English

Local Shearer bound

Combinatorics 2025-01-03 v1

Abstract

We prove the following local strengthening of Shearer's classic bound on the independence number of triangle-free graphs: For every triangle-free graph GG there exists a probability distribution on its independent sets such that every vertex vv of GG is contained in a random independent set drawn from the distribution with probability (1o(1))lnd(v)d(v)(1-o(1))\frac{\ln d(v)}{d(v)}. This resolves the main conjecture raised by Kelly and Postle (2018) about fractional coloring with local demands, which in turn confirms a conjecture by Cames van Batenburg et al. (2018) stating that every nn-vertex triangle-free graph has fractional chromatic number at most (2+o(1))nln(n)(\sqrt{2}+o(1))\sqrt{\frac{n}{\ln(n)}}. Addressing another conjecture posed by Cames van Batenburg et al., we also establish an analogous upper bound in terms of the number of edges. To prove these results we establish a more general technical theorem that works in a weighted setting. As a further application of this more general result, we obtain a new spectral upper bound on the fractional chromatic number of triangle-free graphs: We show that every triangle-free graph GG satisfies χf(G)(1+o(1))ρ(G)lnρ(G)\chi_f(G)\le (1+o(1))\frac{\rho(G)}{\ln \rho(G)} where ρ(G)\rho(G) denotes the spectral radius. This improves the bound implied by Wilf's classic spectral estimate for the chromatic number by a lnρ(G)\ln \rho(G) factor and makes progress towards a conjecture of Harris on fractional coloring of degenerate graphs.

Keywords

Cite

@article{arxiv.2501.00567,
  title  = {Local Shearer bound},
  author = {Anders Martinsson and Raphael Steiner},
  journal= {arXiv preprint arXiv:2501.00567},
  year   = {2025}
}

Comments

11 pages, comments welcome

R2 v1 2026-06-28T20:53:32.797Z