Embedded constant mean curvature hypersurfaces on spheres

Abstract

Let m>1 and n>1 be any pair of integers. In this paper we prove that if H is between the numbers (πm) and bm,n=(m2-2)n-1nm2-1, then, there exists a non isoparametric, compact embedded hypersurface in Sn+1 with constant mean curvature H that admits the group O(n)x Zm in their group of isometries, here O(n) is the set of n x n orthogonal matrices and Zm are the integers mod m. When m=2 and H is close to the boundary value 0, the hypersurfaces look like two very close n-dimensional spheres with two catenoid necks attached, similar to constructions made by Kapouleas. When m>2 and H is close to (πm), the hypersurfaces look like a necklets made out of m spheres with (m+1) catenoid necks attached, similar to constructions made by Butscher and Pacard. In general, when H is close to bm,n the hypersurface is close to an isoparametric hypersurface with the same mean curvature. As a consequence of the expression of these bounds for H, we have that every H different from 0,13 can be realized as the mean curvature of a non isoparametric CMC surface in S3. For hyperbolic spaces we prove that every non negative H can be realized as the mean curvature of an embedded CMC hypersurface in Hn+1, moreover we prove that when H>1 this hypersurface admits the group O(n)× Z in its group of isometries. Here Z are the integer numbers. As a corollary of the properties proven for these hypersurfaces, for any n> 5, we construct non isoparametric compact minimal hypersurfaces in Sn+1 which cone in Rn+2 is stable. Also, we will prove that the stability index of every non isoparametric minimal hypersurface with two principal curvatures in Sn+1 is greater than 2n+5.