Biodegradation and proton exchange using natural rubber in microbial fuel cells

Winfield, Jonathan; Ieropoulos, Ioannis; Rossiter, Jonathan; Greenman, John; Patton, David

doi:10.1007/s10532-013-9621-x

Cited by 56 publications

(23 citation statements)

References 25 publications

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“…3b shows that there [5,18,19]. As previously reported [20], MFCs employing natural rubber as membrane improve over time as the material degrades, and after 6 months the CL-MFC continued to improve whilst maintaining a steady performance. Fig.…”

Section: Carbon Veil Vs Conductive Latex Cathodessupporting

confidence: 68%

The power of glove: Soft microbial fuel cell for low-power electronics

Winfield

Chambers

Stinchcombe

et al. 2014

Journal of Power Sources

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Section: Carbon Veil Vs Conductive Latex Cathodessupporting

confidence: 68%

The power of glove: Soft microbial fuel cell for low-power electronics

Winfield

Chambers

Stinchcombe

et al. 2014

Journal of Power Sources

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“…Due to the material's high cost, the majority of the work has then focused on finding alternatives that include trials with a range of materials such as j-cloth, nylon fibers, glass fibers, ceramics and biodegradable shopping bags [422], [423], [424], [425], [426], [427]. More unconventional materials, normally considered as waste such as natural rubber or laboratory gloves [428], have also been investigated [429], [430], and these materials appear to also offer advantages over membrane fouling [431]. Recently, it has also been demonstrated that a single finger piece from a laboratory glove, successfully operated a power management system, thus exhibiting practical implementation potential [249].…”

Section: Discussionmentioning

confidence: 99%

Microbial fuel cells: From fundamentals to applications. A review

Santoro

Arbizzani

Erable

et al. 2017

Journal of Power Sources

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In the past 10–15 years, the microbial fuel cell (MFC) technology has captured the attention of the scientific community for the possibility of transforming organic waste directly into electricity through microbially catalyzed anodic, and microbial/enzymatic/abiotic cathodic electrochemical reactions. In this review, several aspects of the technology are considered. Firstly, a brief history of abiotic to biological fuel cells and subsequently, microbial fuel cells is presented. Secondly, the development of the concept of microbial fuel cell into a wider range of derivative technologies, called bioelectrochemical systems, is described introducing briefly microbial electrolysis cells, microbial desalination cells and microbial electrosynthesis cells. The focus is then shifted to electroactive biofilms and electron transfer mechanisms involved with solid electrodes. Carbonaceous and metallic anode materials are then introduced, followed by an explanation of the electro catalysis of the oxygen reduction reaction and its behavior in neutral media, from recent studies. Cathode catalysts based on carbonaceous, platinum-group metal and platinum-group-metal-free materials are presented, along with membrane materials with a view to future directions. Finally, microbial fuel cell practical implementation, through the utilization of energy output for practical applications, is described.

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“…Recently, however, less conventional, biodegradable materials have been successfully applied. Natural rubber has proven to be a viable substitute to conventional membranes over long term operation where the act of biodegradation actually aided performance [22]. Other materials such as paper [16], egg, gelatine, PLA and lanolin have all demonstrated their suitability as viable working components in MFCs [23].…”

Section: The Power Source For Biodegradable Robotsmentioning

confidence: 99%