English

Bridges in the random-cluster model

Statistical Mechanics 2016-01-28 v3 High Energy Physics - Lattice Mathematical Physics math.MP

Abstract

The random-cluster model, a correlated bond percolation model, unifies a range of important models of statistical mechanics in one description, including independent bond percolation, the Potts model and uniform spanning trees. By introducing a classification of edges based on their relevance to the connectivity we study the stability of clusters in this model. We derive several exact relations for general graphs that allow us to derive unambiguously the finite-size scaling behavior of the density of bridges and non-bridges. For percolation, we are also able to characterize the point for which clusters become maximally fragile and show that it is connected to the concept of the bridge load. Combining our exact treatment with further results from conformal field theory, we uncover a surprising behavior of the variance of the number of (non-)bridges, showing that these diverge in two dimensions below the value 4cos2(π/3)=0.23158914\cos^2{(\pi/\sqrt{3})}=0.2315891\cdots of the cluster coupling qq. Finally, it is shown that a partial or complete pruning of bridges from clusters enables estimates of the backbone fractal dimension that are much less encumbered by finite-size corrections than more conventional approaches.

Keywords

Cite

@article{arxiv.1509.00668,
  title  = {Bridges in the random-cluster model},
  author = {Eren Metin Elçi and Martin Weigel and Nikolaos G. Fytas},
  journal= {arXiv preprint arXiv:1509.00668},
  year   = {2016}
}

Comments

final version as published

R2 v1 2026-06-22T10:47:24.615Z