Criticality, The List Color Function, and List Coloring the Cartesian Product of Graphs

Abstract

We introduce a notion of color-criticality in the context of chromatic-choosability. We define a graph G to be strong k-chromatic-choosable if (G) = k and every (k-1)-assignment for which G is not list-colorable has the property that the lists are the same for all vertices. That is the usual coloring is, in some sense, the obstacle to list-coloring. We prove basic properties of strongly chromatic-choosable graphs such as chromatic-choosability and vertex-criticality, and we construct infinite families of strongly chromatic-choosable graphs. We derive a sufficient condition for the existence of at least two list colorings of strongly chromatic-choosable graphs and use it to show that: if M is a strong k-chromatic-choosable graph with |E(M)| ≤ |V(M)|(k-2) and H is a graph that contains a Hamilton path, w1, w2, …, wm, such that wi has at most ≥ 1 neighbors among w1, …, wi-1, then (M H) k+ - 1. We show that this bound is sharp for all 1 by generalizing the theorem to apply to H that are (M,)-Cartesian accommodating which is a notion we define with the help of the list color function, P(G,k), the list analogue of the chromatic polynomial. We also use the list color function to determine the list chromatic number of certain star-like graphs: (M K1,s) = k \; if s < P(M,k), or k+1 \; if s ≥ P(M,k), where M is a strong k-chromatic-choosable graph. We show that P(M,k) equals P(M,k), the chromatic polynomial, when M is an odd cycle, complete graph, or the join of an odd cycle with a complete graph.