On the energy growth of some periodically driven quantum systems with shrinking gaps in the spectrum

Abstract

We consider quantum Hamiltonians of the form H(t)=H+V(t) where the spectrum of H is semibounded and discrete, and the eigenvalues behave as En~nα, with 0<α<1. In particular, the gaps between successive eigenvalues decay as nα-1. V(t) is supposed to be periodic, bounded, continuously differentiable in the strong sense and such that the matrix entries with respect to the spectral decomposition of H obey the estimate |V(t)m,n|<=ε*|m-n|-pmaxm,n-2γ for m!=n where ε>0, p>=1 and γ=(1-α)/2. We show that the energy diffusion exponent can be arbitrarily small provided p is sufficiently large and ε is small enough. More precisely, for any initial condition ∈ Dom(H1/2), the diffusion of energy is bounded from above as <H>(t)=O(tσ) where σ=α/(2p-1γ-1/2). As an application we consider the Hamiltonian H(t)=|p|α+ε*v(θ,t) on L2(S1,dθ) which was discussed earlier in the literature by Howland.