Coloring small locally sparse degenerate graphs and related problems

Abstract

The classic upper bound on the chromatic number of d-degenerate graphs is d+1, shown to be tight by complete graphs. A natural question is whether this bound remains tight if one forbids large cliques. Classic constructions of Tutte and Zykov from the early 50s show that there exist d-degenerate (d+1)-chromatic graphs that are triangle-free, however these constructions grow rapidly with d. Motivated by this and addressing a problem posed by the second author at the Oberwolfach Graph Theory workshop, we prove that the minimum order f(d) of a d-degenerate triangle-free graph of chromatic number d+1 satisfies e(d) f(d) eO(d2 d). The lower bound follows from a novel upper bound on the chromatic number of triangle-free graphs: Every triangle-free d-degenerate graph G on n eO(d) vertices satisfies (G) O(d(d/ n)). We extend this to a more general result about degenerate graphs with sparse neighborhoods, which has applications to many graph coloring problems: For example, we prove that every counterexample to Hadwiger's conjecture with parameter t must have a complete bipartite subgraph with one exponentially large side (Ka,b where a=( t)1/2-o(1) and b=et1-o(1)) or a small and very dense subgraph (of order t with t2-o(1) edges) in some neighborhood. For the upper bound on f(d) we establish a surprising connection between f(d) and the on-line-chromatic number g(n) of n-vertex triangle-free graphs. We also give an asymptotic improvement of the previous best upper bound for g(n) due to Lov\'asz, Saks and Trotter from 1989. Along the way we disprove a generalization of Harris' fractional coloring conjecture to graphs of bounded clique number and raise numerous problems which open up interesting directions to explore for future research.