On time dependent Schr{ö}dinger equations: global well-posedness and growth of Sobolev norms

Abstract: In this paper we consider time dependent Schr{\"o}dinger linear PDEs of the form i$\partial$t$\psi$ = L(t)$\psi$, where L(t) is a continuous family of self-adjoint operators. We give conditions for well-posedness and polynomial growth for the evolution in abstract Sobolev spaces. If L(t) = H + V (t) where V (t) is a perturbation smooth in time and H is a self-adjoint positive operator whose spectrum can be enclosed in spectral clusters whose distance is increasing, we prove that the Sobolev norms of the solution grow at most as t $\epsilon$ when t $\rightarrow$ $\infty$, for any $\epsilon$ \textgreater{} 0. If V (t) is analytic in time we improve the bound to (log t) $\gamma$ , for some $\gamma$ \textgreater{} 0. The proof follows the strategy, due to Howland, Joye and Nenciu, of the adiabatic approximation of the flow. We recover most of known results and obtain new estimates for several models including 1-degree of freedom Schr{\"o}dinger operators on R and Schr{\"o}dinger operators on Zoll manifolds.