Enhancing hydrogen production through anode fed-batch mode and controlled cell voltage in a microbial electrolysis cell fully catalysed by microorganisms
Enhancing hydrogen production through anode fed-batch mode and controlled cell voltage in a microbial electrolysis cell fully catalysed by microorganisms
A microbial electrolysis cell (MEC) fully catalysed by microorganisms is an attractive technology because it incorporates the state-of-the-art concept of converting organic waste to hydrogen with less external energy input than conventional electrolysers. In this work, the impact of the anode feed mode on the production of hydrogen by the biocathode was studied. In the first part, three feed modes and MEC performance in terms of hydrogen production were evaluated. The results showed the highest hydrogen production under the continuous mode (14.6 ± 0.4), followed by the fed-batch (12.7 ± 0.4) and batch (0 L m−2 cathode day−1) modes. On one hand, the continuous mode only increased by 15% even though the hydraulic retention time (HRT) (2.78 h) was lower than the fed-batch mode (HRT 5 h). A total replacement (fed-batch) rather than a constant mix of existing anolyte and fresh medium (continuous) was preferable. On the other hand, no hydrogen was produced in batch mode due to the extensive HRT (24 h) and bioanode starvation. In the second part, the fed-batch mode was further evaluated using a chronoamperometry method under a range of applied cell voltages of 0.3–1.6 V. Based on the potential evolution at the electrodes, three main regions were identified depending on the applied cell voltages: the cathode activation (<0.8 V), transition (0.8–1.1 V), and anode limitation (>1.1 V) regions. The maximum hydrogen production recorded was 12.1 ± 2.1 L m−2 cathode day−1 at 1.0 V applied voltage when the oxidation and reduction reactions at the anode and cathode were optimal (2.38 ± 0.61 A m−2). Microbial community analysis of the biocathode revealed that Alpha-, and Deltaproteobacteria were dominant in the samples with >70% abundance. At the genus level, Desulfovibrio sp. was the most abundant in the samples, showing that these microbes may be responsible for hydrogen evolution.
Anode optimisation, Balance reactions, Feed control, Hydrogen evolution, Microbial electrolysis cell
Lim, Swee Su
b2f36c85-e9ce-44da-8a8a-0a4d84fa61d4
Fontmorin, Jean Marie
5bf4da48-91b0-4548-a4ef-c5dd8e0b630c
Ikhmal Salehmin, Mohd Nur
d1abd41e-55b5-4a49-ba5f-38b39da8cd39
Feng, Yujie
c337c8aa-b99d-42d1-9b51-a5521b1e14a0
Scott, Keith
38909157-296d-4fe7-a245-1b98e1fee913
Yu, Eileen Hao
28e47863-4b50-4821-b80b-71fb5a2edef2
12 December 2023
Lim, Swee Su
b2f36c85-e9ce-44da-8a8a-0a4d84fa61d4
Fontmorin, Jean Marie
5bf4da48-91b0-4548-a4ef-c5dd8e0b630c
Ikhmal Salehmin, Mohd Nur
d1abd41e-55b5-4a49-ba5f-38b39da8cd39
Feng, Yujie
c337c8aa-b99d-42d1-9b51-a5521b1e14a0
Scott, Keith
38909157-296d-4fe7-a245-1b98e1fee913
Yu, Eileen Hao
28e47863-4b50-4821-b80b-71fb5a2edef2
Lim, Swee Su, Fontmorin, Jean Marie, Ikhmal Salehmin, Mohd Nur, Feng, Yujie, Scott, Keith and Yu, Eileen Hao
(2023)
Enhancing hydrogen production through anode fed-batch mode and controlled cell voltage in a microbial electrolysis cell fully catalysed by microorganisms.
Chemosphere, 288 (Pt. 2), [132548].
(doi:10.1016/j.chemosphere.2021.132548).
Abstract
A microbial electrolysis cell (MEC) fully catalysed by microorganisms is an attractive technology because it incorporates the state-of-the-art concept of converting organic waste to hydrogen with less external energy input than conventional electrolysers. In this work, the impact of the anode feed mode on the production of hydrogen by the biocathode was studied. In the first part, three feed modes and MEC performance in terms of hydrogen production were evaluated. The results showed the highest hydrogen production under the continuous mode (14.6 ± 0.4), followed by the fed-batch (12.7 ± 0.4) and batch (0 L m−2 cathode day−1) modes. On one hand, the continuous mode only increased by 15% even though the hydraulic retention time (HRT) (2.78 h) was lower than the fed-batch mode (HRT 5 h). A total replacement (fed-batch) rather than a constant mix of existing anolyte and fresh medium (continuous) was preferable. On the other hand, no hydrogen was produced in batch mode due to the extensive HRT (24 h) and bioanode starvation. In the second part, the fed-batch mode was further evaluated using a chronoamperometry method under a range of applied cell voltages of 0.3–1.6 V. Based on the potential evolution at the electrodes, three main regions were identified depending on the applied cell voltages: the cathode activation (<0.8 V), transition (0.8–1.1 V), and anode limitation (>1.1 V) regions. The maximum hydrogen production recorded was 12.1 ± 2.1 L m−2 cathode day−1 at 1.0 V applied voltage when the oxidation and reduction reactions at the anode and cathode were optimal (2.38 ± 0.61 A m−2). Microbial community analysis of the biocathode revealed that Alpha-, and Deltaproteobacteria were dominant in the samples with >70% abundance. At the genus level, Desulfovibrio sp. was the most abundant in the samples, showing that these microbes may be responsible for hydrogen evolution.
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Accepted/In Press date: 10 October 2021
e-pub ahead of print date: 22 October 2021
Published date: 12 December 2023
Keywords:
Anode optimisation, Balance reactions, Feed control, Hydrogen evolution, Microbial electrolysis cell
Identifiers
Local EPrints ID: 499108
URI: http://eprints.soton.ac.uk/id/eprint/499108
ISSN: 0045-6535
PURE UUID: def90c0a-2ce8-4c8e-925c-4cdbd1723f44
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Date deposited: 10 Mar 2025 17:30
Last modified: 11 Mar 2025 03:15
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Author:
Swee Su Lim
Author:
Jean Marie Fontmorin
Author:
Mohd Nur Ikhmal Salehmin
Author:
Yujie Feng
Author:
Keith Scott
Author:
Eileen Hao Yu
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