A Domatic Analogue of χ-Bounded Graph Classes and the Gyárfás-Sumner Conjecture

Abstract

Given a graph G, a dominating set is a subset X⊂eq V(G) such that N[X]=V(G). The domatic number of G, denoted dom(G), is the maximum size of a partition of V(G) into dominating sets. In analogy with the lower bound of the chromatic number by the clique number, the domatic number satisfies the upper bound dom(G) δ(G)+1 where δ(G) is the minimum degree of G. Therefore, as an analogue of the notion of χ-bounded graph classes, we say that a class of graphs G is DOM-bounded if there exists a positive unbounded function fG such that for every G∈ G, we have dom(G) fG(δ(G)). We propose the following conjecture for graphs forbidding a fixed induced subgraph, analogous to the Gyárfás--Sumner Conjecture for χ-bounded graph classes: for every connected graph H, the class of H-free graphs is DOM-bounded if and only if H is a tree of diameter at most 3. We reduce the case of disconnected graphs to the connected setting and show that the conditions on H are necessary. We show that star-free graphs of minimum degree at least δ have domatic number Ω(δ/ δ), which is best possible up to a constant factor. We also identify a subclass of star-free graphs for which the domatic number is linear in δ: line graphs of bounded rank hypergraphs. In support of our conjecture in the case of double stars, we prove that P4-free graphs (i.e. cographs) of minimum degree δ have domatic number at least 1 + δ2, which is best possible.