English

Giant Rainbow Trees in Sparse Random Graphs

Combinatorics 2023-08-29 v1

Abstract

For any small constant ϵ>0\epsilon>0, the Erd\H{o}s-R\'enyi random graph G(n,1+ϵn)G(n,\frac{1+\epsilon}{n}) with high probability has a unique largest component which contains (1±O(ϵ))2ϵn(1\pm O(\epsilon))2\epsilon n vertices. Let Gc(n,p)G_c(n,p) be obtained by assigning each edge in G(n,p)G(n,p) a color in [c][c] independently and uniformly. Cooley, Do, Erde, and Missethan proved that for any fixed α>0\alpha>0, Gαn(n,1+ϵn)G_{\alpha n}(n,\frac{1+\epsilon}{n}) with high probability contains a rainbow tree (a tree that does not repeat colors) which covers (1±O(ϵ))αα+1ϵn(1\pm O(\epsilon))\frac{\alpha}{\alpha+1}\epsilon n vertices, and conjectured that there is one which covers (1±O(ϵ))2ϵn(1\pm O(\epsilon))2\epsilon n. In this paper, we achieve the correct leading constant and prove their conjecture correct up to a logarithmic factor in the error term, as we show that with high probability Gαn(n,1+ϵn)G_{\alpha n}(n,\frac{1+\epsilon}{n}) contains a rainbow tree which covers (1±O(ϵlog(1/ϵ)))2ϵn(1\pm O(\epsilon\log(1/\epsilon)))2\epsilon n vertices.

Keywords

Cite

@article{arxiv.2308.14141,
  title  = {Giant Rainbow Trees in Sparse Random Graphs},
  author = {Tolson Bell and Alan Frieze},
  journal= {arXiv preprint arXiv:2308.14141},
  year   = {2023}
}

Comments

9 pages

R2 v1 2026-06-28T12:05:27.579Z