English

Nearly tight bounds for MaxCut in hypergraphs

Combinatorics 2025-11-12 v1

Abstract

An rr-cut of a kk-uniform hypergraph is a partition of its vertex set into rr parts, and the size of the cut is the number of edges which have at least one vertex in each part. The study of the possible size of the largest rr-cut in a kk-uniform hypergraph was initiated by Erd\H{o}s and Kleitman in 1968. For graphs, a celebrated result of Edwards states that every mm-edge graph has a 22-cut of size m/2+Ω(m1/2)m/2+\Omega(m^{1/2}), which is sharp. In other words, there exists a cut which exceeds the expected size of a random cut by the order of m1/2m^{1/2}. Conlon, Fox, Kwan and Sudakov proved that any kk-uniform hypergraph with mm edges has an rr-cut whose size is Ω(m5/9)\Omega(m^{5/9}) larger than the expected size of a random rr-cut, provided that k4k \geq 4 or r3r \geq 3. They further conjectured that this can be improved to Ω(m2/3)\Omega(m^{2/3}), which would be sharp. Recently, R\"aty and Tomon improved the bound m5/9m^{5/9} to m3/5o(1)m^{3/5-o(1)} when r{k1,k}r \in \{ k-1,k\}. Using a novel approach, we prove the following approximate version of the Conlon-Fox-Kwan-Sudakov conjecture: for each ε>0\varepsilon>0, there is some k0=k0(ε)k_0=k_0(\varepsilon) such that for all k>k0k>k_0 and 2rk2\leq r\leq k, in every kk-uniform hypergraph with mm edges there exists an rr-cut exceeding the random one by Ω(m2/3ε)\Omega(m^{2/3-\varepsilon}). Moreover, we show that (if k4k\geq 4 or r3r\geq 3) every kk-uniform linear hypergraph has an rr-cut exceeding the random one by Ω(m3/4)\Omega(m^{3/4}), which is tight and proves a conjecture of R\"aty and Tomon.

Keywords

Cite

@article{arxiv.2511.08501,
  title  = {Nearly tight bounds for MaxCut in hypergraphs},
  author = {Oliver Janzer and Julien Portier},
  journal= {arXiv preprint arXiv:2511.08501},
  year   = {2025}
}

Comments

41 pages

R2 v1 2026-07-01T07:32:35.149Z