Low-regularity Schrödinger map flow on high-dimensional periodic domains

Abstract

We study the initial-value problem for the Schrödinger map flow from flat torus Td into compact Kähler manifold N. When d ≥ 3 and N = S2, we establish local well-posedness in Hσx with σ> d/2 + 1/2. In this case, the evolution equation for the gradient of the solution reduces to a certain semilinear nonlinear Schrödinger equation (also known as modified Schrödinger map flow) when formulated in orthonormal frames. For general compact Kähler targets, we only obtain local well-posedness in Hσx with σ> d/2 + 5/6 due to the quasilinear nature of the flow, but in all dimensions d ≥ 2. To the best of our knowledge, this is the first low-regularity local well-posedness result for Schrödinger map flow in the periodic setting, which yields a gain of 1/2 derivatives for S2 targets and 1/6 derivatives for general Kähler targets compared to the classical results DW,M. The key ingredients of our method are an Lt, x2 bilinear estimate for the first case and an a priori Lt6Lx∞ estimate for the second case, which are both achieved by combining the mass/energy and momentum balance laws of the equation with a new type of div-curl lemma introduced by the second author.