Abstract
Microbial fuel cell (MFC) can harvest chemical energy stored in volatile organic compounds (VOCs) and consequently are of great potential for waste gas treatment and energy recovery. However, the inadequate connection between active cells and bioanode substrate hinders the extracellular electron transfer, especially in the upper layer of biofilm, resulting in restricted degradation capacity and power output. Herein, we propose a pore matching strategy to establish electron transfer nanowires around individual cells by embedding them separately inside a pore-matched sponge (core-shell polyaniline @ carbon nanotube, PANI@CNT). The resulting MFC for toluene degradation presents 4.41 times increase in power density (279.91 mW m−2), 2.64 times increase in coulombic efficiency (18.13%), and 2.02 times increase in toluene degradation activity (0.77 h−1), which also possesses considerable advantages over literature results. Furthermore, metagenomic analysis indicates that the genes for transmembrane and extracellular electron transfer are down-regulated, validating the effectiveness of the PANI@CNT nanowires linking individual cells with bioanode substrate. These findings reveal the feasibility of the pore matching strategy to boost toluene degradation and power extraction in MFC, and give an in-depth insight into transmembrane and extracellular electron transfer mechanisms.
Published Version
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