Beats, broken-symmetry superfluid on a one dimensional anyon Hubbard model

Abstract

By using the density matrix renormalization group and mean field methods, the anyon Hubbard model is studied systematically on a one dimensional lattice. The model can be expressed as a Bose-Hubbard model with a density-dependent-phase term. When the phase angle is θ=0 or θ=π, the model will be equivalent to boson and pseudo fermion models, respectively. In the mean field frame, we find a broken-symmetry superfluid (BSF), in which the b(b) operators on the nearest neighborhood sites have exactly opposite directions and behave like a directed oscillation pattern. By the density matrix reorganization group method, in the broken-symmetry superfluid, both the real and imaginary parts of the correlation bibi+r behave according to a beat phenomenon with 0<θ<π in the form C0ei k r(-1)r or behave like waves with different wavelengths in the form C0ei k r. The distributions of the broken-symmetry superfluid phase and other phases are shown in the phase diagrams with different values of θ and the direct phase transition between the two types of superfluid is observed. The beats phenomenon is explained by double peaks of momentum distribution with two wave numbers k1 and k2 satisfying the condition k1-k2k1+k2<13, which are expected to be observed in the optical experiments.