Constructing crowded Hausdorff P-spaces in set theory without the axiom of choice
Abstract
For an infinite set X, a closed under finite unions family Z with [X]<ω⊂eqZ⊂eqP(X), and any A⊂eqP(X), the topology τA[Z]=\V∈A: (∀ x∈ V)(∃ z∈ Z)(x z= \y∈A: x⊂eq y⊂eq X z\⊂eq V)\ on A is investigated to give answers to the following open problem in various models of ZF or ZFA: Is there a non-empty Hausdorff, crowded zero-dimensional P-space in the absence of the axiom of choice? Spaces of the form S(X, [X]≤ω)= A, τA[Z] for A=[X]<ω and Z=[X]≤ω are of special importance here. Among many other results, the following theorems are proved in ZF: (1) If X is uncountable, then S(X, [X]≤ω) is a crowded zero-dimensional Hausdorff space, and if X is also quasi Dedekind-finite, then S(X, [X]≤ω) is a P-space; (2) S(ω1, [ω1]≤ω) is a P-space if and only if ω1 is regular; (3) the axiom of countable choice for families of finite sets is equivalent to the statement ``for every infinite Dedekind-finite set X, S(X,[X]≤ω) is a P-space''; (4) the statement ``R admits a topology τ such that , τ is a crowded, zero-dimensional Hausdorff P-space'' is strictly weaker than the axiom of countable choice for families of subsets of R; (5) the statement ``there exists a non-empty, well-orderable crowded zero-dimensional Hausdorff P-space'' is strictly weaker than ``ω1 is regular''. A lot of relevant independence results are obtained.
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