Optimized broad-histogram simulations for strong first-order phase transitions: Droplet transitions in the large-Q Potts model

Details Optimized broad-histogram simulations for strong first-order phase transitions: Droplet transitions in the large-Q Potts model Optimized broad-histogram simulations for strong first-order phase transitions: Droplet transitions in the large-Q Potts model

2009-12-07

arxiv.org/abs/0912.1192v2

J. Stat. Mech. P01020 (2010)

Physics

Condensed Matter

Statistical Mechanics

11 pages, 12 figures

Scientific paper

10.1088/1742-5468/2010/01/P01020

The numerical simulation of strongly first-order phase transitions has remained a notoriously difficult problem even for classical systems due to the exponentially suppressed (thermal) equilibration in the vicinity of such a transition. In the absence of efficient update techniques, a common approach to improve equilibration in Monte Carlo simulations is to broaden the sampled statistical ensemble beyond the bimodal distribution of the canonical ensemble. Here we show how a recently developed feedback algorithm can systematically optimize such broad-histogram ensembles and significantly speed up equilibration in comparison with other extended ensemble techniques such as flat-histogram, multicanonical or Wang-Landau sampling. As a prototypical example of a strong first-order transition we simulate the two-dimensional Potts model with up to Q=250 different states on large systems. The optimized histogram develops a distinct multipeak structure, thereby resolving entropic barriers and their associated phase transitions in the phase coexistence region such as droplet nucleation and annihilation or droplet-strip transitions for systems with periodic boundary conditions. We characterize the efficiency of the optimized histogram sampling by measuring round-trip times tau(N,Q) across the phase transition for samples of size N spins. While we find power-law scaling of tau vs. N for small Q \lesssim 50 and N \lesssim 40^2, we observe a crossover to exponential scaling for larger Q. These results demonstrate that despite the ensemble optimization broad-histogram simulations cannot fully eliminate the supercritical slowing down at strongly first-order transitions.

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