On the Alon-Tarsi Number and Chromatic-choosability of Cartesian Products of Graphs

Abstract

We study the list chromatic number of Cartesian products of graphs through the Alon-Tarsi number as defined by Jensen and Toft (1995) in their seminal book on graph coloring problems. The Alon-Tarsi number of G, AT(G), is the smallest k for which there is an orientation, D, of G with max indegree k\!-\!1 such that the number of even and odd circulations contained in D are different. It is known that (G) ≤ (G) ≤ p(G) ≤ AT(G), where (G) is the chromatic number, (G) is the list chromatic number, and p(G) is the paint number of G. In this paper we find families of graphs G and H such that (G H) = AT(G H), reducing this sequence of inequalities to equality. We show that the Alon-Tarsi number of the Cartesian product of an odd cycle and a path is always equal to 3. This result is then extended to show that if G is an odd cycle or a complete graph and H is a graph on at least two vertices containing the Hamilton path w1, w2, …, wn such that for each i, wi has a most k neighbors among w1, w2, …, wi-1, then AT(G H) ≤ (G)+k where (G) is the maximum degree of G. We discuss other extensions for G H, where G is such that V(G) can be partitioned into odd cycles and complete graphs, and H is a graph containing a Hamiltonian path. We apply these bounds to get chromatic-choosable Cartesian products, in fact we show that these families of graphs have (G) = AT(G), improving previously known bounds.