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Activation of subnanometric Pt on Cu-modified CeO2 via redox-coupled atomic layer deposition for CO oxidation

Xiao Liu, Shuangfeng Jia, Ming Yang, Yuanting Tang, Yanwei Wen, Shengqi Chu, Jianbo Wang, Bin Shan, Rong Chen

2020Nature Communications198 citationsDOIOpen Access PDF

Abstract

Abstract Improving the low-temperature activity (below 100 °C) and noble-metal efficiency of automotive exhaust catalysts has been a continuous effort to eliminate cold-start emissions, yet great challenges remain. Here we report a strategy to activate the low-temperature performance of Pt catalysts on Cu-modified CeO 2 supports based on redox-coupled atomic layer deposition. The interfacial reducibility and structure of composite catalysts have been precisely tuned by oxide doping and accurate control of Pt size. Cu-modified CeO 2 -supported Pt sub-nanoclusters demonstrate a remarkable performance with an onset of CO oxidation reactivity below room temperature, which is one order of magnitude more active than atomically-dispersed Pt catalysts. The Cu-O-Ce site with activated lattice oxygen anchors deposited Pt sub-nanoclusters, leading to a moderate CO adsorption strength at the interface that facilitates the low-temperature CO oxidation performance.

Topics & Concepts

NanoclustersCatalysisRedoxMaterials scienceNoble metalAtomic layer depositionOxideAdsorptionChemical engineeringDeposition (geology)MetalLayer (electronics)Inorganic chemistryNanotechnologyChemistryPhysical chemistryMetallurgySedimentEngineeringPaleontologyBiochemistryBiologyCatalytic Processes in Materials ScienceElectrocatalysts for Energy ConversionCatalysis and Oxidation Reactions
Activation of subnanometric Pt on Cu-modified CeO2 via redox-coupled atomic layer deposition for CO oxidation | Litcius