English

Chromatic Vertex Folkman Numbers

Combinatorics 2019-05-28 v3

Abstract

For graph GG and integers a1ar2a_1 \ge \cdots \ge a_r \ge 2, we write G(a1,,ar)vG \rightarrow (a_1 ,\cdots ,a_r)^v if and only if for every rr-coloring of the vertex set V(G)V(G) there exists a monochromatic KaiK_{a_i} in GG for some color i{1,,r}i \in \{1, \cdots, r\}. The vertex Folkman number Fv(a1,,ar;s)F_v(a_1 ,\cdots ,a_r; s) is defined as the smallest integer nn for which there exists a KsK_s-free graph GG of order nn such that G(a1,,ar)vG \rightarrow (a_1 ,\cdots ,a_r)^v. It is well known that if G(a1,,ar)vG \rightarrow (a_1 ,\cdots ,a_r)^v then χ(G)m\chi(G) \geq m, where m=1+i=1r(ai1)m = 1+ \sum_{i=1}^r (a_i - 1). In this paper we study such Folkman graphs GG with chromatic number χ(G)=m\chi(G)=m, which leads to a new concept of chromatic Folkman numbers. We prove constructively some existential results, among others that for all r,s2r,s \ge 2 there exist Ks+1K_{s+1}-free graphs GG such that G(s,r,s)vG \rightarrow (s,\cdots_r,s)^v and GG has the smallest possible chromatic number r(s1)+1r(s-1)+1 for this rr-color arrowing to hold. We also conjecture that, in some cases, our construction is the best possible, in particular that for every s2s \ge 2 there exists a Ks+1K_{s+1}-free graph GG on Fv(s,s;s+1)F_v(s,s; s+1) vertices with χ(G)=2s1\chi(G)=2s-1 such that G(s,s)vG \rightarrow (s,s)^v.

Keywords

Cite

@article{arxiv.1612.08136,
  title  = {Chromatic Vertex Folkman Numbers},
  author = {Xiaodong Xu and Meilian Liang and Stanisław Radziszowski},
  journal= {arXiv preprint arXiv:1612.08136},
  year   = {2019}
}
R2 v1 2026-06-22T17:33:47.942Z