Strong-Coupling Theory of Rattling-Induced Superconductivity

Abstract

In order to clarify the mechanism of the enhancement of superconducting transition temperature T c due to anharmonic local oscillation of a guest ion in a cage composed of host atoms, i.e., rattling, we analyze the anharmonic Holstein model by applying the Migdal-Eliashberg theory. From the evaluation of the normal-state electron-phonon coupling constant, it is found that the strong coupling state is developed, when the bottom of a potential for the guest ion becomes wide and flat. Then, T c is enhanced with the increase of the anharmonicity in the potential, although T c is rather decreased when the potential becomes a double-well type due to very strong anharmonicity. From these results, we propose a scenario of anharmonicity-controlled strong-coupling tendency for superconductivity induced by rattling. We briefly discuss possible relevance of the present scenario with superconductivity in β-pyrochlore oxides.