Abstract
Microbial pollution in stormwater is a concern in urban areas across the U.S. and is a leading cause of water-quality impairment in the United States. This issue may be addressed through the use of best management practices (BMPs) and target limits for pathogenic indicator species. Bioretention is a commonly used low impact development strategy that addresses this growing pollution problem at the source. Bioretention removal efficiencies have been well studied when considering nutrients and heavy metals, but field-scale treatment data are limited for microbial indicators. The primary objective of this study was to quantify microbial removal by installed bioretention cells with fly-ash amended soils. Three bioretention cells in Grove, Oklahoma were monitored over one and a half years and the removal microbial efficiency was quantified. Overall, removal rates for E. coli, enterococci, and coliphage were highly variable, with mean and standard deviations for removals for each site respectively: E. coli 87%, 35%, and 43%; enterococci 97%, 95%, and 80%; and coliphage 38%, 75%, and 32%. The site with negative removal efficiency appears to have some groundwater intrusion during storm events. Based on this relatively limited data set, these fly-ash amended bioretention cells performed 49% better than those with a sand-only filter media layer currently reported in the literature. Based on this initial field study, it appears that fly-ash amended bioretention cells may be a viable option for enhanced microbial removal from stormwater runoff.
Highlights
Stormwater is a major contributor to microbial pollution in urban areas
Elm Creek Plaza (ECP) had a total of 23 storm events captured with 20 events with paired data from the inlet and outlet
Twelve of the fourteen captured storm events were paired for the Grand Lake Association (GLA) cell, and the high school (GHS) cell had six of the sixteen storm events with paired data
Summary
Stormwater is a major contributor to microbial pollution in urban areas. The use of bioretention cells is a new mechanism that has improved water quality parameters, such as nutrients and heavy metals. There is minimal research as to the impact of bioretention for bacteria and virus removal. The current literature exhibits a need for additional studies of microbial removal by bioretention. This study quantifies microbial removal by bioretention cells with and without a fly-ash amendment. Previous laboratory column studies have shown potential in increasing removal capacity of filter media when amended with iron-oxides [1,2]. The data from this study will provide a greater understanding of the benefits of bioretention with respect to microbes
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