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Worldly cardinal

In mathematical set theory, a worldly cardinal is a cardinal κ such that the rank V<sub>κ</sub> is a model of Zermelo–Fraenkel set theory. A strong limit cardinal κ is worldly if and only if for every natural n, there are unboundedly many ordinals θ < κ such that V<sub>θ</sub> ≺<sub>Σ<sub>n</sub></sub> V<sub>κ</sub>.

Relationship to inaccessible cardinals

By Zermelo's categoricity theorem, every inaccessible cardinal is worldly. By Shepherdson's theorem, inaccessibility is equivalent to the stronger statement that (V<sub>κ</sub>, V<sub>κ+1</sub>) is a model of second order Zermelo-Fraenkel set theory. Being worldly and being inaccessible are not equivalent; in fact, the smallest worldly cardinal has countable cofinality and therefore is a singular cardinal.

The following are in strictly increasing order, where is the least inaccessible cardinal:

  • The least worldly κ.
  • The least worldly κ and λ (κ&lt;λ, and same below) with V<sub>κ</sub> and V<sub>λ</sub> satisfying the same theory.
  • The least worldly κ that is a limit of worldly cardinals (equivalently, a limit of κ worldly cardinals).
  • The least worldly κ and λ with V<sub>κ</sub> ≺<sub>Σ<sub>2</sub></sub> V<sub>λ</sub> (this is higher than even a κ-fold iteration of the above item).
  • The least worldly κ and λ with V<sub>κ</sub> ≺ V<sub>λ</sub>.
  • The least worldly κ of cofinality ω<sub>1</sub> (corresponds to the extension of the above item to a chain of length ω<sub>1</sub>).
  • The least worldly κ of cofinality ω<sub>2</sub> (and so on).
  • The least κ>ω with V<sub>κ</sub> satisfying replacement for the language augmented with the (V<sub>κ</sub>,∈) satisfaction relation.
  • The least κ inaccessible in L<sub>κ</sub>(V<sub>κ</sub>); equivalently, the least κ>ω with V<sub>κ</sub> satisfying replacement for formulas in V<sub>κ</sub> in the infinitary logic L<sub>∞,ω</sub>.
  • The least κ with a transitive model M⊂V<sub>κ+1</sub> extending V<sub>κ</sub> satisfying Morse–Kelley set theory.
  • (not a worldly cardinal) The least κ with V<sub>κ</sub> having the same Σ<sub>2</sub> theory as V<sub></sub>.
  • The least κ with V<sub>κ</sub> and V<sub></sub> having the same theory.
  • The least κ with L<sub>κ</sub>(V<sub>κ</sub>) and L<sub></sub>(V<sub></sub>) having the same theory.
  • (not a worldly cardinal) The least κ with V<sub>κ</sub> and V<sub></sub> having the same Σ<sub>2</sub> theory with real parameters.
  • (not a worldly cardinal) The least κ with V<sub>κ</sub> ≺<sub>Σ<sub>2</sub></sub> V<sub></sub>.
  • The least κ with V<sub>κ</sub> ≺ V<sub></sub>.
  • The least infinite κ with V<sub>κ</sub> and V<sub></sub> satisfying the same L<sub>∞,ω</sub> statements that are in V<sub>κ</sub>.
  • The least κ with a transitive model M⊂V<sub>κ+1</sub> extending V<sub>κ</sub> and satisfying the same sentences with parameters in V<sub>κ</sub> as V<sub></sub> does.
  • The least inaccessible cardinal .

References

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