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Methane Production from Propionate Enhanced by Met@Fe<sub>3</sub>O<sub>4</sub> via Increasing Microbe–Material Attachment in a Direct Interspecies Electron-Transfer Process

Yu Su, Yinguang Chen, Jiang Wu

2020ACS Sustainable Chemistry & Engineering34 citationsDOI

Abstract

Propionic acid is an important metabolic intermediate of anaerobic digestion, but its biotransformation to methane is difficult. Although Fe3O4 was reported to benefit the direct interspecies electron transfer (DIET) in propionate digestion, the poor attachment of Fe3O4 to microbes limited further improvement of methane yield. In this study, the use of methionine-modified Fe3O4 (Met@Fe3O4) aiming at increasing the attachment of Fe3O4 to microbes and enhancing the electron transfer to boost methane production from propionate was reported, and its role was explored. It was observed that in the presence of Met@Fe3O4, the methane yield and the maximal methane production rate were, respectively, 81.2 and 152.1% greater than those of the control and 37.6 and 82.7% higher than those of Fe3O4. The investigation of the mechanism indicated that the lower electrochemical impedance of Met@Fe3O4 made it more effective for promoting not only the intracellular electron transfer of acetoclastic methanogenesis but also extracellular DIET mainly rather than Fe3O4, resulting in the improvement of enzyme and microbial activities involved in anaerobic propionate degradation. Further studies demonstrated that the protein on the cell surface was more likely to bind to Met@Fe3O4 because of the enhanced hydrophilic nature, and the attachment of Met@Fe3O4 to microbes was increased, leading to a faster extracellular electron-transfer efficiency. This study provided an alternative method to improve propionate biodegradation for efficient energy recovery.

Topics & Concepts

PropionateMethanogenesisAnaerobic digestionChemistryElectron transferMethaneBiotransformationExtracellularYield (engineering)BiochemistryBiophysicsEnzymeOrganic chemistryMaterials scienceBiologyMetallurgyMicrobial Fuel Cells and BioremediationAnaerobic Digestion and Biogas ProductionMembrane-based Ion Separation Techniques
Methane Production from Propionate Enhanced by Met@Fe<sub>3</sub>O<sub>4</sub> via Increasing Microbe–Material Attachment in a Direct Interspecies Electron-Transfer Process | Litcius