English

On Kotzig's conjecture in random graphs

Combinatorics 2025-10-03 v1

Abstract

In 1963, Anton Kotzig famously conjectured that KnK_{n}, the complete graph of order nn, where nn is even, can be decomposed into n1n-1 perfect matchings such that every pair of these matchings forms a Hamilton cycle. The problem is still wide open and here we consider a variant of it for the binomial random graph G(n,p)G(n,p). We prove that, for every fixed kk, there exists a constant C=C(k)C=C(k) such that, when pClognnp\ge \frac{C \log n}{n}, with high probability, G(n,p)G(n,p) contains kk edge-disjoint perfect matchings with the property that every pair of them forms a Hamilton cycle. In fact, our main result is a very precise counting result for KnK_n. We show that, given any kk edge-disjoint perfect matchings M1,,MkM_1,\dots,M_k, the probability that a uniformly random perfect matching MM^* in KnK_n has the property that MMiM^*\cup M_i forms a Hamilton cycle for each i[k]i\in [k] is Θk(nk/2)\Theta_k(n^{-k/2}). This is proved by building on a variety of methods, including a random process analysis, the absorption method, the entropy method and the switching method. The result on the binomial random graph follows from a slight strengthening of our counting result via the recent breakthroughs on the expectation threshold conjecture.

Keywords

Cite

@article{arxiv.2510.01949,
  title  = {On Kotzig's conjecture in random graphs},
  author = {Stefan Glock and Amedeo Sgueglia},
  journal= {arXiv preprint arXiv:2510.01949},
  year   = {2025}
}

Comments

29 pages, 5 figures

R2 v1 2026-07-01T06:13:05.457Z