Constant higher order mean curvature hypersurfaces in Riemannian spaces

TL;DR

This paper explores the geometry of hypersurfaces with constant higher order mean curvature in Riemannian spaces, extending symmetry results to hyperbolic space and spheres, and analyzing boundary relationships in a general geometric context.

Contribution

It generalizes previous results on constant mean curvature hypersurfaces to those with constant higher order r-mean curvature in various Riemannian ambient spaces.

Findings

Extended symmetry results to hyperbolic space and spheres.

Analyzed boundary geometry relationships in Riemannian manifolds.

Derived conditions relating hypersurface and boundary geometries.

Abstract

It is still an open question whether a compact embedded hypersurface in the Euclidean space R^{n+1} with constant mean curvature and spherical boundary is necessarily a hyperplanar ball or a spherical cap, even in the simplest case of surfaces in R^3. In a recent paper the first and third authors have shown that this is true for the case of hypersurfaces in R^{n+1} with constant scalar curvature, and more generally, hypersurfaces with constant higher order r-mean curvature, when r>1. In this paper we deal with some aspects of the classical problem above, by considering it in a more general context. Specifically, our starting general ambient space is an orientable Riemannian manifold, where we will consider a general geometric configuration consisting of an immersed hypersurface with boundary on an oriented hypersurface P. For such a geometric configuration, we study the relationship between the geometry of the hypersurface along its boundary and the geometry of its boundary as a hypersurface of P, as well as the geometry of P. Our approach allows us to derive, among others, interesting results for the case where the ambient space has constant curvature. In particular, we are able to extend the previous symmetry results to the case of hypersurfaces with constant higher order r-mean curvature in the hyperbolic space and in the sphere.