Semiclassical limits, Lagrangian states and coboundary equations

Abstract

Assume that f is a continuous transformation f:S1 S1. We consider here the cases where f is either the transformation f(z)=z2 or f is a smooth diffeomorphism of the circle S1. Consider a fixed continuous potential τ:S1=[0,1) R, ∈ R and :S1 C (a quantum state). The transformation F acting on :S1 C, F() = φ, defined by φ(z) = F ((z)) = (f(z))eiτ(z) describes a discrete time dynamical evolution of the quantum state . Given S: R R we define the Lagrangian state xS(z) = Σk∈Z eiS (z-k) e-(z-k-x)24. In this case F(xS(z)) = Σk∈ZeiS (f(z)-k)e-(f(z)-k-x)24eiτ(z). Under suitable conditions on S the micro-support of Sx (z), when 0, is (x,S'(x)). One of meanings of the semiclassical limit in Quantum Mechanics is to take =1 and 0. We address the question of finding S such that Sx satisfies the property: ∀ x, we have that F(Sx) has micro-support on the graph of y S'(y) (which is the micro-support of Sx). In other words: which S is such that F leaves the micro-support of Sx invariant? This is related to a coboundary equation for τ, twist conditions and the boundary of the fat attractor.