Coloring hypergraphs with excluded minors

Abstract

Hadwiger's conjecture, among the most famous open problems in graph theory, states that every graph that does not contain Kt as a minor is properly (t-1)-colorable. The purpose of this work is to demonstrate that a natural extension of Hadwiger's problem to hypergraph coloring exists, and to derive some first partial results and applications. Generalizing ordinary graph minors to hypergraphs, we say that a hypergraph H1 is a minor of a hypergraph H2, if a hypergraph isomorphic to H1 can be obtained from H2 via a finite sequence of vertex- and hyperedge-deletions, and hyperedge contractions. We first show that a weak extension of Hadwiger's conjecture to hypergraphs holds true: For every t 1, there exists a finite (smallest) integer h(t) such that every hypergraph with no Kt-minor is h(t)-colorable, and we prove 32(t-1) h(t) 2g(t) where g(t) denotes the maximum chromatic number of graphs with no Kt-minor. Using the recent result by Delcourt and Postle that g(t)=O(t t), this yields h(t)=O(t t). We further conjecture that h(t)=32(t-1), i.e., that every hypergraph with no Kt-minor is 32(t-1)-colorable for all t 1, and prove this conjecture for all hypergraphs with independence number at most 2. By considering special classes of hypergraphs, the above additionally has some interesting applications for ordinary graph coloring, such as: -graphs of chromatic number C k t t contain Kt-minors with k-edge-connected branch-sets, -graphs of chromatic number C q t t contain Kt-minors with modulo-q-connected branch sets, -by considering cycle hypergraphs of digraphs we recover known results on strong minors in digraphs of large dichromatic number as special cases.