Ramsey-like theorems and moduli of computation

Abstract

Ramsey's theorem asserts that every k-coloring of [ω]n admits an infinite monochromatic set. Whenever n ≥ 3, there exists a computable k-coloring of [ω]n whose solutions compute the halting set. On the other hand, for every computable k-coloring of [ω]2 and every non-computable set C, there is an infinite monochromatic set H such that C ≤T H. The latter property is known as cone avoidance. In this article, we design a natural class of Ramsey-like theorems encompassing many statements studied in reverse mathematics. We prove that this class admits a maximal statement satisfying cone avoidance and use it as a criterion to re-obtain many existing proofs of cone avoidance. This maximal statement asserts the existence, for every k-coloring of [ω]n, of an infinite subdomain H ⊂eq ω over which the coloring depends only on the sparsity of its elements. This confirms the intuition that Ramsey-like theorems compute Turing degrees only through the sparsity of its solutions.