A Computably Enumerable tt-Degree Without Computably Enumerable Irreducible m-Degrees

Abstract

In this paper, we provide a negative solution to Problem 3 formulated by P.~Odifreddi in his survey articles ``Strong Reducibilities'' (1981) and ``Reducibilities'' (1999). The problem asks whether every computably enumerable (c.e.) tt-degree contains a c.e.\ irreducible m-degree (i.e., an m-degree consisting of only one 1-degree). We answer this question in the negative by proving the existence of a c.e.\ tt-degree that does not contain any c.e.\ irreducible m-degree. Our proof relies on the structural properties of c.e.\ semirecursive sets with a rigid complement, originally constructed by A.~N.~Degtev. We show that the unique c.e.\ m-degree contained within the tt-degree of such a set consists of simple sets, which cannot be cylinders, and therefore necessarily splits into multiple 1-degrees. Furthermore, our result demonstrates that a classical 1969 theorem by C.~G.~Jockusch Jr. -- which guarantees the existence of an irreducible m-degree within every c.e.\ tt-degree -- is strictly optimal and cannot be generally strengthened to require such an m-degree to be computably enumerable.