A holographic principle for the existence of parallel spinor fields and an inequality of Shi-Tam type

Abstract

Suppose that =∂ M is the n-dimensional boundary of a connected compact Riemannian spin manifold ( M,\;,\;) with non-negative scalar curvature, and that the (inward) mean curvature H of is positive. We show that the first eigenvalue of the Dirac operator of the boundary corresponding to the conformal metric \;,\;H=H2\;,\; is at least n/2 and equality holds if and only if there exists a parallel spinor field on M. As a consequence, if admits an isometric and isospin immersion φ with mean curvature H0 as a hypersurface into another spin Riemannian manifold M0 admitting a parallel spinor field, then equation HoloIneq ∫ H\,d ∫ H20H\, d equation and equality holds if and only if both immersions have the same shape operator. In this case, has to be also connected. In the special case where M0=n+1, equality in (HoloIneq) implies that M is an Euclidean domain and φ is congruent to the embedding of in M as its boundary. We also prove that Inequality (HoloIneq) implies the Positive Mass Theorem (PMT). Note that, using the PMT and the additional assumption that φ is a strictly convex embedding into the Euclidean space, Shi and Tam ST1 proved the integral inequality equationshi-tam-Ineq ∫ H\,d ∫ H0\, d, equation which is stronger than (HoloIneq) .