Frozen colourings in 2K2-free graphs

Abstract

The reconfiguration graph of the k-colourings of a graph G, denoted Rk(G), is the graph whose vertices are the k-colourings of G and two vertices of Rk(G) are joined by an edge if the colourings of G they correspond to differ in colour on exactly one vertex. A k-colouring of a graph G is called frozen if it is an isolated vertex in Rk(G); in other words, for every vertex v ∈ V(G), v is adjacent to a vertex of every colour different from its colour. A clique partition is a partition of the vertices of a graph into cliques. A clique partition is called a k-clique-partition if it contains at most k cliques. Clearly, a k-colouring of a graph G corresponds precisely to a k-clique-partition of its complement, G. A k-clique-partition Q of a graph H is called frozen if for every vertex v ∈ V(H), v has a non-neighbour in each of the cliques of Q other than the one containing v. The cycle on four vertices, C4, is sometimes called the square; its complement is called 2K2. We give several infinite classes of 2K2-free graphs with frozen colourings. We give an operation which transforms a k-chromatic graph with a frozen (k+1)-colouring into a (k+1)-chromatic graph with a frozen (k+2)-colouring. Our operation preserves being 2K2-free. It follows that for all k 4, there is a k-chromatic 2K2-free graph with a frozen (k+1)-colouring. We prove these results by studying frozen clique partitions in C4-free graphs. We say a graph G is recolourable if R(G) is connected for all greater than the chromatic number of G. We prove that every 3-chromatic 2K2-free graph is recolourable.