Algebraic properties of bounded Killing vector fields

Abstract

In this paper, we consider a connected Riemannian manifold M where a connected Lie group G acts effectively and isometrically. Assume X∈g=Lie(G) defines a bounded Killing vector field, we find some crucial algebraic properties of the decomposition X=Xr+Xs according to a Levi decomposition g=r(g)+s, where r(g) is the radical, and s=scsnc is a Levi subalgebra. The decomposition X=Xr+Xs coincides with the abstract Jordan decomposition of X, and is unique in the sense that it does not depend on the choice of s. By these properties, we prove that the eigenvalues of ad(X):g→g are all imaginary. Furthermore, when M=G/H is a Riemannian homogeneous space, we can completely determine all bounded Killing vector fields induced by vectors in g. We prove that the space of all these bounded Killing vector fields, or equivalently the space of all bounded vectors in g for G/H, is a compact Lie subalgebra, such that its semi-simple part is the ideal csc(r(g)) of g, and its Abelian part is the sum of cc(r(g)) (snc) and all two-dimensional irreducible ad(r(g))-representations in cc(n)(snc) corresponding to nonzero imaginary weights, i.e. R-linear functionals λ:r(g)→ r(g)/n(g) →R-1, where n(g) is the nilradical.