Enhanced bio-production from CO2 by microbial electrosynthesis (MES) with continuous operational mode
Enhanced bio-production from CO2 by microbial electrosynthesis (MES) with continuous operational mode
Technologies able to convert CO2 to various feedstocks for fuels and chemicals are emerging due to the urge of reducing greenhouse gas emissions and de-fossilizing chemical production. Microbial electrosynthesis (MES) has been shown a promising technique to synthesize organic products particularly acetate using microorganisms and electrons. However, the efficiency of the system is low. In this study, we demonstrated the simple yet efficient strategy in enhancing the efficiency of MES by applying continuous feeding regime. Compared to the fed-batch system, continuous operational mode provided better control of pH and constant medium refreshment, resulting in higher acetate production rate and more diverse bio-products, when the cathodic potential of -1.0 V Ag/AgCl and dissolved CO2 were provided. It was observed that hydraulic retention time (HRT) had a direct effect on the pattern of production, acetate production rate and coulombic efficiency. At HRT of 3 days, pH was around 5.2 and acetate was the dominant product with the highest production rate of 651.8 ± 214.2 ppm per day and a significant coulombic efficiency of 90%. However at the HRT of 7 days, pH was lower at around 4.5, and lower but stable acetate production rate of 280 ppm per day and a maximum coulombic efficiency of 80% was obtained. In addition, more diverse and longer chain products, such as butyrate, isovalerate and caproate, were detected with low concentrations only at the HRT of 7 days. Although microbial community analysis showed the change in the planktonic cells communities after switching the fed-batch mode to continuous feeding regime, Acetobacterium still remained as the responsible bacteria for CO2 reduction to acetate, dominating the cathodic biofilm.
344-359
Izadi, Paniz
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Fontmorin, Jean Marie
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Lim, Swee Su
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Head, Ian M.
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Yu, Eileen H.
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Izadi, Paniz
0fda147e-44cf-4480-b72b-c3303c570573
Fontmorin, Jean Marie
5bf4da48-91b0-4548-a4ef-c5dd8e0b630c
Lim, Swee Su
b2f36c85-e9ce-44da-8a8a-0a4d84fa61d4
Head, Ian M.
45e5ea84-bd86-4ffd-a6e3-64b23dc711d2
Yu, Eileen H.
28e47863-4b50-4821-b80b-71fb5a2edef2
Izadi, Paniz, Fontmorin, Jean Marie, Lim, Swee Su, Head, Ian M. and Yu, Eileen H.
(2021)
Enhanced bio-production from CO2 by microbial electrosynthesis (MES) with continuous operational mode.
Faraday Discussions, 230, .
(doi:10.1039/d0fd00132e).
Abstract
Technologies able to convert CO2 to various feedstocks for fuels and chemicals are emerging due to the urge of reducing greenhouse gas emissions and de-fossilizing chemical production. Microbial electrosynthesis (MES) has been shown a promising technique to synthesize organic products particularly acetate using microorganisms and electrons. However, the efficiency of the system is low. In this study, we demonstrated the simple yet efficient strategy in enhancing the efficiency of MES by applying continuous feeding regime. Compared to the fed-batch system, continuous operational mode provided better control of pH and constant medium refreshment, resulting in higher acetate production rate and more diverse bio-products, when the cathodic potential of -1.0 V Ag/AgCl and dissolved CO2 were provided. It was observed that hydraulic retention time (HRT) had a direct effect on the pattern of production, acetate production rate and coulombic efficiency. At HRT of 3 days, pH was around 5.2 and acetate was the dominant product with the highest production rate of 651.8 ± 214.2 ppm per day and a significant coulombic efficiency of 90%. However at the HRT of 7 days, pH was lower at around 4.5, and lower but stable acetate production rate of 280 ppm per day and a maximum coulombic efficiency of 80% was obtained. In addition, more diverse and longer chain products, such as butyrate, isovalerate and caproate, were detected with low concentrations only at the HRT of 7 days. Although microbial community analysis showed the change in the planktonic cells communities after switching the fed-batch mode to continuous feeding regime, Acetobacterium still remained as the responsible bacteria for CO2 reduction to acetate, dominating the cathodic biofilm.
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d0fd00132e
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Accepted/In Press date: 11 January 2021
e-pub ahead of print date: 29 January 2021
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Local EPrints ID: 498879
URI: http://eprints.soton.ac.uk/id/eprint/498879
ISSN: 1359-6640
PURE UUID: 2ec4b076-cf6a-49cd-9ba2-8a50565a9ca2
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Date deposited: 04 Mar 2025 17:50
Last modified: 22 Aug 2025 02:45
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Author:
Paniz Izadi
Author:
Jean Marie Fontmorin
Author:
Swee Su Lim
Author:
Ian M. Head
Author:
Eileen H. Yu
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