English

Partitioning random graphs into monochromatic components

Combinatorics 2017-02-17 v4

Abstract

Erd\H{o}s, Gy\'arf\'as, and Pyber (1991) conjectured that every rr-colored complete graph can be partitioned into at most r1r-1 monochromatic components; this is a strengthening of a conjecture of Lov\'asz (1975) in which the components are only required to form a cover. An important partial result of Haxell and Kohayakawa (1995) shows that a partition into rr monochromatic components is possible for sufficiently large rr-colored complete graphs. We start by extending Haxell and Kohayakawa's result to graphs with large minimum degree, then we provide some partial analogs of their result for random graphs. In particular, we show that if p(27lognn)1/3p\ge \left(\frac{27\log n}{n}\right)^{1/3}, then a.a.s. in every 22-coloring of G(n,p)G(n,p) there exists a partition into two monochromatic components, and for r2r\geq 2 if p(rlognn)1/rp\ll \left(\frac{r\log n}{n}\right)^{1/r}, then a.a.s. there exists an rr-coloring of G(n,p)G(n,p) such that there does not exist a cover with a bounded number of components. Finally, we consider a random graph version of a classic result of Gy\'arf\'as (1977) about large monochromatic components in rr-colored complete graphs. We show that if p=ω(1)np=\frac{\omega(1)}{n}, then a.a.s. in every rr-coloring of G(n,p)G(n,p) there exists a monochromatic component of order at least (1o(1))nr1(1-o(1))\frac{n}{r-1}.

Keywords

Cite

@article{arxiv.1509.09168,
  title  = {Partitioning random graphs into monochromatic components},
  author = {Deepak Bal and Louis DeBiasio},
  journal= {arXiv preprint arXiv:1509.09168},
  year   = {2017}
}

Comments

27 pages, 2 figures. Appears in Electronic Journal of Combinatorics Volume 24, Issue 1 (2017) Paper #P1.18

R2 v1 2026-06-22T11:09:11.605Z