English

Large Cuts in Hypergraphs via Energy

Combinatorics 2025-06-18 v2

Abstract

A simple probabilistic argument shows that every rr-uniform hypergraph with mm edges contains an rr-partite subhypergraph with at least r!rrm\frac{r!}{r^r}m edges. The celebrated result of Edwards states that in the case of graphs, that is r=2r=2, the resulting bound m/2m/2 can be improved to m/2+Ω(m1/2)m/2+\Omega(m^{1/2}), and this is sharp. We prove that if r3r\geq 3, then there is an rr-partite subhypergraph with at least r!rrm+m3/5o(1)\frac{r!}{r^r} m+m^{3/5-o(1)} edges. Moreover, if the hypergraph is linear, this can be improved to r!rrm+m3/4o(1),\frac{r!}{r^r} m+m^{3/4-o(1)}, which is tight up to the o(1)o(1) term. These improve results of Conlon, Fox, Kwan, and Sudakov. Our proof is based on a combination of probabilistic, combinatorial, and linear algebraic techniques, and semidefinite programming. A key part of our argument is relating the energy E(G)\mathcal{E}(G) of a graph GG (i.e. the sum of absolute values of eigenvalues of the adjacency matrix) to its maximum cut. We prove that every mm edge multigraph GG has a cut of size at least m/2+Ω(E(G)logm)m/2+\Omega(\frac{\mathcal{E}(G)}{\log m}), which might be of independent interest.

Keywords

Cite

@article{arxiv.2410.01682,
  title  = {Large Cuts in Hypergraphs via Energy},
  author = {Eero Räty and István Tomon},
  journal= {arXiv preprint arXiv:2410.01682},
  year   = {2025}
}

Comments

corrected Theorem 5.2

R2 v1 2026-06-28T19:05:29.873Z