Rigid many-one degrees contain infinite antichains of 1-degrees

Abstract

Odifreddi asked whether every non-irreducible many-one degree must contain an infinite antichain of one-one degrees. Positive answers are known for computably enumerable many-one degrees (Degtev) and, more recently, for many-one degrees admitting a 02 representative (Batyrshin). In this note we isolate a rigidity principle behind these phenomena. Call a set A⊂eqω m-rigid if every total computable m-autoreduction of A is eventually the identity. We prove that if A is m-rigid, then its many-one degree m(A) contains an infinite antichain of 1-degrees. The proof uses a uniform duplication construction: for each computable parameter S we define BSm A so that any injective reduction BS1 BT induces an m-autoreduction of A and therefore forces S⊂eq*T. Choosing an almost-inclusion infinite antichain of computable sets yields the desired infinite 1-antichain inside m(A). As applications, Jockusch's rigidity theorem implies that every 1-generic set is m-rigid, giving a comeager family of positive instances. Moreover, m-rigidity holds with Lebesgue measure 1 (indeed, every Martin-L\"of random real is m-rigid). Consequently, Odifreddi's Question~5 has a positive answer with probability 1 for a fair-coin random A∈ 2ω; any counterexample (if it exists) is confined to a null set (and, by genericity, also to a meager set).