Preprint,
Performance effects from different shutdown methods of three electrode materials for the power-to-gas application with electromethanogenesis
Affiliations
- [1] University of Tübingen [NORA names: Germany; Europe, EU; OECD];
- [2] Electrochaea GmbH–Power-to-Gas Energy Storage, Semmelweisstraße 3, 82152 Planegg, Germany [NORA names: Germany; Europe, EU; OECD];
- [3] Aarhus University [NORA names: AU Aarhus University; University; Denmark; Europe, EU; Nordic; OECD];
- [4] Cluster of Excellence “Controlling Microbes to Fight Infections” [NORA names: Germany; Europe, EU; OECD];
- [5] Max Planck Institute for Biology [NORA names: Germany; Europe, EU; OECD];
(... more)
Abstract
Abstract Industrial applications of microbial electrochemical systems will require regular maintenance shutdowns, involving inspections and component replacements to extend the lifespan of the system. Here, we examined the impact of such shutdowns on the performance of three electrode materials ( i.e ., platinized titanium, graphite, and nickel) as cathodes in a microbial electrochemical system that would be used for electromethanogenesis in power-to-gas applications. We focused on methane (CH 4 ) production from hydrogen (H 2 ) and carbon dioxide (CO 2 ) using Methanothermobacter thermautotrophicus . We showed that the platinized titanium cathode resulted in high volumetric CH 4 production rates and Coulombic efficiencies. Using a graphite cathode would be more cost-effective than using the platinized titanium cathode in microbial electrochemical systems but showed an inferior performance. The microbial electrochemical system with the nickel cathode showed improvements compared to the graphite cathode. Additionally, this system with a nickel cathode demonstrated the fastest recovery during a shutdown experiment compared to the other two cathodes. Fluctuations in pH and nickel concentrations in the catholyte during power interruptions affected CH 4 production recovery in the system with the nickel cathode. This research enhances understanding of the integration of biological and electrochemical processes in microbial electrochemical systems, providing insights into electrode selection and operating strategies for effective and sustainable CH 4 production.