Structural, Vibrational and Thermodynamic Properties of AgnCu34-n Nanoparticles

TL;DR

This study systematically investigates the structural, vibrational, and thermodynamic properties of 34-atom Ag-Cu bimetallic nanoparticles, revealing trends related to composition, bond lengths, vibrational modes, and Debye temperature.

Contribution

It provides a detailed analysis of how composition affects properties of Ag-Cu nanoparticles using embedded atom method and harmonic lattice dynamics, highlighting new structural and vibrational insights.

Findings

Bond length increases with more silver atoms.

Nanoparticles divide into two groups based on copper atom bond lengths.

Vibrational modes are above bulk bands, with a blue shift as copper content increases.

Abstract

We report results of a systematic study of structural, vibrational and thermodynamical properties of 34-atom bimetallic nanoparticles from the AgnCu34-n family using model interaction potentials as derived from the embedded atom method and in the harmonic approximation of lattice dynamics. Systematic trends in the bond length and dynamical properties can be explained largely on arguments based on local coordination and elemental environment. Thus increase in the number of silver atoms in a given neighborhood introduces a monotonic increase in bond length while increase of the copper content does the reverse. Moreover, based on bond lengths of the lowest coordinated (6 and 8) copper atoms with their nearest neighbors (Cu atoms), we find that the nanoparticles divide into two groups with average bond length either close to (~ 2.58 A) or smaller (~ 2.48 A) than that in bulk copper, accompanied by characteristic features in their vibrational density of states. For the entire set of nanoparticles, vibrational modes are found above the bulk bands of copper/silver. Furthermore, a blue shift in the high frequency end with increasing number of copper atoms in the nanoparticles is traced to a shrinkage of bond lengths from bulk values. The vibrational densities of states at the low frequency end of the spectrum scale linearly with frequency as for single element nanoparticles, however, the effect is more pronounced for these nanoalloys. The Debye temperature was found to be about one third of that of the bulk for pure copper and silver nanoparticles with a non-linear increase with increasing number of copper atoms in the nanoalloys.