Bose one-component plasma in 2D: a Monte Carlo study
Abstract
The low-temperature properties of a 2D Bose fluid of charged particles interacting through a 1/r potential, moving in the presence of a uniform neutralizing background, is studied by Quantum Monte Carlo simulations. We make use of the Modified Periodic Coulomb potential formalism to account for the long-range character of the interaction, and explore a range of density corresponding to average interparticle separation . We report numerical results based on simulations of system comprising up to 2304 particles. We find a superfluid ground state for as large as 70, i.e., significantly above the most recent numerical estimate of the Wigner crystallization threshold, which we estimate at . Furthermore, no thermally re-entrant crystalline phase nor any evidence of metastable bubbles is observed near the transition, in contrast with a previous theoretical study in which quantum statistics was neglected. The computed superfluid transition temperature depends remarkably weakly on density.
Cite
@article{arxiv.2512.10216,
title = {Bose one-component plasma in 2D: a Monte Carlo study},
author = {Massimo Boninsegni},
journal= {arXiv preprint arXiv:2512.10216},
year = {2026}
}
Comments
Replaced with published version