Abstract

We calculated the relative stabilities of carbon clusters with up to 60 atoms. Equilibrium geometries have been obtained by combining an adaptive simulated annealing method and a simple tight-binding-type Hamiltonian for total energies. We found that ${\mathrm{C}}_{\mathit{n}}$ clusters favor one-dimensional structures for n\ensuremath{\lesssim}20. For n\ensuremath{\gtrsim}20, closed fullerene cages show a larger stability than both the one-dimensional and two-dimensional structures (such as graphite flakes and buckled fullerene ``caps''). Isomers with linear and ``fullerene'' structure should coexist near the critical cluster size n\ensuremath{\approxeq}20. We find the ${\mathrm{C}}_{60}$ fullerene to be the most stable structure, with a binding energy of 6.99 eV/atom.