Selection of calibrated subaction when temperature goes to zero in the discounted problem

Abstract

Consider T(x)= d \, x (mod 1) acting on S1, a Lipschitz potential A:S1 R, 0<λ<1 and the unique function bλ:S1 R satisfying bλ(x) = T(y)=x \ λ \, bλ(y) + A(y)\. We will show that, when λ 1, the function bλ- m(A)1-λ converges uniformly to the calibrated subaction V(x) = μ ∈ M ∫ S(y,x) \, d μ(y), where S is the Ma\~ne potential, M is the set of invariant probabilities with support on the Aubry set and m(A)= μ ∈ M ∫ A\,dμ. For β>0 and λ ∈ (0,1), there exists a unique fixed point uλ,β :S1 R for the equation euλ,β(x) = ΣT(y)=xeβ A(y) +λ uλ,β(y). It is known that as λ 1 the family e[uλ,β- uλ,β] converges uniformly to the main eigenfuntion φβ for the Ruelle operator associated to β A. We consider λ=λ(β), β(1-λ(β))+∞ and λ(β) 1, as β ∞. Under these hypothesis we will show that 1β(uλ,β-P(β A)1-λ) converges uniformly to the above V, as β ∞. The parameter β represents the inverse of temperature in Statistical Mechanics and β ∞ means that we are considering that the temperature goes to zero. Under these conditions we get selection of subaction when β ∞.