English

Random collapsibility and 3-sphere recognition

Geometric Topology 2019-10-24 v1 Computational Geometry

Abstract

A triangulation of a 33-manifold can be shown to be homeomorphic to the 33-sphere by describing a discrete Morse function on it with only two critical faces, that is, a sequence of elementary collapses from the triangulation with one tetrahedron removed down to a single vertex. Unfortunately, deciding whether such a sequence exist is believed to be very difficult in general. In this article we present a method, based on uniform spanning trees, to estimate how difficult it is to collapse a given 33-sphere triangulation after removing a tetrahedron. In addition we show that out of all 33-sphere triangulations with eight vertices or less, exactly 2222 admit a non-collapsing sequence onto a contractible non-collapsible 22-complex. As a side product we classify all minimal triangulations of the dunce hat, and all contractible non-collapsible 22-complexes with at most 1818 triangles. This is complemented by large scale experiments on the collapsing difficulty of 99- and 1010-vertex spheres. Finally, we propose an easy-to-compute characterisation of 33-sphere triangulations which experimentally exhibit a low proportion of collapsing sequences, leading to a heuristic to produce 33-sphere triangulations with difficult combinatorial properties.

Keywords

Cite

@article{arxiv.1509.07607,
  title  = {Random collapsibility and 3-sphere recognition},
  author = {João Paixão and Jonathan Spreer},
  journal= {arXiv preprint arXiv:1509.07607},
  year   = {2019}
}

Comments

18 pages, 6 figures

R2 v1 2026-06-22T11:05:10.946Z