English

Extending canonical Monte Carlo methods II

Statistical Mechanics 2013-07-31 v1

Abstract

Previously, we have presented a methodology to extend canonical Monte Carlo methods inspired on a suitable extension of the canonical fluctuation relation C=β2<δE2>C=\beta^{2}<\delta E^{2}> compatible with negative heat capacities C<0C<0. Now, we improve this methodology by introducing a better treatment of finite size effects affecting the precision of a direct determination of the microcanonical caloric curve β(E)=S(E)/E\beta (E) =\partial S(E) /\partial E, as well as a better implementation of MC schemes. We shall show that despite the modifications considered, the extended canonical MC methods possibility an impressive overcome of the so-called \textit{super-critical slowing down} observed close to the region of a temperature driven first-order phase transition. In this case, the dependence of the decorrelation time τ\tau with the system size NN is reduced from an exponential growth to a weak power-law behavior τ(N)Nα\tau(N)\propto N^{\alpha}, which is shown in the particular case of the 2D seven-state Potts model where the exponent α=0.140.18\alpha=0.14-0.18.

Keywords

Cite

@article{arxiv.1002.2234,
  title  = {Extending canonical Monte Carlo methods II},
  author = {L. Velazquez and S. Curilef},
  journal= {arXiv preprint arXiv:1002.2234},
  year   = {2013}
}

Comments

Version submitted to JSTAT

R2 v1 2026-06-21T14:45:48.980Z