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Structural Evolution of Anatase‐Supported Platinum Nanoclusters into a Platinum‐Titanium Intermetallic Containing Platinum Single Atoms for Enhanced Catalytic CO Oxidation

Wenxue He, Xu Zhang, Kun Zheng, Chuanqiang Wu, Ya Pan, Hongmei Li, Liuxin Xu, Ruichao Xu, Wei Chen, Yi Liu, Chao Wang, Zhihu Sun, Shiqiang Wei

2022Angewandte Chemie10 citationsDOI

Abstract

Abstract Strong metal‐support interactions characteristic of the encapsulation of metal particles by oxide overlayers have been widely observed on large metal nanoparticles, but scarcely occur on small nanoclusters (<2 nm) for which the metal‐support interactions remain elusive. Herein, we study the structural evolution of Pt nanoclusters (1.5 nm) supported on anatase TiO 2 upon high‐temperature H 2 reduction. The Pt nanoclusters start to partially evolve into a CsCl‐type PtTi intermetallic compound when the reduction temperature reaches 400 °C. Upon 700 °C reduction, the PtTi nanoparticles are exclusively formed and grow epitaxially along the TiO 2 (101) crystal faces. The thermodynamics of the formation of PtTi via migration of reduced Ti atoms into Pt cluster is unraveled by theoretical calculations. The thermally stable PtTi intermetallic compound, with single‐atom Pt isolated by Ti, exhibits enhanced catalytic activity and promoted catalytic durability for CO oxidation.

Topics & Concepts

NanoclustersIntermetallicPlatinumAnataseCatalysisMaterials scienceTitaniumMetalOxideChemical engineeringTitanium oxideNanoparticleNialInorganic chemistryNanotechnologyChemistryMetallurgyPhotocatalysisOrganic chemistryEngineeringAlloyCatalytic Processes in Materials ScienceElectrocatalysts for Energy ConversionNanomaterials for catalytic reactions
Structural Evolution of Anatase‐Supported Platinum Nanoclusters into a Platinum‐Titanium Intermetallic Containing Platinum Single Atoms for Enhanced Catalytic CO Oxidation | Litcius