Local well-posedness of the skew mean curvature flow for large data

Abstract

The skew mean curvature flow is an evolution equation for d dimensional ma\-nifolds embedded in Rd+2 (or more generally, in a Riemannian manifold). It can be viewed as a Schr\"odinger analogue of the mean curvature flow, or alternatively as a quasilinear version of the Schr\"odinger Map equation. In this article, we prove large data local well-posedness in low-regularity Sobolev spaces for the skew mean curvature flow in dimension d≥ 2. This is achieved by introducing several new ideas: (i) a time discretization method to establish the existence of smooth solutions, (ii) constructing the orthonormal frame by a parallel transport method and a lifting criterion, (iii) introducing intrinsic fractional function spaces Xs⊂ Hs on a noncompact manifold for any s>d2, such that the Xs-norm of the second fundamental form can be propagated well along the quasilinear Schr\"odinger flow, (iv) deriving a difference equation to prove the uniqueness result for solutions F∈ C2, which is independent in the choices of gauge. Our method turns out to be more robust for large data problem.

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