Polyhedral structure of maximal Gromov hyperbolic spaces with finite boundary
Abstract
The boundary ∂ X of a boundary continuous Gromov hyperbolic space X carries a natural Moebius structure on the boundary. For a proper, geodesically complete, boundary continuous Gromov hyperbolic space X, the boundary ∂ X equipped with its cross-ratio is a particular kind of quasi-metric space, called a quasi-metric antipodal space. Given a quasi-metric antipodal space Z, one may consider the family of all hyperbolic fillings of Z. In biswas2024quasi it was shown that this family has a unique upper bound M(Z) (with respect to a natural partial order on hyperbolic fillings of Z), which can be described explicitly in terms of the cross-ratio on Z. As shown in biswas2024quasi, the spaces M(Z) constitute a natural class of spaces called maximal Gromov hyperbolic spaces. A natural problem is to describe explicitly the maximal Gromov hyperbolic spaces X whose boundary ∂ X is finite. We show that for a maximal Gromov hyperbolic space X with boundary ∂ X of cardinality n, the space X is isometric to a finite polyhedral complex embedded in (Rn, ||·||∞) with cells of dimension at most n/2, given by attaching n half-lines to vertices of a compact polyhedral complex. In particular the geometry at infinity of X is trivial. The combinatorics of the polyhedral complex is determined by certain relations R ⊂ ∂ X × ∂ X on the boundary ∂ X, called antipodal relations. In biswas2024quasi it was shown that maximal Gromov hyperbolic spaces are injective metric spaces. We give a shorter, simpler proof of this fact in the case of spaces with finite boundary. We also consider the space of deformations of a maximal Gromov hyperbolic space with finite boundary, and define an associated Teichmuller space.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.