Gold particles growth on carbon felt for efficient micropower generation in a hybrid biofuel cell

• Published in: Electrochimica acta Vol. 219; pp. 121 - 129
• Main Authors: Le, Thi Xuan Huong, Bechelany, Mikhael, Engel, Adriana Both, Cretin, Marc, Tingry, Sophie
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 20.11.2016; Elsevier
• Subjects: Chemical Sciences; dewetting; electrodeposition; enzyme; glucose; gold particles; hybrid biofuel cell; Material chemistry; enzyme; hybrid biofuel cell; dewetting; glucose; electrodeposition; gold particles
• ISSN: 0013-4686; 1873-3859
• DOI: 10.1016/j.electacta.2016.09.135

[Display omitted] •Homogeneously dispersed gold particles onto carbon felt were fabricated by electrodeposition.•We studied the electrocatalytic properties of this new gold material with low gold loading (0.2wt%).•The resulting Au@CF material is used to construct a 3-dimensional glucose hybrid biofuel cell.•The system exhibited an open circuit voltage of 0.71V and maximum power density of 310μWcm−2 at 352mV. In this study, homogeneously dispersed gold particles growth onto carbon felt were fabricated by electrodeposition method followed by a thermal treatment at 1000°C under nitrogen. The thermal treatment induced the dewetting of gold and the formation of well-crystallized gold particles that exhibited large surface area. The structural properties of the resulted Au@CF material were evaluated by SEM, XRD and TGA. We studied the electrocatalytic properties of this new gold material through the abiotic glucose oxidation in alkaline medium and the enzymatic dioxygen electroreduction by the enzyme bilirubin oxidase. Finally, we showed the potentiality of the resulting Au@CF material to build a 3-dimensional glucose hybrid biofuel cell by assemblying an abiotic anode with an enzymatic cathode. The system exhibited high electrochemical performance with an open circuit voltage of 0.71V and a maximum power density of 310μWcm−2 at 352mV (by taking into account the projected surface area), in spite of a low gold loading (0.2wt%). The advance presented in this work is the efficiency of the synthesis technique to get a new free-standing material for electrocatalysis based on gold particles with high reactive surface area for electron transfer and macropores for diffusion transport.