English

On Existentially Complete Triangle-free Graphs

Combinatorics 2017-08-30 v1

Abstract

For a positive integer kk, we say that a graph is kk-existentially complete if for every 0ak0 \leq a \leq k, and every tuple of distinct vertices x1,,xax_1,\ldots,x_a, y1,,ykay_1,\ldots,y_{k-a}, there exists a vertex zz that is joined to all of the vertices x1,,xax_1,\ldots,x_a and none of the vertices y1,,ykay_1,\ldots,y_{k-a}. While it is easy to show that the binomial random graph Gn,1/2G_{n,1/2} satisfies this property with high probability for kclognk \sim c\log n, little is known about the "triangle-free" version of this problem; does there exist a finite triangle-free graph GG with a similar "extension property". This question was first raised by Cherlin in 1993 and remains open even in the case k=4k=4. We show that there are no kk-existentially complete triangle-free graphs with k>8lognloglognk >\frac{8\log n}{\log\log n}, thus giving the first non-trivial, non-existence result on this "old chestnut" of Cherlin. We believe that this result breaks through a natural barrier in our understanding of the problem.

Keywords

Cite

@article{arxiv.1708.08817,
  title  = {On Existentially Complete Triangle-free Graphs},
  author = {Shoham Letzter and Julian Sahasrabudhe},
  journal= {arXiv preprint arXiv:1708.08817},
  year   = {2017}
}
R2 v1 2026-06-22T21:26:43.390Z