Structure and stability of copper clusters: A tight-binding molecular dynamics study

Abstract

In this paper we propose a tight-binding molecular dynamics with parameters fitted to first-principles calculations on the smaller clusters and with an environment correction, to be a powerful technique for studying large transition/noble metal clusters. In particular, the structure and stability of $Cu_n$ clusters for $n=3-55$ are studied by using this technique. The results for small $Cu_n$ clusters ($n=3-9$) show good agreement with {\it ab initio} calculations and available experimental results. In the size range $10\le n \le 55$ most of the clusters adopt icosahedral structure which can be derived from the 13-atom icosahedron, the polyicosahedral 19-, 23-, and 26-atom clusters and the 55-atom icosahedron, by adding or removing atoms. However, a local geometrical change from icosahedral to decahedral structure is observed for $n = 40-44$ and return to the icosahedral growth pattern is found at $n=45$ which continues. Electronic "magic numbers" ($n=2$, 8, 20, 34, 40) in this regime are correctly reproduced. Due to electron pairing in HOMOs, even-odd alternation is found. A sudden loss of even-odd alternation in second difference of cluster binding energy, HOMO-LUMO gap energy and ionization potential is observed in the region $n\sim40$ due to structural change there. Interplay between electronic and geometrical structure is found.