Effect of equivalent sites on the dynamics of bimetallic nanoparticles
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Using a Sutton and Chen interatomic potential, we study the molecular dynamics of Au-Pd nanoparticles with an initial icosahedral structure at different temperatures and concentrations, where each relative concentration of the 561-atom particles was made by placing atoms of the same species at equivalent sites, in order to identify under which conditions the melting transition temperature appears for each particle. In addition, we compute global order parameters in order to correlate the obtained results with the caloric curves of each particle. As a result, we observe that the melting transition temperature depends on the relative atomic positions of gold and palladium. The melting transition temperature of the Au-Pd alloy particles appears at higher temperature than that of the pure-gold particle. From the analysis of the structure of the particles, we found that the melting temperature increases with the proportion of gold atoms, and for those particles with a higher concentration of palladium on the surface, we observe an early migration of gold atoms before the melting transition temperature appears. © 2012 Materials Research Society.
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Gold; Molecular dynamics; Nanoparticles; Palladium Atomic positions; Bimetallic nanoparticles; Icosahedral structure; Interatomic potential; Melting transitions; Order parameter; Relative concentration; Temperature increase; Atoms; Melting; Molecular dynamics; Nanoparticles; Palladium; Temperature; Gold
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