Set-theoretic mereology as a foundation of mathematics, Logic and Metaphysics Workshop, CUNY, October 2016

This will be a talk for the Logic and Metaphysics Workshop at the CUNY Graduate Center, GC 5382, Monday, October 24, 2016, 4:15-6:15 pm.

Venn_Diagram_of_sets_((P),(Q),(R))Abstract. In light of the comparative success of membership-based set theory in the foundations of mathematics, since the time of Cantor, Zermelo and Hilbert, it is natural to wonder whether one might find a similar success for set-theoretic mereology, based upon the set-theoretic inclusion relation $\subseteq$ rather than the element-of relation $\in$.  How well does set-theoretic mereological serve as a foundation of mathematics? Can we faithfully interpret the rest of mathematics in terms of the subset relation to the same extent that set theorists have argued (with whatever degree of success) that we may find faithful representations in terms of the membership relation? Basically, can we get by with merely $\subseteq$ in place of $\in$? Ultimately, I shall identify grounds supporting generally negative answers to these questions, concluding that set-theoretic mereology by itself cannot serve adequately as a foundational theory.

This is joint work with Makoto Kikuchi, and the talk is based on our joint article:

J. D. Hamkins and M. Kikuchi, Set-theoretic mereology, Logic and Logical Philosophy, special issue “Mereology and beyond, part II”, pp. 1-24, 2016.

4 thoughts on “Set-theoretic mereology as a foundation of mathematics, Logic and Metaphysics Workshop, CUNY, October 2016

  1. Mereology is based on a primitive part-of relation, which is distinct from the settheoretic subset relation. Discrete structure is derived from continuous structure. That seems a better foundation for mathematical structure than the other way around.

    • Oh, I am aware of the mereological purists, and we acknowledge that attitude in our paper. Our project is concerned only with how well set-theoretic mereology, which we define to be the study of the $\subseteq$ relation as an example of mereology, serves as a foundation of mathematics. And the conclusion is that it comes up short, since it has a finitely axiomatizable complete and therefore decidable theory. Perhaps you have some other notion of mereology that you want to use as a foundation; but you should make sure that it does not give rise to an infinite atomic relatively complemented distributive lattice.

      • Ok, how about dropping the axiom of Foundation from ZFC and allow for infinitely descending chains of your set-theoretic inclusion? There is a cottage industry of Non-wellfounded settheory – read http://plato.stanford.edu/entries/nonwellfounded-set-theory/
        I gladly leave it to your expertise to determine whether it may give rise to an ‘infinite atomic relatively complemented distributive lattice.’ That’s not quite my cup of tea….

        • All of the non-well-founded set theories with which I am familiar (e.g. Aczel’s AFA, Boffa’s theory and many others) still prove that the inclusion relation is an atomic unbounded relatively complemented distributive lattice. And so those theories have exactly the same set-theoretic mereological theory as does ZFC, since this is a complete theory. Indeed, in our paper we emphasize that the mereology doesn’t change if you assume every set is finite, and work in the structure of hereditarily finite sets. In this sense, the subset relation cannot tell if infinite sets exist, whether ZFC holds, whether there are non-well-founded sets, and so on.

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