Bounding the List Color Function Threshold from Above

Abstract: The chromatic polynomial of a graph $G$, denoted $P(G,m)$, is equal to the number of proper $m$-colorings of $G$ for each $m \in \mathbb{N}$. In 1990, Kostochka and Sidorenko introduced the list color function of graph $G$, denoted $P_{\ell}(G,m)$, which is a list analogue of the chromatic polynomial. The list color function threshold of $G$, denoted $\tau(G)$, is the smallest $k \geq \chi(G)$ such that $P_{\ell}(G,m) = P(G,m)$ whenever $m \geq k$. It is known that for every graph $G$, $\tau(G)$ is finite, and in fact, $\tau(G) \leq (|E(G)|-1)/\ln(1+ \sqrt{2}) + 1$. It is also known that when $G$ is a cycle or chordal graph, $G$ is enumeratively chromatic-choosable which means $\tau(G) = \chi(G)$. A paper of Kaul et al. suggests that understanding the list color function threshold of complete bipartite graphs is essential to the study of the extremal behavior of $\tau$. In this paper we show that for any $n \geq 2$, $\tau(K_{2,n}) \leq \lceil (n+2.05)/1.24 \rceil$ which gives an improvement on the general upper bound for $\tau(G)$ when $G = K_{2,n}$. We also develop additional tools that allow us to show that $\tau(K_{2,3}) = \chi(K_{2,3})$ and $\tau(K_{2,4}) = \tau(K_{2,5}) = 3$.