Increased power generation in supercapacitive microbial fuel cell stack using Fe-N-C cathode catalyst
Increased power generation in supercapacitive microbial fuel cell stack using Fe-N-C cathode catalyst
The anode and cathode electrodes of a microbial fuel cell (MFC) stack, composed of 28 single MFCs, were used as the negative and positive electrodes, respectively of an internal self-charged supercapacitor. Particularly, carbon veil was used as the negative electrode and activated carbon with a Fe-based catalyst as the positive electrode. The red-ox reactions on the anode and cathode, self-charged these electrodes creating an internal electrochemical double layer capacitor. Galvanostatic discharges were performed at different current and time pulses. Supercapacitive-MFC (SC-MFC) was also tested at four different solution conductivities. SC-MFC had an equivalent series resistance (ESR) decreasing from 6.00 Ω to 3.42 Ω in four solutions with conductivity between 2.5 mScm−1 and 40 mScm−1. The ohmic resistance of the positive electrode corresponded to 75–80% of the overall ESR. The highest performance was achieved with a solution conductivity of 40 mS cm−1 and this was due to the positive electrode potential enhancement for the utilization of Fe-based catalysts. Maximum power was 36.9 mW (36.9 W m−3) that decreased with increasing pulse time. SC-MFC was subjected to 4520 cycles (8 days) with a pulse time of 5 s (ipulse 55 mA) and a self-recharging time of 150 s showing robust reproducibility.
Supercapacitor, Microbial fuel cell, Galvanostatic discharges, Fe-based catalyst, Long terms stability
416-424
Santoro, Carlo
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Kodali, Mounika
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Shamoon, Najeeb
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Serov, Alexey
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Soavi, Francesca
ebdd72f5-996d-44e9-a0ac-f29cf580a21e
Merino-Jimenez, Irene
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Gajda, Iwona
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Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Atanassov, Plamen
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1 February 2019
Santoro, Carlo
03549f6d-d57f-4d79-8bae-2d9271aa7371
Kodali, Mounika
40a7e520-fcc7-46d0-bddf-5d03281fd902
Shamoon, Najeeb
2d037a80-e5da-4251-a562-2f582193e69c
Serov, Alexey
d546edc2-cf7a-4b1a-a443-70bffdd636a3
Soavi, Francesca
ebdd72f5-996d-44e9-a0ac-f29cf580a21e
Merino-Jimenez, Irene
7e2a86c3-070b-4fce-a86a-f50279044737
Gajda, Iwona
943dd6bd-524b-4c7b-b794-dec5ee8014b7
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Atanassov, Plamen
a1fe7e9b-9386-448a-90a8-a870c3163922
Santoro, Carlo, Kodali, Mounika, Shamoon, Najeeb, Serov, Alexey, Soavi, Francesca, Merino-Jimenez, Irene, Gajda, Iwona, Greenman, John, Ieropoulos, Ioannis and Atanassov, Plamen
(2019)
Increased power generation in supercapacitive microbial fuel cell stack using Fe-N-C cathode catalyst.
Journal of Power Sources, 412, .
(doi:10.1016/j.jpowsour.2018.11.069).
Abstract
The anode and cathode electrodes of a microbial fuel cell (MFC) stack, composed of 28 single MFCs, were used as the negative and positive electrodes, respectively of an internal self-charged supercapacitor. Particularly, carbon veil was used as the negative electrode and activated carbon with a Fe-based catalyst as the positive electrode. The red-ox reactions on the anode and cathode, self-charged these electrodes creating an internal electrochemical double layer capacitor. Galvanostatic discharges were performed at different current and time pulses. Supercapacitive-MFC (SC-MFC) was also tested at four different solution conductivities. SC-MFC had an equivalent series resistance (ESR) decreasing from 6.00 Ω to 3.42 Ω in four solutions with conductivity between 2.5 mScm−1 and 40 mScm−1. The ohmic resistance of the positive electrode corresponded to 75–80% of the overall ESR. The highest performance was achieved with a solution conductivity of 40 mS cm−1 and this was due to the positive electrode potential enhancement for the utilization of Fe-based catalysts. Maximum power was 36.9 mW (36.9 W m−3) that decreased with increasing pulse time. SC-MFC was subjected to 4520 cycles (8 days) with a pulse time of 5 s (ipulse 55 mA) and a self-recharging time of 150 s showing robust reproducibility.
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1-s2.0-S0378775318313168-main
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Published date: 1 February 2019
Keywords:
Supercapacitor, Microbial fuel cell, Galvanostatic discharges, Fe-based catalyst, Long terms stability
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Local EPrints ID: 456224
URI: http://eprints.soton.ac.uk/id/eprint/456224
ISSN: 0378-7753
PURE UUID: 49edddc5-5482-461e-81df-4ccfd55b2ad9
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Date deposited: 26 Apr 2022 19:06
Last modified: 17 Mar 2024 04:10
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Author:
Carlo Santoro
Author:
Mounika Kodali
Author:
Najeeb Shamoon
Author:
Alexey Serov
Author:
Francesca Soavi
Author:
Irene Merino-Jimenez
Author:
Iwona Gajda
Author:
John Greenman
Author:
Plamen Atanassov
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