Nanoporous high-entropy alloys with low Pt loadings for high-performance electrochemical oxygen reduction

[Display omitted] •Nanoporous high-entropy alloys with low Pt content were prepared.•The composition of the multicomponent HEAs can be widely changed.•The AlNiCuPtMn combination exhibits the highest ORR activity.•The designing principle can be applied to other metals. Pt-based alloys have been widel...

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Bibliographic Details
Published in:Journal of catalysis 2020-03, Vol.383, p.164-171
Main Authors: Li, Shiyin, Tang, Xiaowei, Jia, Henglei, Li, Huanglong, Xie, Guoqiang, Liu, Xingjun, Lin, Xi, Qiu, Hua-Jun
Format: Article
Language:English
Subjects:
Electrocatalysis
Fuel cells
HEAs
Mesoporous
ORR
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Summary:[Display omitted] •Nanoporous high-entropy alloys with low Pt content were prepared.•The composition of the multicomponent HEAs can be widely changed.•The AlNiCuPtMn combination exhibits the highest ORR activity.•The designing principle can be applied to other metals. Pt-based alloys have been widely used as high-performance electrocatalysts for the oxygen reduction reaction (ORR). These catalysts contained high Pt contents, typically 60–70 at.% or higher, since further decreasing Pt contents would significantly lower the desired electro-catalytic activity. High-entropy alloys (HEAs) with built-in stability through their low free-energy phases provided a promising route to prepare Pt-based alloy catalysts with less than 50 at.% Pt while maintaining high ORR activity and stability in various environments. In this work, we reported a top-down de-alloying synthetic method to controllably incorporate five immiscible metals in one nanoscale solid phase. By predetermining four elements (Al, Cu, Ni and Pt) and alternating the fifth element including Pd, V, Co, Mn, etc., a series of nanoporous HEAs (np-HEAs) with Pt content of ~20–30 at.% were obtained. Among these quinary alloys, the Al-Cu-Ni-Pt-Mn np-HEA exhibited the best ORR catalytic activity and electrochemical cycling durability, well exceeding the commercial Pt/C catalysts. We expected these nanostructured HEA would offer a new class of alloy catalysts in many electrochemical reactions.
ISSN:0021-9517
1090-2694
DOI:10.1016/j.jcat.2020.01.024