Superconductivity at 52 K in hole-doped C60

Abstract

Superconductivity in electron-doped C60 was first observed almost ten years ago. The metallic state and superconductivity result from the transfer of electrons from alkaline or alkaline-earth ions to the C60 molecule, which is known to be a strong electron acceptor. For this reason, it is very difficult to remove electrons from C60 - yet one might expect to see superconductivity at higher temperatures in hole-doped than in electron-doped C60, because of the higher density of electronic states in the valence band than in the conduction band. We have used the technique of gate-induced doping in a field-effect transistor configuration to introduce significant densities of holes into C60. We observe superconductivity over an extended range of hole density, with a smoothly varying transition temperature T(c) that peaks at 52 K. By comparison with the well established dependence of T(c) on the lattice parameter in electron-doped C60, we anticipate that T(c) values significantly in excess of 100 K should be achievable in a suitably expanded, hole-doped C60 lattice.