Singularities and Topological Change for Deforming Domains in Manifolds

Abstract

Given a C0-deformation of domains D(t) in a manifold Mn, allowing the topological type of the domains D(t) to vary with t, in what situations do the analysis objects associated with D(t) remain continuous in t, so that analysis techniques continue to work along the deformation? This type of problem was studied in our previous work [Hw] for domains on constant mean curvature (CMC) hypersurfaces in Rn+1. In the present paper, we consider a general setting in which the deforming domains are situated in an arbitrary smooth manifold Mn equipped with a self-adjoint strongly elliptic operator L, replacing the stability operator for CMC hypersurfaces in Rn+1 considered in [Hw]. We introduce the notion of quasi-Lipschitz domains by gluing certain boundary points of a Lipschitz domain in a specific manner, thereby allowing the topology of the deforming domain D(t) to change. It is established that any "appropriate" monotone C0-deformation on Mn (see Definition 1.1) satisfies Sobolev continuity and eigenvalue continuity for the operator L along the deformation parameter t. As a consequence, a "global" Morse index theorem is obtained. Furthermore, given an arbitrary Lipschitz domain D in Mn, we construct a C0-deformation from a small n-ball to the domain D, along which the topology of D(t) may change, while the required continuity properties continue to hold. Consequently, the Morse index theorem remains valid as well.