Cellular generation revisited

Abstract

Cellular generation, which generalises cofibrant generation, is an important categorical smallness condition on a class of morphisms. A general challenge is to determine whether a given class of morphisms M is cellularly generated, in which M-effective squares are often useful. These are commuting squares consisting of morphisms in M, so that the induced morphism from the pushout square is also in M. When we drop the requirement that the vertical morphisms in the square are in M we obtain the weaker notion of M-quasieffective square. We prove that, in a locally presentable category, M is cellularly generated if and only if M is almost everywhere quasieffective. The latter is a set-theoretic condition stating that for almost every partial elementary set-theoretic subuniverse N, we have that restricting any morphism in M to N yields an M-quasieffective square. For locally finitely presentable categories this yields an additional categorical characterisation in terms of filtrations of M-quasieffective squares. If we additionally assume that M is continuous (i.e., the corresponding wide subcategory is closed under directed colimits) then we obtain a stronger characterisation of cellular generation in terms of accessibility of the category of M-effective squares. This improves on a theorem by Lieberman, Vasey, and the third author.