Phosphorus Removal, Metals Dynamics, and Hydraulics in Stormwater Bioretention Systems Amended with Drinking Water Treatment Residuals


TitlePhosphorus Removal, Metals Dynamics, and Hydraulics in Stormwater Bioretention Systems Amended with Drinking Water Treatment Residuals
Publication TypeJournal Article
Year of Publication2022
AuthorsAment, MR, Roy, ED, Yuan, Y, Hurley, SE
JournalJournal of Sustainable Water in the Built Environment
Volume8
Issue3
Date Published2022/08
KeywordsDrinking water treatment, Field tests, Heavy metals, Hydraulics, Nutrient pollution, phosphorus, Retention basins, Stormwater management
Abstract

Drinking water treatment residuals (DWTRs) are a promising media amendment for enhancing phosphorus (P) removal in bioretention systems, but substantial removal of dissolved P by DWTRs has not been demonstrated in field bioretention experiments. We investigated the capacity of a nonamended control media (control) and a DWTR-amended treatment media (DWTR) to remove soluble reactive P (SRP), dissolved organic P (DOP), particulate P (PP), and total P (TP) from stormwater in a 2-year roadside bioretention experiment. Significant reductions in SRP, PP, and TP concentrations and loads were observed in both the control and DWTR media. However, the P removal efficiency of the DWTR cells was greater than those of the control cells for all P species, particularly during the second monitoring season because P sorption complexes likely began to saturate in the control cells. The difference in P removal efficiency between the control and DWTR cells was greatest during large storm events, which transported the majority of dissolved P loads in this study. We also investigated the potential for DWTRs to restrict water flow through bioretention media or leach heavy metals. The DWTRs used in this study did not affect the hydraulic performance of the bioretention cells and no significant evidence of heavy-metal leaching was observed during the study period. Contrasting these results with past studies highlights the importance of media design in bioretention system performance and suggests that DWTRs can effectively capture and retain P without affecting system hydraulics if properly incorporated into bioretention media

URLhttps://ascelibrary.org/doi/10.1061/JSWBAY.0000980
DOI10.1061/JSWBAY.0000980
Short TitleJ. Sustainable Water Built Environ.
Refereed DesignationRefereed
Status: 
Published
Attributable Grant: 
BREE
Grant Year: 
Year7
Acknowledged VT EPSCoR: 
Ack-No