First principles investigation of finite-temperature behavior in small sodium clusters

TL;DR

This study uses density-functional molecular dynamics to analyze the finite-temperature behavior of small sodium clusters, revealing size-dependent melting characteristics and irregular patterns consistent with experimental observations.

Contribution

It provides a detailed first-principles analysis of sodium cluster melting behavior across sizes 8 to 50, highlighting size-sensitive effects and transition signatures.

Findings

Small clusters (n=8,10) do not show melting signatures.

Larger clusters exhibit broad to sharp specific heat peaks indicating melting.

Size-sensitive effects are prominent in clusters n=40 to 55.

Abstract

A systematic and detailed investigation of the finite-temperature behavior of small sodium clusters, Na_n, in the size range of n= 8 to 50 are carried out. The simulations are performed using density-functional molecular-dynamics with ultrasoft pseudopotentials. A number of thermodynamic indicators such as specific heat, caloric curve, root-mean-square bond length fluctuation, deviation energy, etc. are calculated for each of the clusters. Size dependence of these indicators reveals several interesting features. The smallest clusters with n= 8 and 10, do not show any signature of melting transition. With the increase in size, broad peak in the specific heat is developed, which alternately for larger clusters evolves into a sharper one, indicating a solidlike to liquidlike transition. The melting temperatures show irregular pattern similar to experimentally observed one for larger clusters [ M. Schmidt et al., Nature (London) 393, 238 (1998) ]. The present calculations also reveal a remarkable size-sensitive effect in the size range of n= 40 to 55. While Na_40 and Na_55 show well developed peaks in the specific heat curve, Na_50 cluster exhibits a rather broad peak, indicating a poorly-defined melting transition. Such a feature has been experimentally observed for gallium and aluminum clusters [ G. A. Breaux et al., J. Am. Chem. Soc. 126, 8628 (2004); G. A.Breaux et al., Phys. Rev. Lett. 94, 173401 (2005) ].