English

Counting Salem numbers arising from arithmetic hyperbolic orbifolds

Number Theory 2026-03-27 v2 Differential Geometry Group Theory Geometric Topology

Abstract

The relationship between Salem numbers and short geodesics has been fruitful in quantitative studies of arithmetic hyperbolic orbifolds, particularly in dimensions 2 and 3. In this article, we push these connections even further. The primary goals are: (1) to bound the proportion of Salem numbers of degree up to n+1n+1 in the commensurability class of classical arithmetic lattices in any odd dimension nn; (2) to improve lower bounds for the strong exponential growth of averages of multiplicities in the geodesic length spectrum of non-compact arithmetic orbifolds. In order to accomplish these goals, we bound, for a fixed square-free integer DD, the count of Salem numbers with minimal polynomial ff satisfying f(1)f(1)=Df(1)f(-1)=-D in Q×/Q×2\mathbb{Q}^{\times}/\mathbb{Q}^{\times 2}. To do this, we make use of results on the distribution of Salem numbers, as well as classical methods for counting Pythagorean triples and Gauss' lattice-counting argument. To this end, we give a generalization of the count of Pythagorean triples and provide an elementary proof which may be of independent interest.

Keywords

Cite

@article{arxiv.2508.08003,
  title  = {Counting Salem numbers arising from arithmetic hyperbolic orbifolds},
  author = {Michelle Chu and Plinio G. P. Murillo and Otto Romero and Lola Thompson},
  journal= {arXiv preprint arXiv:2508.08003},
  year   = {2026}
}

Comments

19 pages

R2 v1 2026-07-01T04:44:23.848Z