Electrochemical performance of a glucose/oxygen microfluidic biofuel cell

Zebda, Abdelkader; Renaud, Louis; Cretin, Marc; Innocent, Christophe; Pichot, F.; Ferrigno, Rosaria; Tingry, Sophie

doi:10.1016/j.jpowsour.2009.04.066

Cited by 74 publications

(38 citation statements)

References 26 publications

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“…Although the electric power generation demonstrated in this study was lower than those reported by several authors, such as by Zebda et al [18,19], our results clearly demonstrated that enzyme fuel cells employing FADGDH are capable of generating electric power utilizing variety of cellulolytic sugars as the substrate, including glucose. Thanks to the direct electron transfer capability of the enzyme, simple structure and component of enzyme electrode was achieved, consequently allowed to utilize cost effective and versatile carbon cloth as the electrode materials.…”

Section: Power Generation Based On Cellulolytic Sugarscontrasting

confidence: 76%

Enzyme Fuel Cell for Cellulolytic Sugar Conversion Employing FAD Glucose Dehydrogenase and Carbon Cloth Electrode Based on Direct Electron Transfer Principle~!2010-01-09~!2010-02-04~!2010-05-17~!

Desriani¹,

Hanashi²,

Yamazaki³

et al. 2010

TOELECJ

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An enzyme fuel cell employing a carbon cloth electrode and bacterial FAD dependent glucose dehydrogenase (FADGDH) based on the direct electron transfer principle was constructed, and its scalability and cellulolytic sugar conversion were investigated. FADGDH was immobilized on the carbon cloth electrode together with carbon paste to form a multi-module type enzyme fuel cell by combining platinum-supported carbon immobilized carbon cloth as the cathode. The enzyme fuel cell was stable for more than 7 days of continuous operation. The 3 3 module (18 cm 2 ) enzyme fuel cell generated 68 μW (3.8 μW/cm 2 ) using glucose as the substrate, which was almost 9 times that of a single-module enzyme fuel cell. Thanks to the substrate specificity of bacterial FADGDH, cellulolytic sugars were revealed to be a good substrate for the enzyme fuel cell with cellobiose (9.3 μW/cm 2 ), cellotriose (9.2 μW/cm 2 ), or cellotetraose (6.3 μW/cm 2 ). These results demonstrated that together with the feasibility of using carbon cloth as the electrode material, FADGDH as the anode catalyst will become the norm in electrochemical biomass applications in the future.

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Section: Power Generation Based On Cellulolytic Sugarscontrasting

confidence: 76%

Enzyme Fuel Cell for Cellulolytic Sugar Conversion Employing FAD Glucose Dehydrogenase and Carbon Cloth Electrode Based on Direct Electron Transfer Principle~!2010-01-09~!2010-02-04~!2010-05-17~!

Desriani¹,

Hanashi²,

Yamazaki³

et al. 2010

TOELECJ

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show abstract

“…glucose as the fuel and enzymes as the electrocatalysts, can be utilized at the electrode (Halámková et al, 2012;Zebda et al, 2009;Nazaruk et al, 2008;Togo et al, 2008). Various kinds of enzyme proteins, such as families of dehydrogenases, oxidases, peroxidases, etc., have been examined as the electrocatalysts both of the anode and the cathode, thus, the fuel cell reaction proceeds via a wide variety of the chemical reaction and the electron transfer process at the electrode in the field of BFCs (Rasmussen et al, 2012;Prakash et al, 2009;Drobov et al, 2008;Brunel et al, 2007;Kamitaka et al, 2007;Ikeda and Kano, 2003;Tsujimura et al, 2001;Katz et al, 1999;Gorton et al 1999;Palmore et al, 1998).…”

Section: Introductionmentioning

confidence: 99%

A simple biofuel cell cathode with human red blood cells as electrocatalysts for oxygen reduction reaction

Ayato

Sakurai

Fukunaga

et al. 2014

Biosensors and Bioelectronics

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“…6. (Zebda et al, 2009b). Another strategy to prevent the direct contact and the reaction between oxidant and fuel was proposed in the case of a microfluidic fuel cell working from formic acid as fuel (Sun et al, 2007).…”

Section: Strategies To Limit the Cross-diffusional Mixingmentioning

confidence: 99%