On Weak Flexibility in Planar Graphs

Abstract

Recently, Dvor\'ak, Norin, and Postle introduced flexibility as an extension of list coloring on graphs [JGT 19']. In this new setting, each vertex v in some subset of V(G) has a request for a certain color r(v) in its list of colors L(v). The goal is to find an L coloring satisfying many, but not necessarily all, of the requests. The main studied question is whether there exists a universal constant ε >0 such that any graph G in some graph class C satisfies at least ε proportion of the requests. More formally, for k > 0 the goal is to prove that for any graph G ∈ C on vertex set V, with any list assignment L of size k for each vertex, and for every R ⊂eq V and a request vector (r(v): v∈ R, ~r(v) ∈ L(v)), there exists an L-coloring of G satisfying at least ε|R| requests. If this is true, then C is called ε-flexible for lists of size k. Choi et al. [arXiv 20'] introduced the notion of weak flexibility, where R = V. We further develop this direction by introducing a tool to handle weak flexibility. We demonstrate this new tool by showing that for every positive integer b there exists ε(b)>0 so that the class of planar graphs without K4, C5 , C6 , C7, Bb is weakly ε(b)-flexible for lists of size 4 (here Kn, Cn and Bn are the complete graph, a cycle, and a book on n vertices, respectively). We also show that the class of planar graphs without K4, C5 , C6 , C7, B5 is ε-flexible for lists of size 4. The results are tight as these graph classes are not even 3-colorable.