English

On the Poisson relation for compact Lie groups

Differential Geometry 2016-06-24 v1 Spectral Theory

Abstract

Intuition drawn from quantum mechanics and geometric optics raises the following long-standing question: can the length spectrum of a closed Riemannian manifold be recovered from its Laplace spectrum? The Poisson relation states that for any closed Riemannian manifold (M,g)(M,g) the singular support of the trace of its wave group---a spectrally determined tempered distribution---is contained in the set consisting of ±τ\pm \tau, where τ\tau is the length of a smoothly closed geodesic in (M,g)(M,g). Therefore, in cases where the Poisson relation is an equality, we obtain a method for retrieving the length spectrum of a manifold from its Laplace spectrum. The Poisson relation is known to be an equality for sufficiently "bumpy" Riemannian manifolds and there are no known counterexamples. We demonstrate that the Poisson relation is an equality for a compact Lie group equipped with a generic bi-invariant metric. Consequently, the length spectrum of a generic bi-invariant metric (and the rank of its underlying Lie group) can be recovered from its Laplace spectrum. Furthermore, we exhibit a substantial collection G\mathscr{G} of compact Lie groups---including those that are either tori, simple, simply-connected, or products thereof---with the property that for each group UGU \in \mathscr{G} the Laplace spectrum of any bi-invariant metric gg carried by UU encodes the length spectrum of gg and the rank of UU. The preceding statements are special cases of results concerning compact globally symmetric spaces for which the semi-simple part of the universal cover is split-rank. The manifolds considered herein join a short list of families of non-"bumpy" Riemannian manifolds for which the Poisson relation is known to be an equality.

Keywords

Cite

@article{arxiv.1606.07426,
  title  = {On the Poisson relation for compact Lie groups},
  author = {Craig J. Sutton},
  journal= {arXiv preprint arXiv:1606.07426},
  year   = {2016}
}

Comments

63 pages

R2 v1 2026-06-22T14:32:55.740Z