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Article Abstract
Improving microbial electrosynthesis could be one solution for transitioning toward sustainable chemical production, offering a pathway to convert CO into valuable commodities from renewable energy sources. Therefore, we further developed liquid- and vapor-fed anode zero-gap bioelectrochemical cells for electromethanogenesis, utilizing a membrane electrode assembly to enhance mass and ohmic transport. Focusing on CH and H production, we tested two ion-exchange membranes with the liquid-fed anode system and selected the best-performing ion-exchange membrane for the vapor-fed anode system. The liquid-fed anode system did not show considerable differences in volumetric CH production rates compared to vapor-fed anode systems. However, the latter demonstrated advantages in reducing electrocatalyst degradation and maintaining stable cell voltages, resulting in the highest reported maximum CH production efficiency of 48.7 L kWh, thus far. The research underscores the need for further optimization to address performance losses and suggests potential for industrial applications of microbial electrosynthesis, highlighting the importance of catalyst protection.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC12272894 | PMC |
| http://dx.doi.org/10.1016/j.isci.2025.112959 | DOI Listing |
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