Metal-insulator transition and superconductivity in the two-orbital Hubbard-Holstein model for iron-based superconductors

Abstract

We investigate a two-orbital model for iron-based superconductors to elucidate the effect of interplay between electron correlation and Jahn-Teller electron-phonon coupling by using the dynamical mean-field theory combined with the exact diagonalization method. When the intra- and inter-orbital Coulomb interactions, U and U', increase with U=U', both the local spin and orbital susceptibilities, s and o, increase with s=o in the absence of the Hund's rule coupling J and the electron-phonon coupling g. In the presence of J and g, there are distinct two regimes: for J > 2g2/ω0 with the phonon frequency ω0, s is enhanced relative to o and shows a divergence at J=Jc above which the system becomes Mott insulator, while for J < 2g2/ω0, o is enhanced relative to s and shows a divergence at g=gc above which the system becomes bipolaronic insulator. In the former regime, the superconductivity is mediated by antiferromagnetic fluctuations enhanced due to Fermi-surface nesting and is found to be largely dependent on carrier doping. On the other hand, in the latter regime, the superconductivity is mediated by ferro-orbital fluctuations and is observed for wide doping region including heavily doped case without the Fermi-surface nesting.