English

Filtration Games and Potentially Projective Modules

Logic 2022-10-12 v3

Abstract

The notion of a \textbf{C\boldsymbol{\mathcal{C}}-filtered} object, where C\mathcal{C} is some (typically small) collection of objects in a Grothendieck category, has become ubiquitous since the solution of the Flat Cover Conjecture around the year 2000. We introduce the \textbf{C\boldsymbol{\mathcal{C}}-Filtration Game of length ω1\boldsymbol{\omega_1}} on a module, paying particular attention to the case where C\mathcal{C} is the collection of all countably presented, projective modules. We prove that Martin's Maximum implies the determinacy of many C\mathcal{C}-Filtration Games of length ω1\omega_1, which in turn imply the determinacy of certain Ehrenfeucht-Fra\"iss\'{e} games of length ω1\omega_1; this allows a significant strengthening of a theorem of Mekler-Shelah-Vaananen \cite{MR1191613}. Also, Martin's Maximum implies that if RR is a countable hereditary ring, the class of \textbf{σ\boldsymbol{\sigma}-closed potentially projective modules} -- i.e., those modules that are projective in some σ\sigma-closed forcing extension of the universe -- is closed under <2<\aleph_2-directed limits. We also give an example of a (ZFC-definable) class of abelian groups that, under the ordinary subgroup relation, constitutes an Abstract Elementary Class (AEC) with L\"owenheim-Skolem number 1\aleph_1 in some models in set theory, but fails to be an AEC in other models of set theory.

Keywords

Cite

@article{arxiv.2010.00184,
  title  = {Filtration Games and Potentially Projective Modules},
  author = {Sean D. Cox},
  journal= {arXiv preprint arXiv:2010.00184},
  year   = {2022}
}

Comments

minor corrections

R2 v1 2026-06-23T18:55:33.102Z