Variants of the Gy\`arf\`as-Sumner Conjecture: Oriented Trees and Rainbow Paths

Abstract

Given a finite family F of graphs, we say that a graph G is "F-free" if G does not contain any graph in F as a subgraph. A vertex-colored graph H is called "rainbow" if no two vertices of H have the same color. Given an integer s and a finite family of graphs F, let (s,F) denote the smallest integer such that any properly vertex-colored F-free graph G having (G)≥(s,F) contains an induced rainbow path on s vertices. Scott and Seymour showed that (s,K) exists for every complete graph K. A conjecture of N. R. Aravind states that (s,C3)=s. The upper bound on (s,C3) that can be obtained using the methods of Scott and Seymour setting K=C3 are, however, super-exponential. Gy\'arf\'as and S\'ark\"ozy showed that (s,\C3,C4\)=O((2s)2s). For r≥ 2, we show that (s,K2,r)≤ (r-1)(s-1)(s-2)/2+s and therefore, (s,C4)≤s2-s+22. This significantly improves Gy\'arf\'as and S\'ark\"ozy's bound and also covers a bigger class of graphs. We adapt our proof to achieve much stronger upper bounds for graphs of higher girth: we prove that (s,\C3,C4,…,Cg-1\)≤ s1+4g-4, where g≥ 5. Moreover, in each case, our results imply the existence of at least s!/2 distinct induced rainbow paths on s vertices. Along the way, we obtain some results on related problems on oriented graphs. For r≥ 2, let Br denote the orientations of K2,r in which one vertex has out-degree or in-degree r. We show that every Br-free oriented graph G having (G)≥ (r-1)(s-1)(s-2)+2s+1 and every bikernel-perfect oriented graph G with girth g≥ 5 having (G)≥ 2s1+4g-4 contains every s vertex oriented tree as an induced subgraph.