Dynamic structural evolution of MgO-supported palladium catalysts: from metal to metal oxide nanoparticles to surface then subsurface atomically dispersed cations.
Yizhen ChenRachita RanaYizhi ZhangAdam S HoffmanZhennan HuangBo YangFernando D VilaJorge E Perez-AguilarJiyun HongXu LiJie ZengMiaofang ChiColeman X KronawitterHaiyan WangSimon R BareAmbarish R KulkarniBruce C GatesPublished in: Chemical science (2024)
Supported noble metal catalysts, ubiquitous in chemical technology, often undergo dynamic transformations between reduced and oxidized states-which influence the metal nuclearities, oxidation states, and catalytic properties. In this investigation, we report the results of in situ X-ray absorption spectroscopy, scanning transmission electron microscopy, and other physical characterization techniques, bolstered by density functional theory, to elucidate the structural transformations of a set of MgO-supported palladium catalysts under oxidative treatment conditions. As the calcination temperature increased, the as-synthesized supported metallic palladium nanoparticles underwent oxidation to form palladium oxides (at approximately 400 °C), which, at approximately 500 °C, were oxidatively fragmented to form mixtures of atomically dispersed palladium cations. The data indicate two distinct types of atomically dispersed species: palladium cations located at MgO steps and those embedded in the first subsurface layer of MgO. The former exhibit significantly higher (>500 times) catalytic activity for ethylene hydrogenation than the latter. The results pave the way for designing highly active and stable supported palladium hydrogenation catalysts with optimized metal utilization.
Keyphrases
- reduced graphene oxide
- electron microscopy
- ionic liquid
- density functional theory
- highly efficient
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- oxide nanoparticles
- transition metal
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- computed tomography
- magnetic resonance imaging
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