How to make a triangulation of S3 polytopal
Abstract
We introduce a numerical isomorphism invariant p(T) for any triangulation T of S3. Although its definition is purely topological (inspired by the bridge number of knots), p(T) reflects the geometric properties of T. Specifically, if T is polytopal or shellable then p(T) is `small' in the sense that we obtain a linear upper bound for p(T) in the number n=n(T) of tetrahedra of T. Conversely, if p(T) is `small' then T is `almost' polytopal, since we show how to transform T into a polytopal triangulation by O((p(T))2) local subdivisions. The minimal number of local subdivisions needed to transform T into a polytopal triangulation is at least p(T)3n-n-2. Using our previous results [math.GT/0007032], we obtain a general upper bound for p(T) exponential in n2. We prove here by explicit constructions that there is no general subexponential upper bound for p(T) in n. Thus, we obtain triangulations that are `very far' from being polytopal. Our results yield a recognition algorithm for S3 that is conceptually simpler, though somewhat slower, as the famous Rubinstein-Thompson algorithm.
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.