Abstract
Abstract Extreme weather and the proliferation of impervious areas in urban watersheds increases the frequency of flood events and deepens water quality concerns. Bioretention is a type of green infrastructure practice developed to mitigate these impacts by reducing peak flows, runoff volume, and nutrient loads in stormwater. However, studies have shown inconsistency in the ability of bioretention to manage some pollutants, particularly some forms of nitrogen. Innovative sensor and control technologies are being tested to actively manage urban stormwater, primarily in open water stormwater systems such as wet ponds. Through these cyber-physical controls, it may be possible to optimize storage time and/or soil moisture dynamics within bioretention cells to create more favorable conditions for water quality improvements. A column study testing the influence of active control on bioretention system performance was conducted over a 9-week period. Active control columns were regulated based on either maintaining a specific water level or soil moisture content and were compared to free draining (FD) and internal water storage standards. Actively controlled bioretention columns performed similarly, with the soil moisture-based control showing the best performance with over 86% removal of metals and total suspended solids (TSS) while also exhibiting the highest ammonium removal (43%) and second highest nitrate removal (74%). While all column types showed mostly similar TSS and metal removal trends (median 94 and 98%, respectively), traditionally FD and internal water storage configurations promoted aerobic and anaerobic processes, respectively, which suggests that actively controlled systems have greater potential for targeting both processes. The results suggest that active controls can improve upon standard bioretention designs, but further optimization is required to balance the water quality benefits gained by retention time against storage needs for impending storms.
Highlights
Degradation of urban waterways has caused poor water quality and a decline in ecosystem services worldwide
Soil moisture readings collected throughout this study were taken at 30 and 60 centimeters below the surface of the bioretention media
We hypothesize that active controls will be able to meet these multiple objectives more effectively than static systems. This column study tested the use of active control systems, as compared to static designs, over a 9-week period by observing water quality improvements provided by each treatment
Summary
Degradation of urban waterways has caused poor water quality and a decline in ecosystem services worldwide. Stormwater is one major source of impairment for urban systems, leading watershed managers to seek mitigation strategies (USEPA 2016). The use of green infrastructure (a principal component of Water Sensitive Urban Design) has become more prevalent for treating stormwater. Bioretention practices have shown the ability to significantly reduce nutrient, metal, and pathogenic bacteria concentrations in urban runoff. (Henderson et al 2007; Hunt et al 2008; Hatt et al 2009; Hathaway & Hunt 2012)
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