Dynamical Amrein-Berthier Uncertainty for Fractional Schrödinger Flows

Abstract

We prove dynamical Amrein-Berthier uncertainty principles for fractional Schrödinger flows. For the free Hamiltonian H=(-Δ)α on L2(Rn), with α>12, we show that two--time localization on finite measure sets E,F forces the quantitative estimate equation* \|u(t)\|L2E,F,T,n,α \|u(0)\|L2(Ec) + \|u(T)\|L2(Fc), T≠0,\ t∈ R equation* for u(t)=e-itHu(0) at every time. The threshold α>12 is tied to the stationary phase structure of the fractional kernel. If α1 the sets can be arbitrary finite measure sets; if 12<α<1 we impose the finiteness of a natural interaction energy equation* Iγ(E,F) = ∫Rn × Rn 1F(x)|x-y|2γ1E(y)\,dx\,dy<∞, γ= n(1-α)2 α-1 equation* of the pair (E,F), essentially equivalent to a sufficiently fast joint decay of the measure of the sets at infinity. In particular, compact support at two distinct times is impossible for a nonzero solution. We also prove corresponding results for one dimensional fractional Hamiltonians (-∂x2+V)α under weighted scattering assumptions, and for higher order Hamiltonians (-Δ)m+V for suitable classes of decaying potentials V.