Bioelectrochemical Systems (BES) for Biomethane Production—Review

Horváth-Gönczi, Noémi N.; Bagi, Zoltán; Szuhaj, Márk; Rákhely, Gábor; Kovács, Kornél L.

doi:10.3390/fermentation9070610

Cited by 6 publications

(2 citation statements)

References 178 publications

(387 reference statements)

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“…This strategy combines in a single step the biological methanation process with the electro-synthetical approach. 3–8 In conventional biogas plants, methanogenic microorganisms are used to produce biomethane from a limited number of organic substrates ( e.g. , acetate, formate, and methanol) with the process named dark fermentation.…”

Section: Introductionmentioning

confidence: 99%

Interface properties of hydroxyapatite in ternary composites cathodes for electromethanogenesis

Bigica,

Ghiara,

Cristiani

et al. 2024

New J. Chem.

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Section: Introductionmentioning

confidence: 99%

Interface properties of hydroxyapatite in ternary composites cathodes for electromethanogenesis

Bigica,

Ghiara,

Cristiani

et al. 2024

New J. Chem.

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“…This integration combines the breakdown of organic matter through AD to produce biogas (almost equimolar gas mixture of CO 2 :CH 4 ) with MEC where renewable energy and microorganisms from AD are used as catalysts to convert CO 2 into high-purity methane -a clean fuel. The potential benefits of this approach include improved efficiency, increased sustainability, and enhanced energy recovery from organic waste (Horváth-Gönczi et al, 2023;Wang et al, 2022). However, practical implementation requires understanding microbial interactions at the electrode surface and their impact on methane formation.…”

Section: Introductionmentioning

confidence: 99%

Electrical current disrupts the electron transfer in defined consortia

Yee,

Ottosen,

Rotaru

2023

Microbial Biotechnology

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Improving methane production through electrical current application to anaerobic digesters has garnered interest in optimizing such microbial electrochemical technologies, with claims suggesting direct interspecies electron transfer (DIET) at the cathode enhances methane yield. However, previous studies with mixed microbial communities only reported interspecies interactions based on species co‐occurrence at the cathode, lacking insight into how a poised cathode influences well‐defined DIET‐based partnerships. To address this, we investigated the impact of continuous and discontinuous exposure to a poised cathode (−0.7 V vs. standard hydrogen electrode) on a defined consortium of Geobacter metallireducens and Methanosarcina barkeri, known for their DIET capabilities. The physiology of DIET consortia exposed to electrical current was compared to that of unexposed consortia. In current‐exposed incubations, overall metabolic activity and cell numbers for both partners declined. The consortium, receiving electrons from the poised cathode, accumulated acetate and hydrogen, with only 32% of the recovered electrons allocated to methane production. Discontinuous exposure intensified these detrimental effects. Conversely, unexposed control reactors efficiently converted ethanol to methane, transiently accumulating acetate and recovering 88% of electrons in methane. Our results demonstrate the overall detrimental effect of electrochemical stimulation on a DIET consortium. Besides, the data indicate that the presence of an alternative electron donor (cathode) hinders efficient electron retrieval by the methanogen from Geobacter, and induces catabolic repression of oxidative metabolism in Geobacter. This study emphasizes understanding specific DIET‐based interactions to enhance methane production during electrical stimulation, providing insights for optimizing tailored interspecies partnerships in microbial electrochemical technologies.

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