On generalized Ramsey numbers of Erdős and Rogers

Abstract: Extending the concept of Ramsey numbers, Erd{\H o}s and Rogers introduced the following function. For given integers $2\le s<t$ let $$ f_{s,t}(n)=\min {\max {|W| : W\subseteq V(G) {and} G[W] {contains no} K_s} }, $$ where the minimum is taken over all $K_t$-free graphs $G$ of order $n$. In this paper, we show that for every $s\ge 3$ there exist constants $c_1=c_1(s)$ and $c_2=c_2(s)$ such that $f_{s,s+1}(n) \le c_1 (\log n)^{c_2} \sqrt{n}$. This result is best possible up to a polylogarithmic factor. We also show for all $t-2 \geq s \geq 4$, there exists a constant $c_3$ such that $f_{s,t}(n) \le c_3 \sqrt{n}$. In doing so, we partially answer a question of Erd\H{o}s by showing that $\lim_{n\to \infty} \frac{f_{s+1,s+2}(n)}{f_{s,s+2}(n)}=\infty$ for any $s\ge 4$.