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Bifunctional CO oxidation over Mn-mullite anchored Pt sub-nanoclusters via atomic layer deposition.

ABSTRACT: CO oxidation is a widely used model system for understanding fundamental aspects of heterogeneous catalysis. While platinum (Pt) continues to be a reference material for CO oxidation catalysis, poisoning of Pt catalysts presents a critical issue that blocks reaction sites and impedes subsequent reaction steps. Fabrication of CO poison-free Pt catalysts remains a great challenge due to its CO-philic nature. Herein, we report a Pt based catalyst to effectively tackle CO poisoning by tightly anchoring Pt sub-nanoclusters onto Mn-mullite oxide (SmMn2O5) via atomic layer deposition. Superior CO oxidation activity has been observed with a significantly lowered light-off temperature and apparent activation energy. In situ diffuse reflectance infrared Fourier transform spectroscopy analysis, oxygen isotope experiments and density functional theory calculations confirm that the low-temperature activity originates from active oxygen atom sources at the bifunctional interface structure.

SUBMITTER: Liu X 

PROVIDER: S-EPMC5909126 | biostudies-other | 2018 Mar

REPOSITORIES: biostudies-other

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Bifunctional CO oxidation over Mn-mullite anchored Pt sub-nanoclusters <i>via</i> atomic layer deposition.

Liu Xiao X   Tang Yuanting Y   Shen Meiqing M   Li Wei W   Chu Shengqi S   Shan Bin B   Chen Rong R  

Chemical science 20180126 9

CO oxidation is a widely used model system for understanding fundamental aspects of heterogeneous catalysis. While platinum (Pt) continues to be a reference material for CO oxidation catalysis, poisoning of Pt catalysts presents a critical issue that blocks reaction sites and impedes subsequent reaction steps. Fabrication of CO poison-free Pt catalysts remains a great challenge due to its CO-philic nature. Herein, we report a Pt based catalyst to effectively tackle CO poisoning by tightly anchor  ...[more]

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