English

Cycle lengths in expanding graphs

Combinatorics 2020-06-09 v2

Abstract

For a positive constant α\alpha a graph GG on nn vertices is called an α\alpha-expander if every vertex set UU of size at most n/2n/2 has an external neighborhood whose size is at least αU\alpha\left|U\right|. We study cycle lengths in expanding graphs. We first prove that cycle lengths in α\alpha-expanders are well distributed. Specifically, we show that for every 0<α10<\alpha\leq1 there exist positive constants n0n_{0}, CC and A=O(1/α)A=O(1/\alpha) such that for every α\alpha-expander GG on nn0n\geq n_{0} vertices and every integer [Clogn,nC]\ell\in\left[C\log n,\frac{n}{C}\right], GG contains a cycle whose length is between \ell and +A\ell+A; the order of dependence of the additive error term AA on α\alpha is optimal. Secondly, we show that every α\alpha-expander on nn vertices contains Ω(α3log(1/α))n\Omega\left(\frac{\alpha^{3}}{\log\left(1/\alpha\right)}\right)n different cycle lengths. Finally, we introduce another expansion-type property, guaranteeing the existence of a linearly long interval in the set of cycle lengths. For β>0\beta>0 a graph GG on nn vertices is called a β\beta-graph if every pair of disjoint sets of size at least βn\beta n are connected by an edge. We prove that for every β<1/20\beta <1/20 there exist positive constants b1=O(1log(1/β))b_{1}=O\left(\frac{1}{\log\left(1/\beta\right)}\right) and b2=O(β)b_{2}=O\left(\beta\right) such that every β\beta-graph GG on nn vertices contains a cycle of length \ell for every integer [b1logn,(1b2)n]\ell\in\left[b_{1}\log n,(1-b_{2})n\right]; the order of dependence of b1b_{1} and b2b_{2} on β\beta is optimal.

Keywords

Cite

@article{arxiv.1912.11011,
  title  = {Cycle lengths in expanding graphs},
  author = {Limor Friedman and Michael Krivelevich},
  journal= {arXiv preprint arXiv:1912.11011},
  year   = {2020}
}
R2 v1 2026-06-23T12:54:58.626Z