English

Colouring graphs from random lists

Combinatorics 2024-04-10 v2

Abstract

Given positive integers kmk \leq m and a graph GG, a family of lists L={L(v):vV(G)}L = \{L(v) : v \in V(G)\} is said to be a random (k,m)(k,m)-list-assignment if for every vV(G)v \in V(G) the list L(v)L(v) is a subset of {1,,m}\{1, \ldots, m\} of size kk, chosen uniformly at random and independently of the choices of all other vertices. An nn-vertex graph GG is said to be a.a.s. (k,m)(k,m)-colourable if limnP(G is Lcolourable)=1\lim_{n \to \infty} \mathbb{P}(G \textrm{ is } L-colourable) = 1, where LL is a random (k,m)(k,m)-list-assignment. We prove that if mn1/k2Δ1/km \gg n^{1/k^2} \Delta^{1/k} and m3k2Δm \geq 3 k^2 \Delta, where Δ\Delta is the maximum degree of GG and k3k \geq 3 is an integer, then GG is a.a.s. (k,m)(k,m)-colourable. This is not far from being best possible, forms a continuation of the so-called palette sparsification results, and proves in a strong sense a conjecture of Casselgren. Additionally, we consider this problem under the additional assumption that GG is HH-free for some graph HH. For various graphs HH, we estimate the smallest mm for which an HH-free nn-vertex graph GG is a.a.s. (k,m)(k,m)-colourable. This extends and improves several results of Casselgren.

Keywords

Cite

@article{arxiv.2402.09998,
  title  = {Colouring graphs from random lists},
  author = {Dan Hefetz and Michael Krivelevich},
  journal= {arXiv preprint arXiv:2402.09998},
  year   = {2024}
}
R2 v1 2026-06-28T14:49:39.991Z