Biogenic Melanin-Modified
Graphene as a Cathode Catalyst
Yields Greater Bioelectrochemical Performances by Stimulating Oxygen–Reduction
and Microbial Electron Transfer
Bioelectrochemical systems (BES)
can recover energy from
organic-bearing
waste streams, but their use has been stymied by poor electron transfer
from the cathode. Redox-active electron shuttles could stimulate electron
transfer provided that they are compatible with the exoelectrogenic
bacteria. This work evaluated melanin-modified carboxylated graphene
(M/CG) as a novel cathode catalyst in a microbial fuel cell. Biogenic
melanin catalysts (i.e., bio-M/CG) significantly increased bioelectricity
production due to its abundant pyrrole N, which lowered charge-transfer
resistance and, thus, promoted the cathodic oxygen–reduction
reaction (ORR). The high content of pyrrole N in the bio-M/CG catalyst
also enriched exoelectrogens, such as Azospirillum, Chryseobacterium, and Azoarcus, which accounted for over 50% of the total abundance of bacteria
in biofilms on the anode. Moreover, the functional genes of key enzymes
involved in microbial electron transfer (MET) were increased by the
bio-M/CG catalyst. These data confirm that the bio-M/CG catalyst improved
the bioelectrochemical performance via synergetic promotion of cathodic
ORR and microbial electron transfer, thus providing a new alternative
for advancing BES technology. This work highlights the potential application
of melanin in enhancing cathodic oxygen–reduction reaction
kinetics and improving microbial electron transfer in BES. This study
emphasizes the promising application of melanin in enhancing the ORR
kinetics and improving MET in BES, offering exciting prospects for
future sustainable and environmentally friendly applications