Abstract
This study investigated methane (CH(4)) production in a bioelectrochemically enhanced anaerobic digester (BEAD) equipped with a pair of 3-dimensional flow-through electrodes made of conductive polypropylene biorings. The performance of the BEAD reactor was compared to that of a similarly sized Anaerobic Upflow Sludge Bed (UASB) reactor. The reactors were operated at a temperature of 22 ± 1 °C using food waste (FW) leachate fed at organic loading rates of 3-8 g (L(R) d)(-1) or at a temperature of 35 ± 1 °C using the liquid fraction of FW separated using a screw press. With both tested feedstocks, the BEAD reactor demonstrated up to 30% higher CH(4) yield, reaching 0.35-0.38 L g(-1) (COD consumed), compared to the UASB reactor. Additionally, reactor stability under organic overload conditions improved, with the difference more pronounced at organic loads above 6 g (L(R) d)(-1). Energy consumption for bioelectrochemical CH(4) production was estimated at 5.1-12.4 Wh L(-1) (of CH(4) produced), which is significantly below the energy consumption for electrochemical H(2)-based methanation. Overall, BEAD increases methane production and improves process stability, offering a novel sustainable solution for waste management.