Projective length, phantom extensions, and the structure of flat modules

Abstract

We consider the natural generalization of the notion of the order of a phantom map from the topological setting to triangulated categories. When applied to the derived category of the category of countable flat modules over a countable Dedekind domain, this yields a notion of\ phantom extension of order α <ω 1. We provide a complexity-theoretic characterization of the module Ph% α Ext( C,A) of phantom extensions of order α with respect to the structure of phantom Polish module on Ext( C,A) obtained by considering it as an object of the left heart of the quasi-abelian category of Polish modules. We use this characterization to prove the following Dichotomy Theorem: either all the extensions of a countable flat module A are trivial (which happens precisely when A is divisible) or A has phantom extensions of arbitrarily high order. By producing canonical phantom projective resolutions of order α , we prove that phantom extensions of order α define on the category of countable flat modules an exact structure Eα that is hereditary with enough projectives, and the functor Phα % Ext is the derived functor of Hom with respect to Eα . We prove a Structure Theorem characterizing the objects of the class Pα of countable flat modules that have projective length at most α (i.e., are Eα -projective) as the direct summands of colimits of presheaves of finite flat modules over well-founded forests of rank % 1+α regarded as ordered sets. This can be seen as the first analogue in the flat case of the classical Ulm Classification Theorem for torsion modules.