Decoupling the Contributions of Different Instability Mechanisms to the PEMFC Performance Decay of Non-noble Metal O 2 -Reduction Catalysts

Decoupling the Contributions of Different Instability Mechanisms to the PEMFC Performance Decay of Non-noble Metal O 2 -Reduction Catalysts

Non-noble metal catalysts (NNMCs) hold the potential to replace the expensive Pt-based materials currently used to speed up the oxygen reduction reaction (ORR) in proton exchange membrane fuel cell (PEMFC) cathodes, but they feature poor durability that inhibits their implementation in commercial PE...

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Veröffentlicht in:Journal of the American Chemical Society 2023-04, Vol.145 (14), p.7845-7858
Hauptverfasser: Ünsal, Seçil, Girod, Robin, Appel, Christian, Karpov, Dmitry, Mermoux, Michel, Maillard, Frédéric, Saveleva, Viktoriia A, Tileli, Vasiliki, Schmidt, Thomas J, Herranz, Juan
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container_issue 14
container_start_page 7845
container_title Journal of the American Chemical Society
container_volume 145
creator Ünsal, Seçil
Girod, Robin
Appel, Christian
Karpov, Dmitry
Mermoux, Michel
Maillard, Frédéric
Saveleva, Viktoriia A
Tileli, Vasiliki
Schmidt, Thomas J
Herranz, Juan
description Non-noble metal catalysts (NNMCs) hold the potential to replace the expensive Pt-based materials currently used to speed up the oxygen reduction reaction (ORR) in proton exchange membrane fuel cell (PEMFC) cathodes, but they feature poor durability that inhibits their implementation in commercial PEMFCs. This performance decay is commonly ascribed to the operative demetallation of their ORR-active sites, the electro-oxidation of the carbonaceous matrix that hosts these active centers, and/or the chemical degradation of the ionomer, active sites, and/or carbon support by radicals derived from the H O produced as an ORR by-product. However, little is known regarding the relative contributions of these mechanisms to the overall PEMFC performance loss. With this motivation, in this study, we combined four degradation protocols entailing different cathode gas feeds (i.e., air vs N ), potential hold values, and durations to decouple the relative impact of the above deactivation mechanisms to the overall performance decay. Our results indicate that H O -related instability does not depend on the operative voltage but only on the ORR charge. Moreover, the electro-oxidation of the carbon matrix at high potentials (which for the catalyst tested herein triggers at 0.7 V) seems to be more detrimental to the NNMCs' activity than the demetallation occurring at low potentials.
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