Excitation spectrum and momentum distribution of the ionic Bose-Hubbard model

We investigate the excitation spectrum and momentum distribution of the ionic Bose-Hubbard model by the standard basis operator method. We derive Green's functions in the random phase approximation in Mott insulator, superfluid, charge density wave, and supersolid phases. The excitation spectrum has gapped modes and gapless Goldstone modes in the superfluid and supersolid phases. We show that the momentum distribution has a peak at the zone corner in the supersolid phase and the charge density wave phase close to the phase boundary. In addition, we demonstrate that the momentum distribution can be explained by the excitation spectrum and spectral weights of hole excitation modes.

Automated summary

We investigate the excitation spectrum and momentum distribution of the ionic Bose-Hubbard model and derive Green's functions in different phases. The excitation spectrum has gapped and gapless modes in the superfluid and supersolid phases. The momentum distribution shows a peak at the zone corner in the supersolid phase and the charge density wave phase near the phase boundary, which can be explained by the excitation spectrum and spectral weights of hole modes.