Specht module

In set theory, a set is called hereditarily countable if it is a countable set of hereditarily countable sets. This inductive definition is in fact well-founded and can be expressed in the language of first-order set theory. A set is hereditarily countable if and only if it is countable, and every element of its transitive closure is countable. If the axiom of countable choice holds, then a set is hereditarily countable if and only if its transitive closure is countable.

The class of all hereditarily countable sets can be proven to be a set from the axioms of Zermelo–Fraenkel set theory (ZF) without any form of the axiom of choice, and this set is designated ${\displaystyle H_{\aleph _{1}}}$. The hereditarily countable sets form a model of Kripke–Platek set theory with the axiom of infinity (KPI), if the axiom of countable choice is assumed in the metatheory.

If ${\displaystyle x\in H_{\aleph _{1}}}$, then ${\displaystyle L_{\omega _{1}}(x)\subset H_{\aleph _{1}}}$.

More generally, a set is hereditarily of cardinality less than κ if and only it is of cardinality less than κ, and all its elements are hereditarily of cardinality less than κ; the class of all such sets can also be proven to be a set from the axioms of ZF, and is designated ${\displaystyle H_{\kappa }\!}$. If the axiom of choice holds and the cardinal κ is regular, then a set is hereditarily of cardinality less than κ if and only if its transitive closure is of cardinality less than κ.

See also

• Hereditarily finite set
• Constructible universe

External links

• "On Hereditarily Countable Sets" by Thomas Jech

Template:Settheory-stub