Van der Waerden theorem

on arithmetic progressions

Given natural numbers $\ell,m$, there exists a number $N(\ell,m)$ such that if $n \ge N(\ell,m)$ and $\{1,2,\ldots,n\}$ is partitioned into $m$ sets, then at least one set contains $\ell$ terms in arithmetic progression [a1]. Another, equivalent, non-finitary, formulation is as follows. Let $\mathbb{N} = X_1 \cup \cdots \cup X_m$ be a finite partition of the natural numbers; then at least one $X_i$ contains arithmetic progressions of arbitrary length. The result was conjectured by A. Baudet. Let $A \subset \{1,2,\ldots\}$ be a set of natural numbers and let $\bar d(A)$ be its upper asymptotic density. When discussing van der Waerden's theorem stated above, P. Erdös and P. Turán conjectured that if $\bar d(A) > 0$, then $A$ contains arbitrary long arithmetic progressions; [a2].

Let $B(\ell,n)$ be a maximally large subset of $\{1,2,\ldots,n\}$ which contains no $\ell$ elements in arithmetic progression. Let $b(\ell,n)$ be the number of elements in a $B(\ell,n)$. Then Szemerédi's theorem, [a3], says that $\lim_{n \rightarrow \infty} n^{-1} b(\ell,n) = 0$. This implies the Erdös–Turán conjecture. Another proof of Szemerédi's theorem was given by H. Furstenberg, based on ideas from ergodic theory, [a4].

For a personal historical account of the van der Waerden theorem see [a6].

References