On the Equivalence of Equilibrium and Freezing States in Dynamical Systems
Abstract
This paper is concerned with freezing phase transitions in general dynamical systems. A freezing phase transition is one in which, for a given potential φ, there exists some inverse temperature β0 > 0 such that for all α, β > β0, the collection of equilibrium states for α φ and β φ coincide. In this sense, below the temperature 1 / β0, the system "freezes" on a fixed collection of equilibrium states. We show that for a given invariant measure μ, it is no more restrictive that μ is the freezing state for some potential than it is for μ to be the equilibrium state for some potential. In fact, our main result applies to any collection of equilibrium states with the same entropy. In the case where the entropy map h is upper semi-continuous, we show any ergodic measure μ can be obtained as a freezing state for some potential. In this upper semi-continuous setting, we additionally show that the collection of potentials that freeze at a single state is dense in the space of all potentials. However, in the action setting where the dynamical system satisfies specification, the collection of potentials that do not freeze contains a dense Gδ.
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