Large subgraphs in rainbow-triangle free colorings

TL;DR

This paper investigates large subgraphs with high chromatic number in rainbow-triangle free colorings, improving bounds and generalizing classical theorems in graph theory and combinatorics.

Contribution

It establishes optimal bounds for the chromatic number of subgraphs with limited colors in rainbow-triangle free colorings, extending previous clique-based results.

Findings

Found a 2-colored subgraph with chromatic number at least n^{2/3}

Generalized Erdős-Szekeres theorem to rainbow-triangle free colorings

Proved existence of large s-colored directed paths in tournaments without rainbow triangles

Abstract

Fox--Grinshpun--Pach showed that every $3$-coloring of the complete graph on $n$ vertices without a rainbow triangle contains a clique of size $\Omega\left(n^{1/3}\log^2 n\right)$ which uses at most two colors, and this bound is tight up to the constant factor. We show that if instead of looking for large cliques one only tries to find subgraphs of large chromatic number, one can do much better. We show that every such coloring contains a $2$-colored subgraph with chromatic number at least $n^{2/3}$, and this is best possible. We further show that for fixed positive integers $s,r$ with $s\leq r$, every $r$-coloring of the edges of the complete graph on $n$ vertices without a rainbow triangle contains a subgraph that uses at most $s$ colors and has chromatic number at least $n^{s/r}$, and this is best possible. Fox--Grinshpun--Pach previously showed a clique version of this result. As a direct corollary of our result we obtain a generalisation of the celebrated theorem of Erd\H{o}s-Szekeres, which states that any sequence of $n$ numbers contains a monotone subsequence of length at least $\sqrt{n}$. We prove that if an $r$-coloring of the edges of an $n$-vertex tournament does not contain a rainbow triangle then there is an $s$-colored directed path on $n^{s/r}$ vertices, which is best possible. This gives a partial answer to a question of Loh.