Optimally Reconfiguring List and Correspondence Colourings

Abstract

The reconfiguration graph Ck(G) for the k-colourings of a graph G has a vertex for each proper k-colouring of G, and two vertices of Ck(G) are adjacent precisely when those k-colourings differ on a single vertex of G. Much work has focused on bounding the maximum value of diam~Ck(G) over all n-vertex graphs G. We consider the analogous problems for list colourings and for correspondence colourings. We conjecture that if L is a list-assignment for a graph G with |L(v)| d(v)+2 for all v∈ V(G), then diam~CL(G) n(G)+μ(G). We also conjecture that if (L,H) is a correspondence cover for a graph G with |L(v)| d(v)+2 for all v∈ V(G), then diam~C(L,H)(G) n(G)+τ(G). (Here μ(G) and τ(G) denote the matching number and vertex cover number of G.) For every graph G, we give constructions showing that both conjectures are best possible. Our first main result proves the upper bounds (for the list and correspondence versions, respectively) diam~CL(G) n(G)+2μ(G) and diam~C(L,H)(G) n(G)+2τ(G). Our second main result proves that both conjectured bounds hold, whenever all v satisfy |L(v)| 2d(v)+1. We conclude by proving one or both conjectures for various classes of graphs such as complete bipartite graphs, subcubic graphs, cactuses, and graphs with bounded maximum average degree.