Effect of geometric and electronic structures on the finite temperature behavior of Na58, Na57, and Na55 clusters

Abstract

An analysis of the evolutionary trends in the ground state geometries of Na55 to Na62 reveals Na58, an electronic closed--shell system, shows namely an electronically driven spherical shape leading to a disordered but compact structure. This structural change induces a strong connectivity of short bonds among the surface atoms as well as between core and surface atoms with inhomogeneous strength in the ground state geometry, which affects its finite--temperature behavior. By employing ab initio density--functional molecular dynamics, we show that this leads to two distinct features in specific heat curve compared to that of Na55: (1) The peak is shifted by about 100 K higher in temperature. (2) The transition region becomes much broader than Na55. The inhomogeneous distribution of bond strengths results in a broad melting transition and the strongly connected network of short bonds leads to the highest melting temperature of 375 K reported among the sodium clusters. Na57, which has one electron less than Na58, also possesses stronger short--bond network compared with Na55, resulting in higher melting temperature (350 K) than observed in Na55. Thus, we conclude that when a cluster has nearly closed shell structure not only geometrically but also electronically, it show a high melting temperature. Our calculations clearly bring out the size--sensitive nature of the specific heat curve in sodium clusters.

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