Finite Temperature Behavior of Small Silicon and Tin Clusters: An Ab Initio Molecular Dynamics Study
Abstract
The finite temperature behavior of small Silicon (Si10, Si15, and Si20) and Tin (Sn10 and Sn20) clusters is studied using isokinetic Born-Oppenheimer molecular dynamics. The lowest equilibrium structures of all the clusters are built upon a highly stable tricapped trigonal prism unit which is seen to play a crucial role in the finite temperature behavior of these clusters. Thermodynamics of small tin clusters (Sn10 and Sn20) is revisited in light of the recent experiments on tin clusters of sizes 18-21 [G. A. Breaux et. al. Phys. Rev. B 71 073410 (2005)]. We have calculated heat capacities using multiple histogram technique for Si10, Sn10 and Si15 clusters. Our calculated specific heat curves have a main peak around 2300 K and 2200 K for Si10 and Sn10 clusters respectively. However, various other melting indicators such as root mean square bond length fluctuations, mean square displacements show that diffusive motion of atoms within the cluster begins around 650 K. The finite temperature behavior of Si10 and Sn10 is dominated by isomerization and it is rather difficult to discern the temperature range for transition region. On the other hand, Si15 does show a liquid like behavior over a short temperature range followed by the fragmentation observed around 1800 K. Finite temperature behavior of Si20 and Sn20 show that these clusters do not melt but fragment around 1200 K and 650 K respectively.
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