Self-regenerative noble metal catalysts supported on high-entropy oxides | Zendy

Hao Chen | Zendy; Yifan Sun | Zendy; Shize Yang | Zendy; Hui Wang | Zendy; Wojciech Dmowski | Zendy; T. Egami | Zendy; Sheng Dai | Zendy

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Self-regenerative noble metal catalysts supported on high-entropy oxides

Author(s) -

Hao Chen,

Yifan Sun,

Shize Yang,

Hui Wang,

Wojciech Dmowski,

T. Egami,

Sheng Dai

Publication year - 2020

Publication title -

chemical communications

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.837

H-Index - 333

eISSN - 1364-548X

pISSN - 1359-7345

DOI - 10.1039/d0cc05860b

Subject(s) - noble metal , catalysis , sintering , dissolution , metal , materials science , entropy (arrow of time) , transition metal , chemical engineering , nanotechnology , inorganic chemistry , chemistry , thermodynamics , metallurgy , organic chemistry , physics , engineering

Discovery of anti-sintering noble metal catalysts is challenging, as supported noble metal species tend to aggregate at high temperatures, leading to severely deteriorated catalytic performances. Here we show that 1 wt% of noble metal species including Au, Pd and Ru can be incorporated into high-entropy oxides (HEOs) through entropy stabilization at 900 °C in air. A reversible temperature-dependent dissolution-exsolution process is observed for Au-HEO. Further correlation with distinct CO oxidation capabilities demonstrates the potential to utilize the entropy effect to access self-regenerative catalysts for catalytic reactions.

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