English

Induced paths in graphs without anticomplete cycles

Combinatorics 2023-01-11 v2

Abstract

Let us say a graph is sOs\mathcal{O}-free, where s1s\ge 1 is an integer, if there do not exist ss cycles of the graph that are pairwise vertex-disjoint and have no edges joining them. The structure of such graphs, even when s=2s=2, is not well understood. For instance, until now we did not know how to test whether a graph is 2O2\mathcal{O}-free in polynomial time; and there was an open conjecture, due to Ngoc Khang Le, that 2O2\mathcal{O}-free graphs have only a polynomial number of induced paths. In this paper we prove Le's conjecture; indeed, we will show that for all s1s\ge 1, there exists c>0c>0 such that every sOs\mathcal{O}-free graph GG has at most Gc|G|^c induced paths. This provides a poly-time algorithm to test if a graph is sOs\mathcal{O}-free, for all fixed ss. The proof has three parts. First, there is a short and beautiful proof, due to Le, that reduces the question to proving the same thing for graphs with no cycles of length four. Second, there is a recent result of Bonamy, Bonnet, D\'epr\'es, Esperet, Geniet, Hilaire, Thomass\'e and Wesolek, that in every sOs\mathcal{O}-free graph GG with no cycle of length four, there is a set of vertices that intersects every cycle, with size logarithmic in G|G|. And third, there is an argument that uses the result of Bonamy et al. to deduce the theorem. The last is the main content of this paper.

Keywords

Cite

@article{arxiv.2212.01089,
  title  = {Induced paths in graphs without anticomplete cycles},
  author = {Tung Nguyen and Alex Scott and Paul Seymour},
  journal= {arXiv preprint arXiv:2212.01089},
  year   = {2023}
}
R2 v1 2026-06-28T07:20:19.254Z