Induced subgraph density. III. Cycles and subdivisions

TL;DR

This paper proves that certain cycle and subdivision-free graphs necessarily contain large cliques or stable sets, extending the Erdős-Hajnal conjecture and unifying various results using iterative sparsification.

Contribution

It establishes new bounds for graphs free of specific cycles and subdivisions, extending the Erdős-Hajnal conjecture to broader classes of graphs.

Findings

Graphs free of certain cycles have large cliques or stable sets.

Results extend to graphs with subdivisions of edges.

Provides a simplified proof of Fox and Sudakov's theorem.

Abstract

We show that for every two cycles $C,D$, there exists $c>0$ such that if $G$ is both $C$-free and $\overline{D}$-free then $G$ has a clique or stable set of size at least $|G|^c$. ("$H$-free" means with no induced subgraph isomorphic to $H$, and $\overline{D}$ denotes the complement graph of $D$.) Since the five-vertex cycle $C_5$ is isomorphic to its complement, this extends the earlier result that $C_5$ satisfies the Erd\H{o}s-Hajnal conjecture. It also unifies and strengthens several other results. The results for cycles are special cases of results for subdivisions, as follows. Let $H,J$ be obtained from smaller graphs by subdividing every edge exactly twice. We will prove that there exists $c>0$ such that if $G$ is both $H$-free and $\overline{J}$-free then $G$ has a clique or stable set of size at least $|G|^c$. And the same holds if $H$ and/or $J$ is obtained from a graph bychoosing a forest $F$ and subdividing every edge not in $F$ at least five times. Our proof uses the framework of iterative sparsification developed in other papers of this series. Along the way, we will also give a short and simple proof of a celebrated result of Fox and Sudakov, that says that for all $H$, every $H$-free graph contains either a large stable set or a large complete bipartite subgraph.