Abstract
Microbial fuel cells (MFC) have becomea more popular bio-electrochemical approach due to their environmental friendliness and sustainability. The anode is a vital component of the MFC, and its unstable material remains one of the primary causes of poor electron transportation throughout the reactor operations. This study seeks to improve MFC electron transport and naphthalene biodegradation by employing modified palm kernel shell (PKS)-based anode electrodes. These anode fabrications were successfully developed through the combination of PKS-based rGO hybridized into metal oxide modifiers (ZnO and TiO2). The anode electrodes were subsequently assigned PKS-rGO, PKS-rGO/TiO2, and PKS-rGO/ZnO. The power density displayed for PKS-rGO was 35.1 mW/m2, whereas the power density for the PKS-rGO/TiO2 composite anode was found to be 38.2 mW/m2. On the other hand, PKS-rGO/ZnO had a maximum power density of 45.4 mW/m2. The maximum current density (CD) in the anode PKS-rGO/ZnO was 114.0 mA/m2, indicating a comparable pattern of power output. Bacillus sp. and Niallia sp. were identified as exo-electrogens in the microbial study. In the MFC operation, the highest biodegradation efficiency was 85.50 % in the PKS-rGO settings, 92.80 % in PKS-rGO/TiO2, and94.30 % in PKS-rGO/ZnO. SEM and microbiological studies revealed that our anodes were highly biocompatible with microbes. Furthermore, this result proposes future research directions for the mortality ofanodic microbial communitiesin MFC.
Published Version
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