Modified graphene oxide anode: A bioinspired waste material for bioremediation of Pb2+ with energy generation through microbial fuel cells

Nowadays, Microbial fuel cells (MFCs) technology has received a great attention as a promising and sustainable technology to generate electricity and reduce environmental pollution. However, low energy generation and fabrication cost-issue of anode material hamper the commercial viability of MFCs. In this study, oil palm biomass waste-derived graphene derivatives (L-GO) was used as an anode in a double chamber of MFCs. Furthermore, to improve the electron transportation rate, composite based anode (L-GO/ZnO) was fabricated to generate energy and concurrently remediate the Pb2+ supplemented wastewater. The setup with L-GO/ZnO anode showed 91.07% removal efficiency of metal ions (Pb2+) while 85% removal efficiency was exhibited by L-GO anode. Moreover, the composite anode (L-GO/ZnO) delivered maximum power density (1350 x 10(-3) mW/m(2)) and current density (142.98 mA/m(2)) which are higher than L-GO anode (power density = 20 x 10(-3) mW/m(2) and current density = 17.54 mA/m(2)). The anode performance was well supported by electrochemical and physicochemical analyses. The results of the fabricated anodes showed that oil palm biomass can be used as a promising and low-cost material to enhance the anode performance of MFCs.

Automated summary

This study utilized oil palm biomass waste-derived graphene derivatives as a novel anode material in MFCs and further improved the efficiency of MFCs by fabricating composite anodes to treat Pb2+ wastewater. The results demonstrate that the composite anode exhibited higher efficiency, power density, and current density compared to the single L-GO anode.