Abstract
Let G=(V,E) be a graph. A clique-transversal setD is a subset of vertices of G such that D meets all cliques of G, where a clique is defined as a complete subgraph maximal under inclusion and having at least two vertices. The clique-transversal number, denoted by τC(G), of G is the cardinality of a minimum clique-transversal set in G. A k-clique-coloring of G is a k-coloring of its vertices such that no clique is monochromatic. All planar graphs have been proved to be 3-clique-colorable by Mohar and Škrekovski [B. Mohar, R. Škrekovski, The Grötzsch theorem for the hypergraph of maximal cliques, Electron. J. Combin. 6 (1999) #R26]. Erdős et al. [P. Erdős, T. Gallai, Zs. Tuza, Covering the cliques of a graph with vertices, Discrete Math. 108 (1992) 279–289] proposed to find sharp estimates on τC(G) for planar graphs. In this paper we first show that every outerplanar graph G of order n(≥2) has τC(G)≤3n/5 and the bound is tight. Secondly, we prove that every claw-free planar graph different from an odd cycle is 2-clique-colorable and we present a polynomial-time algorithm to find the 2-clique-coloring. As a by-product of the result, we obtain a tight upper bound on the clique-transversal number for claw-free planar graphs.
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