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Tree Fungus Lets Current Flow

Scientists at the Department of Microsystems Engineering present new concept for biofuel cells

Freiburg, Jul 05, 2013

Tree Fungus Lets Current Flow

The tree fungus Trametes versicolor provides the cathode of a biofuel cell with a steady supply of the enzyme laccase, thus enabling the fuel cell to react with oxygen. Source: ChemSusChem, Wiley-VCH Verlag GmbH & Co. KGaA (www.chemsuschem.org)

Sabine Sané, doctoral candidate in the research training group Micro Energy Harvesting at the Department of Microsystems Engineering (IMTEK) of the University of Freiburg, has found a way to make a species of tree fungus useful for the production of electricity. The new energy conversion concept was chosen as the cover story of ChemSusChem, a journal for chemistry, sustainability, energy, and materials. The research was supported by scientists from a research group led by Dr. Sven Kerzenmacher at Prof. Dr. Roland Zengerle’s Laboratory for MEMS Applications.

Biofuel cells produce electricity that is environmentally friendly and conserves resources, for instance from organic waste material. They can use enzymes as catalysts to enable electrochemical reactions that generate electricity. In contrast to precious metal catalysts in conventional fuel cells, these enzymes can be obtained at low cost from renewable raw materials. For many technical applications, however, their lifetime is too short.

The new concept developed by the Freiburg scientists solves this problem by ensuring that the fuel cell is continually resupplied with the biocatalyst. The supplier of the fuel cell is Trametes versicolor, a tree fungus that is also found in temperate climates: It releases the fungal enzyme laccase into a solution surrounding the cathode – the positive pole of the cell – where it enables the electrochemical conversion of oxygen. Experiments conducted by the researchers demonstrate that this method can be used to extend the lifetime of the cathodes to as much as 120 days, and even considerably longer lifetimes seem possible. By comparison, the cathodes only have a lifetime of 14 days if they are not supplied with more of the enzymes. Since the enzymatic solution can be supplied directly to the fuel cell without time-consuming and expensive purification, the costs are reduced to a minimum. Potential applications for the concept include microbial fuel cells that generate electricity from wastewater, a technology Kerzenmacher’s research group is also developing.

Original publication:
S. Sané, C. Jolivalt, G. Mittler, P.J. Nielsen, S. Rubenwolf, R. Zengerle, S. Kerzenmacher (2013): Overcoming Bottlenecks of Enzymatic Biofuel Cell Cathodes: Crude Fungal Culture Supernatant Can Help to Extend Lifetime and Reduce Cost. In: ChemSusChem 6, p. 1209-1215. Available online without a subscription until 17 July 2013 at:
http://onlinelibrary.wiley.com/doi/10.1002/cssc.201300205/abstract


Contact:
Dr. Sven Kerzenmacher, Head of the Biofuel Cell Research Group
Department of Microsystems Engineering, Laboratory of MEMS Applications
University of Freiburg
Phone: +49 (0)761 / 203-73218
E-Mail: kerzenma@imtek.uni-freiburg.de

Katrin Grötzinger, PR/Marketing
Department of Microsystems Engineering, Laboratory of MEMS Applications
University of Freiburg
Phone: +49 (0)761 / 203-73242
E-Mail: katrin.groetzinger@hsg-imit.de

 

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