On the compactness of the set of invariant Einstein metrics

Abstract

Let M = G/H be a connected simply connected homogeneous manifold of a compact, not necessarily connected Lie group G. We will assume that the isotropy H-module g/h has a simple spectrum, i.e. irreducible submodules are mutually non-equivalent. There exists a convex Newton polytope N=N(G,H), which was used for the estimation of the number of isolated complex solutions of the algebraic Einstein equation for invariant metrics on G/H (up to scaling). Using the moment map, we identify the space M1 of invariant Riemannian metrics of volume 1 on G/H with the interior of this polytope N. We associate with a point x ∈ ∂ N of the boundary a homogeneous Riemannian space (in general, only local) and we extend the Einstein equation to M1= N. As an application of the Aleksevsky--Kimel'fel'd theorem, we prove that all solutions of the Einstein equation associated with points of the boundary are locally Euclidean. We describe explicitly the set T⊂ ∂ N of solutions at the boundary together with its natural triangulation. Investigating the compactification M1 of M1, we get an algebraic proof of the deep result by B\"ohm, Wang and Ziller about the compactness of the set E1 ⊂ M1 of Einstein metrics. The original proof by B\"ohm, Wang and Ziller was based on a different approach and did not use the simplicity of the spectrum. In Appendix we consider the non-symmetric K\"ahler homogeneous spaces G/H with the second Betti number b2=1. We write the normalized volumes 2,6,20,82,344 of the corresponding Newton polytopes and discuss the number of complex solutions of the algebraic Einstein equation and the finiteness problem.