English

Riemannian manifolds with maximal eigenfunction growth

Analysis of PDEs 2013-01-29 v2

Abstract

On any compact Riemannian manifold (M,g)(M, g) of dimension nn, the L2L^2-normalized eigenfunctions {ϕλ}\{\phi_{\lambda}\} satisfy ϕλCλn12||\phi_{\lambda}||_{\infty} \leq C \lambda^{\frac{n-1}{2}} where Δϕλ=λ2ϕλ.-\Delta \phi_{\lambda} = \lambda^2 \phi_{\lambda}. The bound is sharp in the class of all (M,g)(M, g) since it is obtained by zonal spherical harmonics on the standard nn-sphere SnS^n. But of course, it is not sharp for many Riemannian manifolds, e.g. flat tori Rn/Γ\R^n/\Gamma. We say that SnS^n, but not Rn/Γ\R^n/\Gamma, is a Riemannian manifold with maximal eigenfunction growth. The problem which motivates this paper is to determine the (M,g)(M, g) with maximal eigenfunction growth. Our main result is that such an (M,g)(M, g) must have a point xx where the set Lx{\mathcal L}_x of geodesic loops at xx has positive measure in SxMS^*_x M. We show that if (M,g)(M, g) is real analytic, this puts topological restrictions on MM, e.g. only M=S2M = S^2 (topologically) in dimension 2 can possess a real analytic metric of maximal eigenfunction growth. We further show that generic metrics on any MM fail to have maximal eigenfunction growth. In addition, we construct an example of (M,g)(M, g) for which Lx{\mathcal L}_x has positive measure for an open set of xx but which does not have maximal eigenfunction growth, thus disproving a naive converse to the main result.

Keywords

Cite

@article{arxiv.math/0103172,
  title  = {Riemannian manifolds with maximal eigenfunction growth},
  author = {Christopher D. Sogge and Steve Zelditch},
  journal= {arXiv preprint arXiv:math/0103172},
  year   = {2013}
}

Comments

Corrected typos and added a couple of references