Electromethanogenesis at medium-low temperatures: Impact on performance and sources of variability

Electromethanogenesis at medium-low temperatures: Impact on performance and sources of variability

•Electromethanogenesis (EM) can convert pure CO2 into high-purity biogas (∼90% CH4).•EM performance greatly deteriorates when temperature is reduced from 30 to 15 °C.•This deterioration is attributed to methanogenic rather than hydrogenic activity.•EM can easily recover its previous performance when...

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Bibliographic Details
Published in:Fuel (Guildford) Vol. 310; p. 122336
Main Authors: Pelaz, Guillermo, Carrillo-Peña, Daniela, Morán, Antonio, Escapa, Adrián
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 15-02-2022
Elsevier BV
Subjects:
Biocathode
Bioelectrochemical system
Biogas
Carbon dioxide
Electromethanogenesis
Low temperature
Methane
Methanogenesis
Temperature
Biogas
Biocathode
Bioelectrochemical system
Electromethanogenesis
Low temperature
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Summary:•Electromethanogenesis (EM) can convert pure CO2 into high-purity biogas (∼90% CH4).•EM performance greatly deteriorates when temperature is reduced from 30 to 15 °C.•This deterioration is attributed to methanogenic rather than hydrogenic activity.•EM can easily recover its previous performance when temperature returns to 30 °C.•Methanogenic rather than hydrogenic activity explains the low replicability of EM. In this study we aimed to understand the impact of medium–low temperatures on the two main steps that usually comprise the electromethanogenesis (EM) process: electrothrophic hydrogenesis and hydrogenothrophic methanogenesis. Results revealed that pure CO2 could effectively be converted into a high-purity biogas (∼90:10 CH4/CO2) at 30 °C. However, when temperature was reduced to 15 °C, methane richness greatly decreased (∼40:60 CH4/CO2). This deterioration in performance was mostly attributed to a decline in methanogenic activity (represented mainly by Methanobacterium and Methanobrevibacter). In contrast, the hydrogenic activity (mostly Desulfomicrobium) did not suffer any significant decay. Results also seemed to indicate that methanogenesis, rather than hydrogenesis, is the main source of variability in EM. Increasing the temperature again to 30 °C restored previous performance, which highlights the resilience of EM to wide temperature fluctuations (from 30 to 15 and back 30 °C).
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.122336