English

Trace Systoles and Sink Constant

Geometric Topology 2023-08-30 v2

Abstract

Let Σ\Sigma be a surface with χ(Σ)<0\chi (\Sigma) < 0, and a representation ρ\rho from the fundamental group π1(Σ)\pi_1 (\Sigma) into SL(2,C) \rm{SL} (2 , \mathbb{C}). We define the \emph{trace systole} of ρ\rho, denoted tys(ρ)\mathrm{tys} (\rho) as folows : tys(ρ)=inf{tr(ρ(γ)) , γπ1(S)\mboxessentialsimpleclosedcurve}\mathrm{tys} (\rho) = \inf \left\{ | \rm{tr} (\rho (\gamma)) | \ , \ \gamma \in \pi_1 (S) \mbox{ essential simple closed curve} \right\} When Σ\Sigma is endowed with an hyperbolic structure, the trace systole of the holonomy representation is naturally related to the usual systolic length of the hyperbolic surface, which is one of the motivation for this study. The function tys\mathrm{tys} is bounded on relative character varieties of Σ\Sigma, and in this article we compute explicitly the optimal bounds for the one-holed torus, the four-holed sphere and the non-orientable surface of genus 33. The proofs rely on the correspondance between representations of these surface groups and so-called Markoff maps which were introduced by Bowditch. From this, we infer various consequences on the optimal systolic inequalities of certain hyperbolic manifolds and also on non-Fuchsian representations for these surfaces.

Keywords

Cite

@article{arxiv.2201.09088,
  title  = {Trace Systoles and Sink Constant},
  author = {Frederic Palesi},
  journal= {arXiv preprint arXiv:2201.09088},
  year   = {2023}
}

Comments

28 pages, 2 figures

R2 v1 2026-06-24T08:58:40.612Z