Macroscopic loops in the loop O(n) model at Nienhuis' critical point

Abstract

The loop O(n) model is a model for a random collection of non-intersecting loops on the hexagonal lattice, which is believed to be in the same universality class as the spin O(n) model. It has been predicted by Nienhuis that for 0 n 2 the loop O(n) model exhibits a phase transition at a critical parameter xc(n)=12+2-n. For 0<n 2, the transition line has been further conjectured to separate a regime with short loops when x<xc(n) from a regime with macroscopic loops when x xc(n). In this paper, we prove that for n∈ [1,2] and x=xc(n) the loop O(n) model exhibits macroscopic loops. This is the first instance in which a loop O(n) model with n≠ 1 is shown to exhibit such behaviour. A main tool in the proof is a new positive association (FKG) property shown to hold when n 1 and 0<x1n. This property implies, using techniques recently developed for the random-cluster model, the following dichotomy: either long loops are exponentially unlikely or the origin is surrounded by loops at any scale (box-crossing property). We develop a 'domain gluing' technique which allows us to employ Smirnov's parafermionic observable to rule out the first alternative when x=xc(n) and n∈[1,2].