English

MICC: A tool for computing short distances in the curve complex

Geometric Topology 2015-08-14 v2

Abstract

The complex of curves C(Sg)\mathcal{C}(S_g) of a closed orientable surface of genus g2g \geq 2 is the simplicial complex having its vertices, C0(Sg)\mathcal{C}^0(S_g), are isotopy classes of essential curves in SgS_g. Two vertices co-bound an edge of the 11-skeleton, C1(Sg)\mathcal{C}^1(S_g), if there are disjoint representatives in SgS_g. A metric is obtained on C0(Sg)\mathcal{C}^0(S_g) by assigning unit length to each edge of C1(Sg)\mathcal{C}^1(S_g). Thus, the distance between two vertices, d(v,w)d(v,w), corresponds to the length of a geodesic---a shortest edge-path between vv and ww in C1(Sg)\mathcal{C}^1 (S_g). Recently, Birman, Margalit and the second author introduced the concept of {\em initially efficient geodesics} in C1(Sg)\mathcal{C}^1(S_g) and used them to give a new algorithm for computing the distance between vertices. In this note we introduce the software package MICC ({\em Metric in the Curve Complex}), a partial implementation of the initially efficient geodesic algorithm. We discuss the mathematics underlying MICC and give applications. In particular, we give examples of distance four vertex pairs, for g=2g=2 and 3. Previously, there was only one known example, in genus 22, due to John Hempel.

Cite

@article{arxiv.1408.4134,
  title  = {MICC: A tool for computing short distances in the curve complex},
  author = {Paul Glenn and William W. Menasco and Kayla Morrell and Matthew Morse},
  journal= {arXiv preprint arXiv:1408.4134},
  year   = {2015}
}

Comments

19 pages, 9 figures, Version 2 has updated figures and references

R2 v1 2026-06-22T05:32:37.426Z