On polynomial degree-boundedness
Abstract
We prove a conjecture of Bonamy, Bousquet, Pilipczuk, Rz\k{a}\.zewski, Thomass\'e, and Walczak, that for every graph , there is a polynomial such that for every positive integer , every graph of average degree at least contains either as a subgraph or contains an induced subdivision of . This improves upon a result of K\"uhn and Osthus from 2004 who proved it for graphs whose average degree is at least triply exponential in and a recent result of Du, Gir\~{a}o, Hunter, McCarty and Scott for graphs with average degree at least singly exponential in . As an application, we prove that the class of graphs that do not contain an induced subdivision of is polynomially -bounded. In the case of , this is the class of theta-free graphs, and answers a question of Davies. Along the way, we also answer a recent question of McCarty, by showing that if is a hereditary class of graphs for which there is a polynomial such that every bipartite -free graph in has average degree at most , then more generally, there is a polynomial such that every -free graph in has average degree at most . Our main new tool is an induced variant of the K\H{o}v\'ari-S\'os-Tur\'an theorem, which we find to be of independent interest.
Cite
@article{arxiv.2311.03341,
title = {On polynomial degree-boundedness},
author = {Romain Bourneuf and Matija Bucić and Linda Cook and James Davies},
journal= {arXiv preprint arXiv:2311.03341},
year = {2024}
}