One-body dynamical correlation function of Lieb-Liniger model at finite temperature

The dynamical correlated properties of one-dimensional (1D) Bose gases provide profound understanding of novel physics emergent from collective excitations, for instance, the breakdown of off-diagonal long-range order, and the establishment of Tomonaga-Luttinger liquid (TLL) theory. However, due to the non-perturbative nature of 1D many-body systems, the exact evaluation of correlation functions is notoriously difficult. Here by means of form factor approach based on algebraic Bethe ansatz and numerics, we present a thorough study on the one-body dynamical correlation function (1BDCF) of the Lieb-Liniger model at finite temperature. The influence of thermal fluctuation and dynamical interaction on the behavior of 1BDCF has been demonstrated and analyzed from various perspectives, including the spectral distribution, the line-shape of 1BDCF, and the static correlations etc. The static correlation properties, i.e. the momentum distribution and one body density matrix are shown in good agreement with the TLL prediction.