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A note on Hadwiger's Conjecture for $W_5$-free graphs with independence number two

Published 21 Jan 2019 in math.CO | (1901.06985v1)

Abstract: The Hadwiger number of a graph $G$, denoted $h(G)$, is the largest integer $t$ such that $G$ contains $K_t$ as a minor. A famous conjecture due to Hadwiger in 1943 states that for every graph $G$, $h(G) \ge \chi(G)$, where $\chi(G)$ denotes the chromatic number of $G$. Let $\alpha(G)$ denote the independence number of $G$. A graph is $H$-free if it does not contain the graph $H$ as an induced subgraph. In 2003, Plummer, Stiebitz and Toft proved that $h(G) \ge \chi(G)$ for all $H$-free graphs $G$ with $\alpha(G) \le 2$, where $H$ is any graph on four vertices with $\alpha(H) \le 2$, $H=C_5$, or $H$ is a particular graph on seven vertices. In 2010, Kriesell considered a particular strengthening of Hadwiger's conjecture due to Seymour and subsequently generalized the statement to include all forbidden subgraphs $H$ on five vertices with $\alpha(H) \le 2$. In this note, we prove that $h(G) \ge \chi(G)$ for all $W_5$-free graphs $G$ with $\alpha(G) \le 2$, where $W_5$ denotes the wheel on six vertices.

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