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Atomic-Scale Mechanism of Platinum Catalyst Restructuring under a Pressure of Reactant Gas

Vaidish Sumaria, Luan Nguyen, Franklin Tao, Philippe Sautet

2022Journal of the American Chemical Society53 citationsDOIOpen Access PDF

Abstract

Heterogeneous catalysis is key for chemical transformations. Understanding how catalysts' active sites dynamically evolve at the atomic scale under reaction conditions is a prerequisite for accurately determining catalytic mechanisms and predictably developing catalysts. We combine in situ time-dependent scanning tunneling microscopy observations and machine-learning-accelerated first-principles atomistic simulations to uncover the mechanism of restructuring of Pt catalysts under a pressure of carbon monoxide (CO). We show that a high CO coverage at a Pt step edge triggers the formation of atomic protrusions of low-coordination Pt atoms, which then detach from the step edge to create sub-nano-islands on the terraces, where under-coordinated sites are stabilized by the CO adsorbates. The fast and accurate machine-learning potential is key to enabling the exploration of tens of thousands of configurations for the CO-covered restructuring catalyst. These studies open an avenue to achieve an atomic-scale understanding of the structural dynamics of more complex metal nanoparticle catalysts under reaction conditions.

Topics & Concepts

CatalysisChemistryAtomic unitsRestructuringCarbon monoxideChemical physicsNanotechnologyHeterogeneous catalysisNanoscopic scalePlatinumChemical engineeringMaterials scienceQuantum mechanicsFinanceEngineeringBiochemistryPhysicsEconomicsMachine Learning in Materials ScienceElectronic and Structural Properties of OxidesCatalytic Processes in Materials Science