English

Highly connected graphs have highly connected spanning bipartite subgraphs

Combinatorics 2024-03-26 v1

Abstract

For integers k,nk,n with 1kn/21 \le k \le n/2, let f(k,n)f(k,n) be the smallest integer tt such that every tt-connected nn-vertex graph has a spanning bipartite kk-connected subgraph. A conjecture of Thomassen asserts that f(k,n)f(k,n) is upper bounded by some function of kk. The best upper bound for f(k,n)f(k,n) is by Delcourt and Ferber who proved that f(k,n)1010k3lognf(k,n) \le 10^{10}k^3 \log n. Here it is proved that f(k,n)22k2lognf(k,n) \le 22k^2 \log n. For larger kk, stronger bounds hold. In the linear regime, it is proved that for any 0<c<120 < c < \frac{1}{2} and all sufficiently large nn, if k=cnk=\lfloor cn \rfloor, then f(k,n)30cn30n(k+1)f(k, n) \le 30\sqrt{c} n \le 30\sqrt{n(k+1)}. In the polynomial regime, it is proved that for any 13α<1\frac{1}{3} \le \alpha < 1 and all sufficiently large nn, if k=nαk = \lfloor n^\alpha \rfloor, then f(k,n)9n(1+α)/29n(k+1)f(k ,n) \le 9n^{(1+\alpha)/2} \le 9\sqrt{n(k+1)}.

Keywords

Cite

@article{arxiv.2403.15599,
  title  = {Highly connected graphs have highly connected spanning bipartite subgraphs},
  author = {Raphael Yuster},
  journal= {arXiv preprint arXiv:2403.15599},
  year   = {2024}
}
R2 v1 2026-06-28T15:30:39.117Z