Article ID Journal Published Year Pages File Type
49660 Catalysis Communications 2014 6 Pages PDF
Abstract

•A GC-MC/MD hybrid method evaluates the in situ nanoparticle phase.•A surface oxide phase forms on Pd nanoparticles during oxidation catalysis.•A subsurface carbide phase forms under acetylene selective hydrogenation conditions.

Catalyst design requires a detailed understanding of the structure of the catalyst surface as a function of varying reaction conditions. Here we demonstrate the capability of a grand canonical Monte Carlo/molecular dynamics (GC-MC/MD) method utilizing the ReaxFF potential to predict nanoparticle structure and phase stability as a function of temperature and pressure. This is demonstrated for Pd nanoparticles, which readily form oxide, hydride, and carbide phases under reaction environments, impacting catalytic behavior. The approach presented here can be extended to other catalytic systems, providing a new tool for exploring the effects of reaction conditions on catalyst activity, selectivity, and stability.

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Related Topics
Physical Sciences and Engineering Chemical Engineering Catalysis
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