English

Eigenvalue multiplicity and volume growth

Metric Geometry 2009-03-26 v2 Differential Geometry Group Theory

Abstract

Let GG be a finite group with symmetric generating set SS, and let c=maxR>0B(2R)/B(R)c = \max_{R > 0} |B(2R)|/|B(R)| be the doubling constant of the corresponding Cayley graph, where B(R)B(R) denotes an RR-ball in the word-metric with respect to SS. We show that the multiplicity of the kkth eigenvalue of the Laplacian on the Cayley graph of GG is bounded by a function of only cc and kk. More specifically, the multiplicity is at most exp((logc)(logc+logk))\exp((\log c)(\log c + \log k)). Similarly, if XX is a compact, nn-dimensional Riemannian manifold with non-negative Ricci curvature, then the multiplicity of the kkth eigenvalue of the Laplace-Beltrami operator on XX is at most exp(n2+nlogk)\exp(n^2 + n log k). The first result (for k=2k=2) yields the following group-theoretic application. There exists a normal subgroup NN of GG, with [G:N]α(c)[G : N] \leq \alpha(c), and such that NN admits a homomorphism onto the cyclic group ZMZ_M, where MGδ(c)M \geq |G|^{\delta(c)} and α(c),δ(c)>0\alpha(c), \delta(c) > 0 are explicit functions depending only on cc. This is the finitary analog of a theorem of Gromov which states that every infinite group of polynomial growth has a subgroup of finite index which admits a homomorphism onto the integers. This addresses a question of Trevisan, and is proved by scaling down Kleiner's proof of Gromov's theorem. In particular, we replace the space of harmonic functions of fixed polynomial growth by the second eigenspace of the Laplacian on the Cayley graph of GG.

Keywords

Cite

@article{arxiv.0806.1745,
  title  = {Eigenvalue multiplicity and volume growth},
  author = {James R. Lee and Yury Makarychev},
  journal= {arXiv preprint arXiv:0806.1745},
  year   = {2009}
}
R2 v1 2026-06-21T10:49:20.556Z