Bose-Einstein Condensation Temperature of a Homogeneous Weakly Interacting Bose Gas : PIMC study
Abstract
Using a finite-temperature Path Integral Monte Carlo simulation (PIMC) method and finite-size scaling, we have investigated the interaction-induced shift of the phase transition temperature for Bose-Einstein condensation of homogeneous weakly interacting Bose gases in three dimensions, which is given by a proposed analytical expression Tc = Tc0\1 + c1an1/3+[c'2(an1/3)+c''2]a2n2/3 +O(a3n)\, where Tc0 is the critical temperature for an ideal gas, a is the s-wave scattering length, and n is the number density. We have used smaller number densities and more time slices than in the previous PIMC simulations [Gruter et al., Phys. Rev. Lett. 79, 3549 (1997)] in order to understand the difference in the value of the coefficient c1 between their results and the (apparently) other reliable results in the literature. Our results show that \(Tc-Tc0)/Tc0\/(an1/3) depends strongly on the interaction strength an1/3 while the previous PIMC results are considerably flatter and smaller than our results. We obtain c1 = 1.32 0.14, in agreement with results from recent Monte Carlo methods of three-dimensional O(2) scalar φ4 field theory and variational perturbation theory.
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