Chromatic Numbers of Simplicial Manifolds

TL;DR

This paper investigates the chromatic numbers of simplicial complexes, especially simplicial manifolds, providing explicit constructions of triangulations with high 2-chromatic numbers and establishing bounds for surfaces and 3-manifolds.

Contribution

It constructs explicit examples of triangulated surfaces and 3-manifolds with high 2-chromatic numbers, advancing understanding of chromatic properties in higher-dimensional topology.

Findings

Surfaces of genus ≥20 (orientable) and ≥26 (non-orientable) have 2-chromatic number ≥4.

Explicit triangulation of a non-orientable surface of genus 2542 with 2-chromatic number 5 or 6.

A small triangulation of the 3-sphere with face vector (167,1579,2824,1412) and 2-chromatic number 5.

Abstract

Higher chromatic numbers $\chi_s$ of simplicial complexes naturally generalize the chromatic number $\chi_1$ of a graph. In any fixed dimension $d$, the $s$-chromatic number $\chi_s$ of $d$-complexes can become arbitrarily large for $s\leq\lceil d/2\rceil$ [6,18]. In contrast, $\chi_{d+1}=1$, and only little is known on $\chi_s$ for $\lceil d/2\rceil<s\leq d$. A particular class of $d$-complexes are triangulations of $d$-manifolds. As a consequence of the Map Color Theorem for surfaces [29], the 2-chromatic number of any fixed surface is finite. However, by combining results from the literature, we will see that $\chi_2$ for surfaces becomes arbitrarily large with growing genus. The proof for this is via Steiner triple systems and is non-constructive. In particular, up to now, no explicit triangulations of surfaces with high $\chi_2$ were known. We show that orientable surfaces of genus at least 20 and non-orientable surfaces of genus at least 26 have a 2-chromatic number of at least 4. Via a projective Steiner triple systems, we construct an explicit triangulation of a non-orientable surface of genus 2542 and with face vector $f=(127,8001,5334)$ that has 2-chromatic number 5 or 6. We also give orientable examples with 2-chromatic numbers 5 and 6. For 3-dimensional manifolds, an iterated moment curve construction [18] along with embedding results [6] can be used to produce triangulations with arbitrarily large 2-chromatic number, but of tremendous size. Via a topological version of the geometric construction of [18], we obtain a rather small triangulation of the 3-dimensional sphere $S^3$ with face vector $f=(167,1579,2824,1412)$ and 2-chromatic number 5.