Arithmetic Progressions in the Graphs of Slightly Curved Sequences

Abstract

A strictly increasing sequence of positive integers is called a slightly curved sequence with small error if the sequence can be well-approximated by a function whose second derivative goes to zero faster than or equal to 1/xα for some α>0. In this paper, we prove that arbitrarily long arithmetic progressions are contained in the graph of a slightly curved sequence with small error. Furthermore, we extend Szemer\'edi's theorem to a theorem about slightly curved sequences. As a corollary, it follows that the graph of the sequence \na\n∈ A contains arbitrarily long arithmetic progressions for every 1 a<2 and every A⊂N with positive upper density. Using this corollary, we show that the set \ p1/ba p prime \ contains arbitrarily long arithmetic progressions for every 1 a<2 and b>1. We also prove that, for every a2, the graph of \na\n=1∞ does not contain any arithmetic progressions of length 3.