Litcius/Paper detail

Self-regeneration of supported transition metals by a high entropy-driven principle

Shengtai Hou, Xuefeng Ma, Shu Yuan, Jiafeng Bao, Qiuyue Zhang, Mingshu Chen, Pengfei Zhang, Sheng Dai

2021Nature Communications99 citationsDOIOpen Access PDF

Abstract

Abstract The sintering of Supported Transition Metal Catalysts (STMCs) is a core issue during high temperature catalysis. Perovskite oxides as host matrix for STMCs are proven to be sintering-resistance, leading to a family of self-regenerative materials. However, none other design principles for self-regenerative catalysts were put forward since 2002, which cannot satisfy diverse catalytic processes. Herein, inspired by the principle of high entropy-stabilized structure, a concept whether entropy driving force could promote the self-regeneration process is proposed. To verify it, a high entropy cubic Zr 0.5 (NiFeCuMnCo) 0.5 O x is constructed as a host model, and interestingly in situ reversible exsolution-dissolution of supported metallic species are observed in multi redox cycles. Notably, in situ exsolved transition metals from high entropy Zr 0.5 (NiFeCuMnCo) 0.5 O x support, whose entropic contribution (TΔS config = T⋆12.7 J mol −1 K −1 ) is predominant in ∆G, affording ultrahigh thermal stability in long-term CO 2 hydrogenation (400 °C, >500 h). Current theory may inspire more STWCs with excellent sintering-resistance performance.

Topics & Concepts

Regeneration (biology)Entropy (arrow of time)Statistical physicsPhysicsBiologyThermodynamicsCell biologyCatalytic Processes in Materials ScienceHigh Entropy Alloys StudiesCatalysis and Oxidation Reactions