Alkaline polymer electrolyte fuel cells: Principle, challenges, and recent progress 被引量：9

Alkaline polymer electrolyte fuel cells: Principle, challenges, and recent progress

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摘要 Polymer electrolyte membrane fuel cells (PEMFC) have been recognized as a significant power source in future energy systems based on hydrogen. The current PEMFC technology features the employment of acidic polymer electrolytes which, albeit superior to electrolyte solutions, have intrinsically limited the catalysts to noble metals, fundamentally preventing PEMFC from widespread deployment. An effective solution to this problem is to develop fuel cells based on alkaline polymer electrolytes (APEFC), which not only enable the use of non-precious metal catalysts but also avoid the carbonate-precipitate issue which has been troubling the conventional alkaline fuel cells (AFC). This feature article introduces the principle of APEFC, the challenges, and our research progress, and focuses on strategies for developing key materials, including high-performance alkaline polyelectrolytes and stable non-precious metal catalysts. For alkaline polymer electrolytes, high ionic conductivity and satisfactory mechanical property are difficult to be balanced, therefore polymer cross-linking is an ultimate strategy. For non-precious metal catalysts, it is urgent to improve the catalytic activity and stability. New materials, such as transition-metal complexes, nitrogen-doped carbon nanotubes, and metal carbides, would become applicable in APEFC. Polymer electrolyte membrane fuel cells (PEMFC) have been recognized as a significant power source in future energy systems based on hydrogen. The current PEMFC technology features the employment of acidic polymer electrolytes which, albeit superior to electrolyte solutions, have intrinsically limited the catalysts to noble metals, fundamentally preventing PEMFC from widespread deployment. An effective solution to this problem is to develop fuel cells based on alkaline polymer electrolytes (APEFC), which not only enable the use of non-precious metal catalysts but also avoid the carbonate-precipitate issue which has been troubling the conventional alkaline fuel cells (AFC). This feature article introduces the principle of APEFC, the challenges, and our research progress, and focuses on strategies for developing key materials, including high-performance alkaline polyelectrolytes and stable non-precious metal catalysts. For alkaline polymer electrolytes, high ionic conductivity and satisfactory mechanical property are difficult to be balanced, therefore polymer cross-linking is an ultimate strategy. For non-precious metal catalysts, it is urgent to improve the catalytic activity and stability. New materials, such as transition-metal complexes, nitrogen-doped carbon nanotubes, and metal carbides, would become applicable in APEFC.

作者 TANG DaoPing PAN Jing LU ShanFu ZHUANG Lin LU JunTao

机构地区 Hubei Key Lab of Electrochemical Power Sources

出处《Science China Chemistry》 SCIE EI CAS 2010年第2期357-364,共8页 中国科学(化学英文版)

基金 supported by the National Natural Science Foundation of China (Grant Nos. 20933004, 20773096, 50632050, 20433060 and J0730426) the National Hi-Tech R&D Program (2007AA05Z142)

关键词 fuel cells polymer electrolyte anion exchange membrane CATALYST non-precious metal fuel cells polymer electrolyte anion exchange membrane catalyst non-precious metal

分类号 TM911.4 [电气工程—电力电子与电力传动]

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Alkaline polymer electrolyte fuel cells: Principle, challenges, and recent progress 被引量：9

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