English

New lower bounds for hypergraph Ramsey numbers

Combinatorics 2018-01-17 v2

Abstract

The Ramsey number rk(s,n)r_k(s,n) is the minimum NN such that for every red-blue coloring of the kk-tuples of {1,,N}\{1,\ldots, N\}, there are ss integers such that every kk-tuple among them is red, or nn integers such that every kk-tuple among them is blue. We prove the following new lower bounds for 4-uniform hypergraph Ramsey numbers: r4(5,n)>2nclogn and r4(6,n)>22cn1/5,r_4(5,n) > 2^{n^{c\log n}} \qquad \hbox{ and } \qquad r_4(6,n) > 2^{2^{cn^{1/5}}}, where cc is an absolute positive constant. This substantially improves the previous best bounds of 2ncloglogn2^{n^{c\log\log n}} and 2nclogn2^{n^{c\log n}}, respectively. Using previously known upper bounds, our result implies that the growth rate of r4(6,n)r_4(6,n) is double exponential in a power of nn. As a consequence, we obtain similar bounds for the kk-uniform Ramsey numbers rk(k+1,n)r_k(k+1, n) and rk(k+2,n)r_k(k+2, n) where the exponent is replaced by an appropriate tower function. This almost solves the question of determining the tower growth rate for {\emph {all}} classical off-diagonal hypergraph Ramsey numbers, a question first posed by Erd\H os and Hajnal in 1972. The only problem that remains is to prove that r4(5,n)r_4(5,n) is double exponential in a power of nn.

Keywords

Cite

@article{arxiv.1702.05509,
  title  = {New lower bounds for hypergraph Ramsey numbers},
  author = {Dhruv Mubayi and Andrew Suk},
  journal= {arXiv preprint arXiv:1702.05509},
  year   = {2018}
}
R2 v1 2026-06-22T18:21:40.541Z