Equilibrium states and growth of quasi-lattice ordered monoids

TL;DR

This paper investigates the equilibrium states of a C*-dynamical system derived from quasi-lattice ordered monoids, establishing a critical inverse temperature and linking it to algebraic properties like the clique polynomial and growth series.

Contribution

It provides a novel analysis of KMS states for these systems, connecting equilibrium states to algebraic invariants and proving an inversion formula for the growth series.

Findings

Existence of a critical inverse temperature 2_c with unique KMS states above it

KMS states above 2_c are faithful Type I states with analytic density operators

2_c is the smallest pole of the growth series and related to the clique polynomial

Abstract

Each multiplicative real-valued homomorphism on a quasi-lattice ordered monoid gives rise to a quasi-periodic dynamics on the associated Toeplitz C*-algebra; here we study the KMS equilibrium states of the resulting C*-dynamical system. We show that, under a nondegeneracy assumption on the homomorphism, there is a critical inverse temperature $\beta_c$ such that at each inverse temperature $\beta \geq \beta_c$ there exists a unique KMS state. Strictly above $\beta_c$, the KMS states are generalised Gibbs states with density operators determined by analytic extension to the upper half-plane of the unitaries implementing the dynamics. These are faithful Type~I states. The critical value $\beta_c$ is the largest real pole of the partition function of the system and is related to the clique polynomial and skew-growth function of the monoid, relative to the degree map given by the logarithm of the multiplicative homomorphism. Motivated by the study of equilibrium states, we give a proof of the inversion formula for the growth series of a quasi-lattice ordered monoid in terms of the clique polynomial as in recent work of Albenque--Nadeau and McMullen for the finitely generated case, and in terms of the skew-growth series as in recent work of Saito. Specifically, we show that $e^{-\beta_c}$ is the smallest pole of the growth series and thus is the smallest positive real root of the clique polynomial. We use this to show that equilibrium states in the subcritical range can only occur at inverse temperatures that correspond to roots of the clique polynomial in the interval $(e^{-\beta_c},1)$, but we are not aware of any examples in which such roots exist.