Zermelo's categoricity theorem

Last updated May 02, 2024

Zermelo's categoricity theorem was proven by Ernst Zermelo in 1930. It states that all models of a certain second-order version of the Zermelo-Fraenkel axioms of set theory are isomorphic to a member of a certain class of sets.

Statement

Let $\mathrm {ZFC} ^{2}$ denote Zermelo-Fraenkel set theory, but with a second-order version of the axiom of replacement formulated as follows:^[1]

\forall F\forall x\exists y\forall z(z\in y\iff \exists w(w\in x\land z=f(w)))

, namely the second-order universal closure of the axiom schema of replacement.^[2]^p. 289 Then every model of $\mathrm {ZFC} ^{2}$ is isomorphic to a set $V_{\kappa }$ in the von Neumann hierarchy, for some inaccessible cardinal $\kappa$ .^[3]

Original presentation

Zermelo originally considered a version of $\mathrm {ZFC} ^{2}$ with urelements. Rather than using the modern satisfaction relation $\vDash$ , he defines a "normal domain" to be a collection of sets along with the true $\in$ relation that satisfies $\mathrm {ZFC} ^{2}$ .^[4]^p. 9

Related results

Dedekind proved that the second-order Peano axioms hold in a model if and only if the model is isomorphic to the true natural numbers.^[4]^pp. 5–6^[3]^p. 1 Uzquiano proved that when removing replacement form ${\mathsf {ZFC}}^{2}$ and considering a second-order version of Zermelo set theory with a second-order version of separation, there exist models not isomorphic to any $V_{\delta }$ for a limit ordinal $\delta >\omega$ .^[5]^p. 396

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References

↑ S. Shapiro, Foundations Without Foundationalism: A Case for Second-order Logic (1991).
↑ G. Uzquiano, "Models of Second-Order Zermelo Set Theory". Bulletin of Symbolic Logic, vol. 5, no. 3 (1999), pp.289--302.
1 2 Joel David Hamkins; Hans Robin Solberg (2020). "Categorical large cardinals and the tension between categoricity and set-theoretic reflection". arXiv: 2009.07164 [math.LO]., Theorem 1.
1 2 Maddy, Penelope; Väänänen, Jouko (2022). "Philosophical Uses of Categoricity Arguments". arXiv: 2204.13754 [math.LO].
↑ A. Kanamori, "Introductory note to 1930a". In Ernst Zermelo - Collected Works/Gesammelte Werke (2009), DOI 10.1007/978-3-540-79384-7.

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[1] S. Shapiro, Foundations Without Foundationalism: A Case for Second-order Logic (1991).

[Uzquiano99-2] G. Uzquiano, "Models of Second-Order Zermelo Set Theory". Bulletin of Symbolic Logic, vol. 5, no. 3 (1999), pp.289--302.

[HamkinsSolberg22-3] 1 2 Joel David Hamkins; Hans Robin Solberg (2020). "Categorical large cardinals and the tension between categoricity and set-theoretic reflection". arXiv: 2009.07164 [math.LO]., Theorem 1.

[MaddyVaananen23-4] 1 2 Maddy, Penelope; Väänänen, Jouko (2022). "Philosophical Uses of Categoricity Arguments". arXiv: 2204.13754 [math.LO].

[5] A. Kanamori, "Introductory note to 1930a". In Ernst Zermelo - Collected Works/Gesammelte Werke (2009), DOI 10.1007/978-3-540-79384-7.

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