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Carbon to electricity in a solid oxide fuel cell combined with an internal catalytic gasification process

Konsolakis Michail, Marnellos Giorgos E., Al-Musa A., Nikolaos Kaklidis, Ioannis Garagounis, Kyriakou Vasileios

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URI: http://purl.tuc.gr/dl/dias/BAEFE5D7-30B5-4CE5-9419-40D5AA142BFA
Year 2015
Type of Item Peer-Reviewed Journal Publication
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Bibliographic Citation M. Konsolakis, G.E. Marnellos, A. Al-Musa, N. Kaklidis, I. Garagounis, V. Kyriakou, "Carbon to electricity in a solid oxide fuel cell combined with an internal catalytic gasification process," vol. 36, no. 4, pp. 509-516, 2015. doi: 10.1016/S1872-2067(14)60262-X https://doi.org/10.1016/S1872-2067(14)60262-X
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Summary

This study explores strategies to develop highly efficient direct carbon fuel cells (DCFCs) by combining a solid-oxide fuel cell (SOFC) with a catalyst-aided carbon-gasification process. This system employs Cu/CeO2 composites as both anodic electrodes and carbon additives in a cell of the type: carbon|Cu-CeO2/YSZ/Ag|air. The study investigates the impact on in situ carbon-gasification and DCFC performance characteristics of catalyst addition and variation in the carrier gas used (inert He versus reactive CO2). The results indicate that cell performance is significantly improved by infusing the catalyst into the carbon feedstock and by employing CO2 as the carrier gas. At 800 °C, the maximum power output is enhanced by approximately 40% and 230% for carbon/CO2 and carbon/catalyst/CO2 systems, respectively, compared with that of the carbon/He configuration. The increase observed when employing the catalyst and CO2 as the carrier gas can be primarily attributed to the pronounced effect of the catalyst on carbon-gasification through the reverse-Boudouard reaction, and the subsequent in situ electro-oxidation of CO at the anode three-phase boundary.

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