Hypersurfaces in non-flat Lorentzian space forms satisfying Lk=A+b

Abstract

We study hypersurfaces either in the De Sitter space 1n+1⊂1n+2 or in the anti De Sitter space 1n+1⊂2n+2 whose position vector satisfies the condition Lk=A+b, where Lk is the linearized operator of the (k+1)-th mean curvature of the hypersurface, for a fixed k=0,...,n-1, A is an (n+2)×(n+2) constant matrix and b is a constant vector in the corresponding pseudo-Euclidean space. For every k, we prove that when A is self-adjoint and b=0, the only hypersurfaces satisfying that condition are hypersurfaces with zero (k+1)-th mean curvature and constant k-th mean curvature, open pieces of standard pseudo-Riemannian products in 1n+1 (1m(r)×n-m(1-r2), m(-r)×n-m(1+r2), 1m(1-r2)×n-m(r), m(-r2-1)×n-m(r)), open pieces of standard pseudo-Riemannian products in 1n+1 (1m(-r)×n-m(r2-1), m(-1+r2)×1n-m(r), 1m(r2-1)×n-m(-r), m(-1-r2)×n-m(-r)) and open pieces of a quadratic hypersurface \x∈Mcn+1\;|\;Rx,x=d\, where R is a self-adjoint constant matrix whose minimal polynomial is t2+at+b, a2-4b≤ 0, and Mcn+1 stands for 1n+1⊂1n+2 or 1n+1⊂2n+2. When Hk is constant and b is a non-zero constant vector, we show that the hypersurface is totally umbilical, and then we also obtain a classification result (see Theorem 2).