English

Applications of Sparse Hypergraph Colorings

Combinatorics 2024-06-04 v1

Abstract

Many problems in extremal combinatorics can be reduced to determining the independence number of a specific auxiliary hypergraph. We present two such problems, one from discrete geometry and one from hypergraph Tur\'an theory. Using results on hypergraph colorings by Cooper-Mubayi and Li-Postle, we demonstrate that for those two problems the trivial lower bound on the independence number can be improved upon: Erd\H{o}s, Graham, Ruzsa and Taylor asked to determine the largest size, denoted by g(n)g(n), of a subset PP of the grid [n]2[n]^2 such that every pair of points in PP span a different slope. Improving on a lower bound by Zhang from 1993, we show that g(n)=Ω(n2/3(loglogn)1/3log1/3n).g(n)=\Omega \left( \frac{n^{2/3} (\log \log n)^{1/3} }{ \log^{1/3}n} \right). Let H3rH^r_3 denote an rr-graph with r+1r+1 vertices and 33 edges. Recently, Sidorenko proved the following lower bounds for the Tur\'an density of this rr-graph: π(H3r)r2\pi(H^r_3)\geq r^{-2} for every rr, and π(H3r)(1.7215o(1))r2\pi(H^r_3)\geq (1.7215 - o(1)) r^{-2}. We present an improved asymptotic bound: π(H3r)=Ω(r2log1/2r).\pi(H^r_3)=\Omega\left(r^{-2} \log^{1/2} r \right).

Keywords

Cite

@article{arxiv.2406.01499,
  title  = {Applications of Sparse Hypergraph Colorings},
  author = {Felix Christian Clemen},
  journal= {arXiv preprint arXiv:2406.01499},
  year   = {2024}
}
R2 v1 2026-06-28T16:51:31.312Z