Biodegradation and proton exchange using natural rubber in microbial fuel cells
Biodegradation and proton exchange using natural rubber in microbial fuel cells
Microbial fuel cells (MFCs) generate electricity from waste but to date the technology’s development and scale-up has been held-up by the need to incorporate expensive materials. A costly but vital component is the ion exchange membrane (IEM) which conducts protons between the anode and cathode electrodes. The current study compares natural rubber as an alternative material to two commercially available IEMs. Initially, the material proved impermeable to protons, but gradually a working voltage was generated that improved with time. After 6 months, MFCs with natural rubber membrane outperformed those with anion exchange membrane (AEM) but cation exchange membrane (CEM) produced 109 % higher power and 16 % higher current. After 11 months, polarisation experiments showed a decline in performance for both commercially available membranes while natural rubber continued to improve and generated 12 % higher power and 54 % higher current than CEM MFC. Scanning electron microscope images revealed distinct structural changes and the formation of micropores in natural latex samples that had been employed as IEM for 9 months. It is proposed that the channels and micropores formed as a result of biodegradation were providing pathways for proton transfer, reflected by the steady increase in power generation over time. These improvements may also be aided by the establishment of biofilms that, in contrast, caused declining performance in the CEM. The research demonstrates for the first time that the biodegradation of a ubiquitous waste material operating as IEM can benefit MFC performance while also improving the reactor’s lifetime compared to commercially available membranes.
Microbial fuel cell, Latex, Biodegradation, Ion exchange membrane, Natural rubber
733-739
Winfield, Jonathan
e81f4fad-1433-4c6a-9723-24a14f172896
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Patton, David
fc823c9b-0ef2-438b-a8cb-d25c607f88ed
30 January 2013
Winfield, Jonathan
e81f4fad-1433-4c6a-9723-24a14f172896
Ieropoulos, Ioannis
6c580270-3e08-430a-9f49-7fbe869daf13
Rossiter, Jonathan
64caa0df-19e0-40c8-ab69-7021de665c39
Greenman, John
eb3d9b82-7cac-4442-9301-f34884ae4a16
Patton, David
fc823c9b-0ef2-438b-a8cb-d25c607f88ed
Winfield, Jonathan, Ieropoulos, Ioannis, Rossiter, Jonathan, Greenman, John and Patton, David
(2013)
Biodegradation and proton exchange using natural rubber in microbial fuel cells.
Biodegradation, 24 (6), .
(doi:10.1007/s10532-013-9621-x).
Abstract
Microbial fuel cells (MFCs) generate electricity from waste but to date the technology’s development and scale-up has been held-up by the need to incorporate expensive materials. A costly but vital component is the ion exchange membrane (IEM) which conducts protons between the anode and cathode electrodes. The current study compares natural rubber as an alternative material to two commercially available IEMs. Initially, the material proved impermeable to protons, but gradually a working voltage was generated that improved with time. After 6 months, MFCs with natural rubber membrane outperformed those with anion exchange membrane (AEM) but cation exchange membrane (CEM) produced 109 % higher power and 16 % higher current. After 11 months, polarisation experiments showed a decline in performance for both commercially available membranes while natural rubber continued to improve and generated 12 % higher power and 54 % higher current than CEM MFC. Scanning electron microscope images revealed distinct structural changes and the formation of micropores in natural latex samples that had been employed as IEM for 9 months. It is proposed that the channels and micropores formed as a result of biodegradation were providing pathways for proton transfer, reflected by the steady increase in power generation over time. These improvements may also be aided by the establishment of biofilms that, in contrast, caused declining performance in the CEM. The research demonstrates for the first time that the biodegradation of a ubiquitous waste material operating as IEM can benefit MFC performance while also improving the reactor’s lifetime compared to commercially available membranes.
This record has no associated files available for download.
More information
Accepted/In Press date: 17 January 2013
Published date: 30 January 2013
Keywords:
Microbial fuel cell, Latex, Biodegradation, Ion exchange membrane, Natural rubber
Identifiers
Local EPrints ID: 454669
URI: http://eprints.soton.ac.uk/id/eprint/454669
ISSN: 0923-9820
PURE UUID: 82f8ab97-0fbf-45e4-9702-5f2313f01ffe
Catalogue record
Date deposited: 18 Feb 2022 17:43
Last modified: 17 Mar 2024 04:10
Export record
Altmetrics
Contributors
Author:
Jonathan Winfield
Author:
Jonathan Rossiter
Author:
John Greenman
Author:
David Patton
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
