Shift in critical temperature for random spatial permutations with cycle weights
Abstract
We examine a phase transition in a model of random spatial permutations which originates in a study of the interacting Bose gas. Permutations are weighted according to point positions; the low-temperature onset of the appearance of arbitrarily long cycles is connected to the phase transition of Bose-Einstein condensates. In our simplified model, point positions are held fixed on the fully occupied cubic lattice and interactions are expressed as Ewens-type weights on cycle lengths of permutations. The critical temperature of the transition to long cycles depends on an interaction-strength parameter . For weak interactions, the shift in critical temperature is expected to be linear in with constant of linearity . Using Markov chain Monte Carlo methods and finite-size scaling, we find . This finding matches a similar analytical result of Ueltschi and Betz. We also examine the mean longest cycle length as a fraction of the number of sites in long cycles, recovering an earlier result of Shepp and Lloyd for non-spatial permutations.
Cite
@article{arxiv.0912.4292,
title = {Shift in critical temperature for random spatial permutations with cycle weights},
author = {John Kerl},
journal= {arXiv preprint arXiv:0912.4292},
year = {2015}
}
Comments
v2 incorporated reviewer comments. v3 removed two extraneous figures which appeared at the end of the PDF.