On Some Generalized Vertex Folkman Numbers

Abstract

For a graph G and integers ai 1, the expression G → (a1,…,ar)v means that for any r-coloring of the vertices of G there exists a monochromatic ai-clique in G for some color i ∈ \1,·s,r\. The vertex Folkman numbers are defined as Fv(a1,…,ar;H) = \|V(G)| : G is H-free and G → (a1,…,ar)v\, where H is a graph. Such vertex Folkman numbers have been extensively studied for H=Ks with s>\ai\1 i r. If ai=a for all i, then we use notation Fv(ar;H)=Fv(a1,…,ar;H). Let Jk be the complete graph Kk missing one edge, i.e. Jk=Kk-e. In this work we focus on vertex Folkman numbers with H=Jk, in particular for k=4 and ai 3. A result by Nesetril and R\"odl from 1976 implies that Fv(3r;J4) is well defined for any r 2. We present a new and more direct proof of this fact. The simplest but already intriguing case is that of Fv(3,3;J4), for which we establish the upper bound of 135 by using the J4-free process. We obtain the exact values and bounds for a few other small cases of Fv(a1,…,ar;J4) when ai 3 for all 1 i r, including Fv(2,3;J4)=14, Fv(24;J4)=15, and 22 Fv(25;J4) 25. Note that Fv(2r;J4) is the smallest number of vertices in any J4-free graph with chromatic number r+1. Most of the results were obtained with the help of computations, but some of the upper bound graphs we found are interesting by themselves.

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