Turing jumps through provability

Abstract

Fixing some computably enumerable theory T, the Friedman-Goldfarb-Harrington (FGH) theorem says that over elementary arithmetic, each 1 formula is equivalent to some formula of the form T provided that T is consistent. In this paper we give various generalizations of the FGH theorem. In particular, for n>1 we relate n formulas to provability statements [n]T True which are a formalization of "provable in T together with all true n+1 sentences". As a corollary we conclude that each [n]T True is n+1-complete. This observation yields us to consider a recursively defined hierarchy of provability predicates [n+1]T which look a lot like [n+1]T True except that where [n+1]T True calls upon the oracle of all true n+2 sentences, the [n+1]T recursively calls upon the oracle of all true sentences of the form n Tφ. As such we obtain a `syntax-light' characterization of n+1 definability whence of Turing jumps which is readily extended beyond the finite. Moreover, we observe that the corresponding provability predicates [n+1]T are well behaved in that together they provide a sound interpretation of the polymodal provability logic GLPω.