Sharp Reilly-type inequalities for submanifolds in space forms

Abstract

Let M be an n(>2)-dimensional closed orientable submanifold in an (n+p)-dimensional space form Rn+p(c). We obtain an optimal upper bound for the second eigenvalue of a class of elliptic operators on M defined by LTf=-div(T∇ f), where T is a general symmetric, positive definite and divergence-free (1,1)-tensor on M. The upper bound is given in terms of an integration involving tr T and |HT|2, where tr T is the trace of the tensor T and HT=Σi=1nA(Tei,ei) is a normal vector field associated with T and the second fundamental form A of M. Furthermore, we give the sufficient and necessary conditions when the upper bound is attained. Our main theorem can be viewed as an extension of the famous `Reilly inequality'. The operator LT can be regarded as a natural generalization of the well-known operator Lr which is the linearized operator of the first variation of the (r+1)-th mean curvature for hypersurfaces in a space form. As applications of our main theorem, we generalize the results of Grosjean ([16]) and Li-Wang ([19]) for hypersurfaces to higher codimension case.