Abstract:
This study reports organic matter, nutrient, coliform removal performance in microbial fuel cell (MFC)-based, normal (without electrodes) horizontal flow (HF) constructed wetlands that were filled with stone-aggregate and dosed with municipal wastewater. The HF constructed wetlands were operated as monoculture plant-based shallow bedfully saturated or polyculture plant-based deep bed-partially saturated systems. The HF wetlands were operated under two hydraulic loading (HL) rates: 29.3 and 58.6 mmid. The MFC-based, normal HF constructed wetlands achieved 80 to 100% organic, 55 to 92% nitrogen removal percentage throughout the experimental campaign. Organic removal was influenced by the organic biodegradation ratio (BOD/COD) profiles of municipal wastewater, particularly in the MFC-based systems. Nitrogen removal was achieved through media-based adsorption and microbial nitrification-denitrification. The wetland systems achieved >= 93% phosphorus and >= 83% coliform removal through media-based adsorption, filtration, and oxidation kinetics. Nutrient accumulation percentage in plants tissue was <1% with respect to total removal. HL and pollutant removal rates increment were positively correlated. Maximum power density production rates were 10.6, and 38.6 mW/m(2) in shallow bed-fully saturated and deep bed-partially saturated HF constructed wetlands, respectively. The deep bed-partially saturated MFC-based, normal HF wetlands achieved higher pollutant removal, bioenergy production because of better atmospheric oxygen transmission capacity. (C) 2021 The Authors. Published by Elsevier B.V.