English

Subspace stabilisers in hyperbolic lattices

Geometric Topology 2025-11-10 v10 Differential Geometry Group Theory Metric Geometry Number Theory

Abstract

This paper shows that immersed totally geodesic mm-dimensional suborbifolds of nn-dimensional arithmetic hyperbolic orbifolds correspond to finite subgroups of the commensurator whenever mn12m \geqslant \frac{n-1}{2}. We call such totally geodesic suborbifolds finite centraliser subspaces (or fc-subspaces) and use them to formulate an arithmeticity criterion for hyperbolic lattices. We show that a hyperbolic orbifold MM is arithmetic if and only if it has infinitely many fc-subspaces, and exhibit examples of non-arithmetic orbifolds that contain non-fc subspaces of codimension one. We provide an algebraic characterization of totally geodesically immersed suborbifolds of arithmetic hyperbolic orbifolds by analysing Vinberg's commensurability invariants. This allows us to construct examples with the property that the adjoint trace field of the geodesic suborbifold properly contains the adjoint trace field of the orbifold. The case of special interest is that of exceptional trialitarian 77-dimensional orbifolds. We show that every such orbifold contains a totally geodesic arithmetic hyperbolic 33-orbifold of exceptional type. Finally, we study arithmetic properties of orbifolds that descend to their totally geodesic suborbifolds, proving that all suborbifolds in a (quasi-)arithmetic orbifold are (quasi-)arithmetic.

Keywords

Cite

@article{arxiv.2105.06897,
  title  = {Subspace stabilisers in hyperbolic lattices},
  author = {Mikhail Belolipetsky and Nikolay Bogachev and Alexander Kolpakov and Leone Slavich},
  journal= {arXiv preprint arXiv:2105.06897},
  year   = {2025}
}

Comments

78 pages, 4 figures. Final version (to appear in J. Assoc. Math. Res.). The paper has been rewritten. What was Theorem 1.9, now becomes Theorem 1.2, and therefore all other theorems in the introduction have shifted: Thm 1.n -> 1.(n+1). Sections 2.2, 2.3, 2.4, 3.3, and 5 have been rewritten, and some proofs (e.g. of Theorems 1.8 & 1.9) have been simplified

R2 v1 2026-06-24T02:07:11.841Z