# Sharp phase transition for the random-cluster and Potts models via   decision trees

**Authors:** Hugo Duminil-Copin, Aran Raoufi, Vincent Tassion

arXiv: 1705.03104 · 2018-12-27

## TL;DR

This paper introduces a new inequality for decision trees on monotonic measures, leading to significant results on phase transitions and correlation decay in Potts and random-cluster models, with broad potential applications.

## Contribution

The paper generalizes the OSSS inequality to monotonic measures and applies it to derive new results on phase transitions and correlation decay in lattice spin and random-cluster models.

## Key findings

- Exponential decay of correlations below critical temperature in Potts models.
- Exact critical point formula for random-cluster models on planar graphs.
-  Short proof of critical points for square, triangular, and hexagonal lattices.

## Abstract

We prove an inequality on decision trees on monotonic measures which generalizes the OSSS inequality on product spaces. As an application, we use this inequality to prove a number of new results on lattice spin models and their random-cluster representations. More precisely, we prove that   1. For the Potts model on transitive graphs, correlations decay exponentially fast for $\beta<\beta_c$.   2. For the random-cluster model with cluster weight $q\geq1$ on transitive graphs, correlations decay exponentially fast in the subcritical regime and the cluster-density satisfies the mean-field lower bound in the supercritical regime.   3. For the random-cluster models with cluster weight $q\geq1$ on planar quasi-transitive graphs $\mathbb{G}$,   $$\frac{p_c(\mathbb{G})p_c(\mathbb{G}^*)}{(1-p_c(\mathbb{G}))(1-p_c(\mathbb{G}^*))}~=~q.$$ As a special case, we obtain the value of the critical point for the square, triangular and hexagonal lattices (this provides a short proof of the result of Beffara and Duminil-Copin [Probability Theory and Related Fields, 153(3-4):511--542, 2012]).   These results have many applications for the understanding of the subcritical (respectively disordered) phase of all these models. The techniques developed in this paper have potential to be extended to a wide class of models including the Ashkin-Teller model, continuum percolation models such as Voronoi percolation and Boolean percolation, super-level sets of massive Gaussian Free Field, and random-cluster and Potts model with infinite range interactions.

## Full text

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## Figures

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## References

36 references — full list in the complete paper: https://tomesphere.com/paper/1705.03104/full.md

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Source: https://tomesphere.com/paper/1705.03104