Parameters influencing the development of highly conductive and efficient biofilm during microbial electrosynthesis: the importance of applied potential and inorganic carbon source
Parameters influencing the development of highly conductive and efficient biofilm during microbial electrosynthesis: the importance of applied potential and inorganic carbon source
Cathode-driven applications of bio-electrochemical systems (BESs) have the potential to transform CO2 into value-added chemicals using microorganisms. However, their commercialisation is limited as biocathodes in BESs are characterised by slow start-up and low efficiency. Understanding biosynthesis pathways, electron transfer mechanisms and the effect of operational variables on microbial electrosynthesis (MES) is of fundamental importance to advance these applications of a system that has the capacity to convert CO2 to organics and is potentially sustainable. In this work, we demonstrate that cathodic potential and inorganic carbon source are keys for the development of a dense and conductive biofilm that ensures high efficiency in the overall system. Applying the cathodic potential of −1.0 V vs. Ag/AgCl and providing only gaseous CO2 in our system, a dense biofilm dominated by Acetobacterium (ca. 50% of biofilm) was formed. The superior biofilm density was significantly correlated with a higher production yield of organic chemicals, particularly acetate. Together, a significant decrease in the H2 evolution overpotential (by 200 mV) and abundant nifH genes within the biofilm were observed. This can only be mechanistically explained if intracellular hydrogen production with direct electron uptake from the cathode via nitrogenase within bacterial cells is occurring in addition to the commonly observed extracellular H2 production. Indeed, the enzymatic activity within the biofilm accelerated the electron transfer. This was evidenced by an increase in the coulombic efficiency (ca. 69%) and a 10-fold decrease in the charge transfer resistance. This is the first report of such a significant decrease in the charge resistance via the development of a highly conductive biofilm during MES. The results highlight the fundamental importance of maintaining a highly active autotrophic Acetobacterium population through feeding CO2 in gaseous form, which its dominance in the biocathode leads to a higher efficiency of the system.
1-15
Izadi, Paniz
0fda147e-44cf-4480-b72b-c3303c570573
Fontmorin, Jean Marie
5bf4da48-91b0-4548-a4ef-c5dd8e0b630c
Godain, Alexiane
d503861b-a87d-4a66-8e7f-3d4d2b529adb
Yu, Eileen H.
28e47863-4b50-4821-b80b-71fb5a2edef2
Head, Ian M.
45e5ea84-bd86-4ffd-a6e3-64b23dc711d2
14 October 2020
Izadi, Paniz
0fda147e-44cf-4480-b72b-c3303c570573
Fontmorin, Jean Marie
5bf4da48-91b0-4548-a4ef-c5dd8e0b630c
Godain, Alexiane
d503861b-a87d-4a66-8e7f-3d4d2b529adb
Yu, Eileen H.
28e47863-4b50-4821-b80b-71fb5a2edef2
Head, Ian M.
45e5ea84-bd86-4ffd-a6e3-64b23dc711d2
Izadi, Paniz, Fontmorin, Jean Marie, Godain, Alexiane, Yu, Eileen H. and Head, Ian M.
(2020)
Parameters influencing the development of highly conductive and efficient biofilm during microbial electrosynthesis: the importance of applied potential and inorganic carbon source.
NPJ Biofilms and Microbiomes, 6 (1), , [40].
(doi:10.1038/s41522-020-00151-x).
Abstract
Cathode-driven applications of bio-electrochemical systems (BESs) have the potential to transform CO2 into value-added chemicals using microorganisms. However, their commercialisation is limited as biocathodes in BESs are characterised by slow start-up and low efficiency. Understanding biosynthesis pathways, electron transfer mechanisms and the effect of operational variables on microbial electrosynthesis (MES) is of fundamental importance to advance these applications of a system that has the capacity to convert CO2 to organics and is potentially sustainable. In this work, we demonstrate that cathodic potential and inorganic carbon source are keys for the development of a dense and conductive biofilm that ensures high efficiency in the overall system. Applying the cathodic potential of −1.0 V vs. Ag/AgCl and providing only gaseous CO2 in our system, a dense biofilm dominated by Acetobacterium (ca. 50% of biofilm) was formed. The superior biofilm density was significantly correlated with a higher production yield of organic chemicals, particularly acetate. Together, a significant decrease in the H2 evolution overpotential (by 200 mV) and abundant nifH genes within the biofilm were observed. This can only be mechanistically explained if intracellular hydrogen production with direct electron uptake from the cathode via nitrogenase within bacterial cells is occurring in addition to the commonly observed extracellular H2 production. Indeed, the enzymatic activity within the biofilm accelerated the electron transfer. This was evidenced by an increase in the coulombic efficiency (ca. 69%) and a 10-fold decrease in the charge transfer resistance. This is the first report of such a significant decrease in the charge resistance via the development of a highly conductive biofilm during MES. The results highlight the fundamental importance of maintaining a highly active autotrophic Acetobacterium population through feeding CO2 in gaseous form, which its dominance in the biocathode leads to a higher efficiency of the system.
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s41522-020-00151-x
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Accepted/In Press date: 21 September 2020
Published date: 14 October 2020
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© 2020, The Author(s).
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Local EPrints ID: 498642
URI: http://eprints.soton.ac.uk/id/eprint/498642
PURE UUID: 825a2bcc-248e-40fd-a496-10b197ee6366
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Date deposited: 24 Feb 2025 18:03
Last modified: 22 Aug 2025 02:45
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Author:
Paniz Izadi
Author:
Jean Marie Fontmorin
Author:
Alexiane Godain
Author:
Eileen H. Yu
Author:
Ian M. Head
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