(Plenary) Remaining Technical Challenges in R&D for Automotive PEM Fuel Cell System

Cost and durability are still challenging for commercialization enabling automotive fuel cell technology. Mass transport, oxygen reduction reaction (ORR) activity and fuel cell stack materials such as bipolar plates are high cost impact areas. Significant research and development (R&D) efforts h...

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Hauptverfasser:	Hirano, Shinichi, Waldecker, James
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Sprache:	eng
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creator	Hirano, Shinichi Waldecker, James
description	Cost and durability are still challenging for commercialization enabling automotive fuel cell technology. Mass transport, oxygen reduction reaction (ORR) activity and fuel cell stack materials such as bipolar plates are high cost impact areas. Significant research and development (R&D) efforts have been pursued in each area individually. To fill the gap to the target, further R&D is necessary to develop a concept which is attributed to those factors concurrently. For example, catalyst research aims not only to improve ORR mass activity but also to enhance mass transport performance in the high current density region. Therefore further R&D focus for catalyst area will be shifted from the catalyst material itself to the catalyst layer structure to enhance the ORR activity and overcome mass transport in the membrane electrode assembly. The technical outlook and research approaches for the remaining technical challenges for automotive PEMFCs will be discussed.
doi_str_mv	10.1149/06403.0003ecst
format	Conference Proceeding
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title	(Plenary) Remaining Technical Challenges in R&D for Automotive PEM Fuel Cell System
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