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Progress in Solid Acid Fuel Cell Electrodes

Received: 15 November 2014     Accepted: 23 December 2014     Published: 23 December 2014
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Abstract

Solid acid fuel cells represent a relatively new technology with the advantage of an intermediate operating temperature of 240°C and a solid state proton conducting electrolyte (CsH2PO4). Widespread commercial application has been hindered mainly by low performance and costly electrodes containing a high Pt loading. Here we review the recent progress and current status of solid acid fuel cell electrodes. Major efforts include creating nanostructured composites leading to much reduced Pt loadings while maintaining or even increasing performance. Furthermore, fundamental studies on Pt thin films, as geometrically controlled electrodes, have recently revealed the possibility of an electrochemical pathway through the two-phase boundary in addition to the classic three-phase boundary. Carbon nanotubes as electronic interconnects have been shown to dramatically improve Pt catalyst utilization and hence electrode performance. Major efforts are spent to search for alternative, non-precious metal catalysts.

Published in American Journal of Nano Research and Applications (Volume 2, Issue 6-1)

This article belongs to the Special Issue Advanced Functional Materials

DOI 10.11648/j.nano.s.2014020601.18
Page(s) 61-65
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2014. Published by Science Publishing Group

Keywords

Solid Acid Fuel Cells, Electrodes, CsH2PO4, Pt, CNTs

References
[1] S. M. Haile, D. A. Boysen, C. Chisholm, and R. Merle, Nature 410, 910 (2001).
[2] C. R. I. Chisholm, D. A. Boysen, A. B. Papandrew, S. K. Zecevic, S. Cha, K. A. Sasaki, Á. Varga, K. P. Giapis, and S. M. Haile, Interface Magazine 18, 53 (2009).
[3] M. Louie, California Institute of Technology, 2011
[4] T. Uda and S. M. Haile, Electrochemical and Solid-State Letters 8 (5), A245 (2005).
[5] A. Ikeda, S. M. Haile, Solid State Ionics 213, 63 (2012)
[6] S. B. Adler, Journal of The Electrochemical Society 149 (5), E166 (2002).
[7] K. A. Sasaki, Y. Hao, and S. M. Haile, Physical chemistry chemical physics : PCCP 11 (37), 8349 (2009).
[8] K. Ota and Y. Koizumi, in Handbook of Fuel Cells - Fundamentals, Technology and Applications, edited by W. Vielstich, H. Yokokawa, and H. A. Gasteiger (John Wiley and Sons, 2009), Vol. 5, pp. 243.
[9] S. M. Haile, C. R. I. Chisholm, K. Sasaki, D. A. Boysen, and T. Uda, Faraday Discussions 134, 17 (2007).
[10] Á. Varga, N. A. Brunelli, M. W. Louie, K. P. Giapis, and S. M. Haile, Journal of Materials Chemistry 20 (30), 6309 (2010).
[11] Á. Varga, M. Pfohl, N. A. Brunelli, M. Schreier, K. P. Giapis, and S. M. Haile, Physical chemistry chemical physics : PCCP 15 (37), 15470 (2013).
[12] R. C. Suryaprakash, F. Lohmann, M. Wagner, B. Abel, and A. Varga, RSC Adv. (2014).
[13] M. W. Louie and S. M. Haile, Energy & Environmental Science 4 (10), 4230 (2011).
[14] M. W. Louie, K. Sasaki, and S. M. Haile, ECS Transactions 13 (28), 57 (2008).
[15] A. B. Papandrew, C. R. I. Chisholm, R. A. Elgammal, M. M. Özer, and S. K. Zecevic, Chemistry of Materials 23 (7), 1659 (2011).
[16] T. Uda, D. A. Boysen, C. R. I. Chisholm, and S. M. Haile, Electrochemical and Solid-State Letters 9 (6), A261 (2006).
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    Aron Varga. (2014). Progress in Solid Acid Fuel Cell Electrodes. American Journal of Nano Research and Applications, 2(6-1), 61-65. https://doi.org/10.11648/j.nano.s.2014020601.18

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    ACS Style

    Aron Varga. Progress in Solid Acid Fuel Cell Electrodes. Am. J. Nano Res. Appl. 2014, 2(6-1), 61-65. doi: 10.11648/j.nano.s.2014020601.18

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    AMA Style

    Aron Varga. Progress in Solid Acid Fuel Cell Electrodes. Am J Nano Res Appl. 2014;2(6-1):61-65. doi: 10.11648/j.nano.s.2014020601.18

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  • @article{10.11648/j.nano.s.2014020601.18,
      author = {Aron Varga},
      title = {Progress in Solid Acid Fuel Cell Electrodes},
      journal = {American Journal of Nano Research and Applications},
      volume = {2},
      number = {6-1},
      pages = {61-65},
      doi = {10.11648/j.nano.s.2014020601.18},
      url = {https://doi.org/10.11648/j.nano.s.2014020601.18},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.nano.s.2014020601.18},
      abstract = {Solid acid fuel cells represent a relatively new technology with the advantage of an intermediate operating temperature of 240°C and a solid state proton conducting electrolyte (CsH2PO4). Widespread commercial application has been hindered mainly by low performance and costly electrodes containing a high Pt loading. Here we review the recent progress and current status of solid acid fuel cell electrodes. Major efforts include creating nanostructured composites leading to much reduced Pt loadings while maintaining or even increasing performance. Furthermore, fundamental studies on Pt thin films, as geometrically controlled electrodes, have recently revealed the possibility of an electrochemical pathway through the two-phase boundary in addition to the classic three-phase boundary. Carbon nanotubes as electronic interconnects have been shown to dramatically improve Pt catalyst utilization and hence electrode performance. Major efforts are spent to search for alternative, non-precious metal catalysts.},
     year = {2014}
    }
    

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    AU  - Aron Varga
    Y1  - 2014/12/23
    PY  - 2014
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    JF  - American Journal of Nano Research and Applications
    JO  - American Journal of Nano Research and Applications
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    AB  - Solid acid fuel cells represent a relatively new technology with the advantage of an intermediate operating temperature of 240°C and a solid state proton conducting electrolyte (CsH2PO4). Widespread commercial application has been hindered mainly by low performance and costly electrodes containing a high Pt loading. Here we review the recent progress and current status of solid acid fuel cell electrodes. Major efforts include creating nanostructured composites leading to much reduced Pt loadings while maintaining or even increasing performance. Furthermore, fundamental studies on Pt thin films, as geometrically controlled electrodes, have recently revealed the possibility of an electrochemical pathway through the two-phase boundary in addition to the classic three-phase boundary. Carbon nanotubes as electronic interconnects have been shown to dramatically improve Pt catalyst utilization and hence electrode performance. Major efforts are spent to search for alternative, non-precious metal catalysts.
    VL  - 2
    IS  - 6-1
    ER  - 

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Author Information
  • Leibniz Insitute of Surface Modification, Permoserstra?e 15, D-04318 Leipzig, Germany

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