English

Substructures in Latin squares

Combinatorics 2022-08-05 v4

Abstract

We prove several results about substructures in Latin squares. First, we explain how to adapt our recent work on high-girth Steiner triple systems to the setting of Latin squares, resolving a conjecture of Linial that there exist Latin squares with arbitrarily high girth. As a consequence, we see that the number of order-nn Latin squares with no intercalate (i.e., no 2×22\times2 Latin subsquare) is at least (e9/4no(n))n2(e^{-9/4}n-o(n))^{n^{2}}. Equivalently, P[N=0]en2/4o(n2)=e(1+o(1))EN\mathbb{P}\left[\mathbf{N}=0\right]\ge e^{-n^{2}/4-o(n^{2})}=e^{-(1+o(1))\mathbb{E}\mathbf{N}}, where N\mathbf{N} is the number of intercalates in a uniformly random order-nn Latin square. In fact, extending recent work of Kwan, Sah, and Sawhney, we resolve the general large-deviation problem for intercalates in random Latin squares, up to constant factors in the exponent: for any constant 0<δ10<\delta\le1 we have P[N(1δ)EN]=exp(Θ(n2))\mathbb{P}[\mathbf{N}\le(1-\delta)\mathbb{E}\mathbf{N}]=\exp(-\Theta(n^{2})) and for any constant δ>0\delta>0 we have P[N(1+δ)EN]=exp(Θ(n4/3logn))\mathbb{P}[\mathbf{N}\ge(1+\delta)\mathbb{E}\mathbf{N}]=\exp(-\Theta(n^{4/3}\log n)). Finally, as an application of some new general tools for studying substructures in random Latin squares, we show that in almost all order-nn Latin squares, the number of cuboctahedra (i.e., the number of pairs of possibly degenerate 2×22\times2 submatrices with the same arrangement of symbols) is of order n4n^{4}, which is the minimum possible. As observed by Gowers and Long, this number can be interpreted as measuring ``how associative'' the quasigroup associated with the Latin square is.

Cite

@article{arxiv.2202.05088,
  title  = {Substructures in Latin squares},
  author = {Matthew Kwan and Ashwin Sah and Mehtaab Sawhney and Michael Simkin},
  journal= {arXiv preprint arXiv:2202.05088},
  year   = {2022}
}

Comments

32 pages, 1 figure. Corrected typos and improved terminology

R2 v1 2026-06-24T09:30:18.731Z