English

Cohesive avoidance and arithmetical sets

Logic 2012-12-05 v1

Abstract

An open question in reverse mathematics is whether the cohesive principle, \COH\COH, is implied by the stable form of Ramsey's theorem for pairs, \SRT22\SRT^2_2, in ω\omega-models of \RCA\RCA. One typical way of establishing this implication would be to show that for every sequence R\vec{R} of subsets of ω\omega, there is a set AA that is Δ20\Delta^0_2 in R\vec{R} such that every infinite subset of AA or Aˉ\bar{A} computes an R\vec{R}-cohesive set. In this article, this is shown to be false, even under far less stringent assumptions: for all natural numbers n2n \geq 2 and m<2nm < 2^n, there is a sequence R=\sequenceR0,...,Rn1\vec{R} = \sequence{R_0,...,R_{n-1}} of subsets of ω\omega such that for any partition A0,...,Am1A_0,...,A_{m-1} of ω\omega arithmetical in R\vec{R}, there is an infinite subset of some AjA_j that computes no set cohesive for R\vec{R}. This complements a number of previous results in computability theory on the computational feebleness of infinite sets of numbers with prescribed combinatorial properties. The proof is a forcing argument using an adaptation of the method of Seetapun showing that every finite coloring of pairs of integers has an infinite homogeneous set not computing a given non-computable set.

Keywords

Cite

@article{arxiv.1212.0828,
  title  = {Cohesive avoidance and arithmetical sets},
  author = {Damir D. Dzhafarov},
  journal= {arXiv preprint arXiv:1212.0828},
  year   = {2012}
}
R2 v1 2026-06-21T22:48:42.681Z