Finite Temperature Off-Diagonal Long-Range Order for Interacting Bosons

Abstract

Characterizing the scaling with the total particle number (N) of the largest eigenvalue of the one--body density matrix (λ0), provides informations on the occurrence of the off-diagonal long-range order (ODLRO) according to the Penrose-Onsager criterion. Setting λ0 NC0, then C0=1 corresponds to ODLRO. The intermediate case, 0<C0<1, corresponds for translational invariant systems to the power-law decaying of (non-connected) correlation functions and it can be seen as identifying quasi-long-range order. The goal of the present paper is to characterize the ODLRO properties encoded in C0 [and in the corresponding quantities Ck ≠ 0 for excited natural orbitals] exhibited by homogeneous interacting bosonic systems at finite temperature for different dimensions. We show that Ck ≠ 0=0 in the thermodynamic limit. In 1D it is C0=0 for non-vanishing temperature, while in 3D C0=1 (C0=0) for temperatures smaller (larger) than the Bose-Einstein critical temperature. We then focus our attention to D=2, studying the XY and the Villain models, and the weakly interacting Bose gas. The universal value of C0 near the Berezinskii--Kosterlitz--Thouless temperature TBKT is 7/8. The dependence of C0 on temperatures between T=0 (at which C0=1) and TBKT is studied in the different models. An estimate for the (non-perturbative) parameter entering the equation of state of the 2D Bose gases, is obtained using low temperature expansions and compared with the Monte Carlo result. We finally discuss a double jump behaviour for C0, and correspondingly of the anomalous dimension η, right below TBKT in the limit of vanishing interactions.