Surface Segregation in AgAuCuPdPt High Entropy Alloy: Insights From Molecular Simulations

17 February 2022, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

High entropy alloys (HEAs) are emerging as a novel class of superior catalysts for diverse chemical conversions. The activity of a catalyst is intimately related to the composition and atomic structure at its surface. In this work, we used embedded atom (EAM) potential based Monte Carlo – Molecular Dynamics simulations to study surface segregation in the equimolar AuAgCuPdPt HEA, that was recently shown to be an efficient catalyst for CO2 electrochemical reduction. Firstly, EAM potentials were extensively validated against experimental segregation data for several different binary and ternary compositions. Subsequently, simulations on the HEA were carried out for four different surface orientations, spherical and cubical nanoparticles, to obtain detailed structural and concentration profiles normal to the surface. In all cases, Ag atoms were found to preferentially segregate to the surface while the subsurface layer mainly consisted of Au atoms. No Pt atoms were found on the surface layer for all systems. A detailed analysis neighborhood of each surface site revealed that the atoms formed a finite number of chemically unique clusters. The percentage of chemically unique sites were larger for elements with lower concentration at the surface. Together with the physical diversity surrounding each site, the enrichment of one or more element(s) at the surface also increased its number of unique catalytically active sites. Results from our work suggest that HEAs are prone to surface segregation and such effects must be taken into consideration while modeling the surface chemistry of these materials.

Keywords

surface segregation
hybrid MC/MD simulations
nanoscale clustering
High entropy alloy catalyst

Supplementary materials

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Title
Surface Segregation in AgAuCuPdPt High Entropy Alloy: Insights From Molecular Simulations
Description
Evolved surface structures of the binary and ternary alloys, variation of HEA surface composition with number of MC swaps/atom, evolved structures of the HEA surfaces, distribution of various unique chemical neighborhoods on different HEA surfaces, fully tabulated results of the cluster analysis, computed atomic strain and binary mixing enthalpies are provided in the supporting information.
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