Long-time propagation of coherent states in a normally hyperbolic setting

Abstract

We present a method to find asymptotics for the evolution of coherent states (or Gaussian wavepackets with standard deviation h) under semiclassical Schr\"odinger's equation for a given Hamiltonian. These results extend the work of Combescure and Robert, in which the evolution of coherent states can be approximated in the limit h 0 with deformed Gaussian wavepackets called squeezed coherent states. The description with squeezed states holds for times t that can go to infinity as h 0, under the constraint |t|≤ | h|/(6λ0) where λ0 is the maximal Lyapunov exponent of the classical dynamics. The breakdown of this approximation at time | h|/(6λ0) is related to the bending of evolved wavepackets: once propagated states spread at a scale h1/3, squeezed states no longer provide an appropriate description. To obtain a representation of propagated states valid up to times |t|≤ C| h| with a larger C (for instance, up to Ehrenfest's time | h|/(2λ0) where spreading on macroscopic scales is allowed), we make additional assumptions on the flow t associated to the classical dynamics, imposing constraints on directions of elongation. Namely, we work in a neighborhood of a normally hyperbolic t-invariant submanifold K, on which the dynamics is considered as slow in comparison with its transverse directions, along which t is assumed to be hyperbolic. In this context, we describe the propagated state as a WKB state in transverse directions and a squeezed state along K. This description emphasizes the fact that propagated states should no longer be thought of as microlocalized on a point, but rather on an isotropic submanifold (corresponding to transverse unstable directions). Guillemin, Uribe, and Wang presented a similar class of wavefunctions microlocalized on an isotropic submanifold.