The hyperbolic mean curvature flow

TL;DR

This paper introduces the hyperbolic mean curvature flow, a geometric evolution equation for hypersurfaces driven by mean curvature, and analyzes its well-posedness, blow-up criteria, and solutions in specific cases.

Contribution

It develops a new hyperbolic geometric flow model, establishes local well-posedness, and provides criteria for finite-time blow-up and global solutions in one dimension.

Findings

Derives balance laws for the flow

Proves local well-posedness in Sobolev spaces

Establishes finite-time blow-up criteria

Abstract

We introduce a geometric evolution equation of hyperbolic type, which governs the evolution of a hypersurface moving in the direction of its mean curvature vector. The flow stems from a geometrically natural action containing kinetic and internal energy terms. As the mean curvature of the hypersurface is the main driving factor, we refer to this model as the hyperbolic mean curvature flow (HMCF). The case that the initial velocity field is normal to the hypersurface is of particular interest: this property is preserved during the evolution and gives rise to a comparatively simpler evolution equation. We also consider the case where the manifold can be viewed as a graph over a fixed manifold. Our main results are as follows. First, we derive several balance laws satisfied by the hypersurface during the evolution. Second, we establish that the initial-value problem is locally well-posed in Sobolev spaces; this is achieved by exhibiting a convexity property satisfied by the energy density which is naturally associated with the flow. Third, we provide some criteria ensuring that the flow will blow-up in finite time. Fourth, in the case of graphs, we introduce a concept of weak solutions suitably restricted by an entropy inequality, and we prove that a classical solution is unique in the larger class of entropy solutions. In the special case of one-dimensional graphs, a global-in-time existence result is established.