Constructed wetland coupled microbial fuel cell (CW-MFC) with Phragmites australis planted for hexavalent chromium removal and electricity generation

Hexavalent chromium (Cr(VI)) in aqueous solution is characterized by strong mobility, high solubility, and significant biological toxicity. In this study, four constructed wetland combined with microbial fuel cell (CW-MFC) systems were established to explore the changes in electricity generation, water purification, and microbial community structure under the influence of plant, bioelectrochemical, and Cr(VI) stress. The planted CW-MFC (total Cr: 97.5 %, Cr(VI): 99.2 %) and non-planted CW-MFC (total Cr: 95.3 %, Cr(VI): 97.3 %) showed significantly higher Cr removal efficiency than open circuit CW-MFC (total Cr: 86.9 %, Cr(VI): 84.8 %). The presence of plants and Cr(VI) increased the average voltage and power density of CW-MFC. Additionally, plants, bioelectrochemistry, and Cr(VI) improved COD removal and significantly enhanced the abundance and diversity of microorganisms in the system during long-term domestication. The Cr(VI)-reducing bacterium Exiguobacterium was least abundant in non-Cr(VI) containing CW-MFC system. The abundance of the electrochemically active bacteria (EAB) Geobacter increased under bioelectrochemistry and Cr(VI).