Pits, increasing rooting volume and offering the tree more water from the adjacent road to simultaneously meet the natural needs of the tree and reduce urban runoff.

Extended Tree Pits

Enhanced Tree Pits

Climate Change

Sustainable Stormwater Management

Natural Infrastructure

Nature-Based Engineering

Sustainable Development Goals

Low Impact Development

Resilient Infrastructure