Enhancing extracellular electron transfer through selective enrichment of Geobacter with Fe@CN modified carbon-based anode in microbial fuel cells

Abstract: Microbial fuel cells (MFCs) have been demonstrated as a renewable energy strategy to efficiently recover chemical energy stored in wastewater into clean electricity by exoelectrogens through a combination of microbial metabolism and electrochemical processes, yet the limited power density limits their application. Here, Fe coped carbon and nitrogen (Fe@CN) nano-material was synthesized by direct pyrolysis of FeCl3 and urea, which was further decorated to fabricate Fe@CN modified carbon paper anode to improve t… Show more

“…In a study that investigated how (semi)conductive iron-oxide minerals alter the EET pathway of Geobacter spp. (Kato et al 2013), it was discovered that iron-oxide minerals increased current generation in Geobacter strains (Cheng et al 2022) while having no effect on another strain. Their findings raise the notion that natural (semi)conductive iron oxide minerals provide Geobacter with energetic and ecological advantages, enabling their growth and survival in the natural environment.…”

Strategies for Enhancing Extracellular Electron Transfer in Environmental Biotechnology

“…In a study that investigated how (semi)conductive iron-oxide minerals alter the EET pathway of Geobacter spp. (Kato et al 2013), it was discovered that iron-oxide minerals increased current generation in Geobacter strains (Cheng et al 2022) while having no effect on another strain. Their findings raise the notion that natural (semi)conductive iron oxide minerals provide Geobacter with energetic and ecological advantages, enabling their growth and survival in the natural environment.…”

Strategies for Enhancing Extracellular Electron Transfer in Environmental Biotechnology