Interface Engineering Between Multi‐Elemental Alloy Nanoparticles and a Carbon Support Toward Stable Catalysts

材料科学 氧化物 电化学 纳米颗粒 化学工程 催化作用 热稳定性 相(物质) 炭黑 纳米技术 合金 碳纤维 电极 复合材料 冶金 有机化学 化学 复合数 工程类 物理化学 天然橡胶
作者
Tangyuan Li,Qi Dong,Zhennan Huang,Lianping Wu,Yonggang Yao,Jinlong Gao,Xizheng Wang,Haochuan Zhang,Dunwei Wang,Teng Li,Reza Shahbazian‐Yassar,Liangbing Hu
出处
期刊:Advanced Materials [Wiley]
卷期号:34 (9): e2106436-e2106436 被引量:69
标识
DOI:10.1002/adma.202106436
摘要

Abstract Multi‐elemental alloy (MEA) nanoparticles have recently received notable attention owing to their high activity and superior phase stability. Previous syntheses of MEA nanoparticles mainly used carbon as the support, owing to its high surface area, good electrical conductivity, and tunable defective sites. However, the interfacial stability issue, such as nanoparticle agglomeration, remains outstanding due to poor interfacial binding between MEA and carbon. Such a problem often causes performance decay when MEA nanoparticles are used as catalysts, hindering their practical applications. Herein, an interface engineering strategy is developed to synthesize MEA–oxide–carbon hierarchical catalysts, where the oxide on carbon helps disperse and stabilize the MEA nanoparticles toward superior thermal and electrochemical stability. Using several MEA compositions (PdRuRh, PtPdIrRuRh, and PdRuRhFeCoNi) and oxides (TiO 2 and Cr 2 O 3 ) as model systems, it is shown that adding the oxide renders superior interfacial stability and therefore excellent catalytic performance. Excellent thermal stability is demonstrated under transmission electron microscopy with in situ heating up to 1023 K, as well as via long‐term cycling (>370 hours) of a Li–O 2 battery as a harsh electrochemical condition to challenge the catalyst stability. This work offers a new route toward constructing efficient and stable catalysts for various applications.
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