Establishing sequential managed aquifer recharge technology (SMART) for enhanced removal of trace organic chemicals: Experiences from field studies in Berlin, Germany

• Published in: Journal of hydrology (Amsterdam) Vol. 563; pp. 1161 - 1168
• Main Authors: Hellauer, Karin, Karakurt, Sema, Sperlich, Alexander, Burke, Victoria, Massmann, Gudrun, Hübner, Uwe, Drewes, Jörg E.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.08.2018
• Subjects: Dissolved organic carbon; Groundwater recharge; Redox conditions; Sequential managed aquifer recharge; Trace organic chemicals; Dissolved organic carbon; Redox conditions; Groundwater recharge; Sequential managed aquifer recharge; Trace organic chemicals
• ISSN: 0022-1694; 1879-2707
• DOI: 10.1016/j.jhydrol.2017.09.044

•Sequential managed aquifer recharge technology (SMART) validated at field-scale.•More stable oxic and carbon-limited conditions in SMART compared to conventional MAR.•Enhanced removal of several biodegradable trace organic chemicals in SMART. Despite the efficient removal of many contaminants including pathogens and trace organic chemicals (TOrCs) during managed aquifer recharge (MAR), fate and transport of TOrCs in the subsurface might not always occur under conditions that favor effective biotransformation resulting in a contamination risk where water is recovered for drinking water production. A promising technology that can lead to improved removal of TOrCs is the sequential MAR technology (SMART), which combines two infiltration steps with an intermediate aeration to establish more favorable oxic and carbon-limited conditions resulting in enhanced TOrCs transformation. The aim of this study was to test the performance of the SMART concept under field conditions in comparison to a conventional MAR using pond infiltration (cMAR) operated in Berlin, Germany. Although oxic conditions were obtained at both field sites considering infiltration depth to 200 cm, redox conditions were more stable at the SMART facility fed with bank filtrate. In addition, carbon-limited conditions were solely observed during SMART. Chemicals known to persist during MAR, including candesartan, carbamazepine, dihydroxydihydrocarbamazepine, olmesartan, oxypurinol, phenylethylmalonamide, primidone, and tolyltriazole exhibited a refractory behavior at both field sites, whereas valsartan acid, metformin, and gabapentin-lactam were removed by more than 85% during 200 cm of infiltration. 4-Formylaminoantipyrine, acesulfame, benzotriazole, and gabapentin exhibited a significantly enhanced transformation during SMART compared to the cMAR site. These results confirm that SMART can result in controlled oxic and carbon-depleted subsurface conditions during MAR facilitating an improved transformation of moderately degradable TOrCs by natural treatment processes.