Symmetric Iterations with Countable and <-Support: A Framework for Choiceless ZF Extensions

Abstract

We develop a unified framework for iterated symmetric extensions with countable support and, more generally, with <-support. Set-length iterations are treated uniformly, and when the iteration template is first-order definable over a Godel-Bernays ground with Global Choice, the construction extends to class-length iterations. At limit stages with cf(λ) we use direct limits; when cf(λ)< we use inverse-limit presentations via trees of conditions together with tuple-stabilizer symmetry filters. The resulting limit filters are normal and -complete, yielding closure of hereditarily symmetric names and preservation of ZF. Under a -Baire (strategic closure) hypothesis we obtain DC<, and under a Localization hypothesis we obtain DC. In the countable-support setting we give an ω1-length construction adding reals and refuting AC while preserving ZF+DC, and we treat mixed products via stable pushforwards and restrictions. For singular , we develop the cf()=ω case using block-partition stabilizers and trees; for arbitrary singular we introduce game-guided fusion of length cf() and a tree-fusion master condition, obtaining singular-limit completeness, preservation of DC<, no collapse of , and no new subsets of any λ<.

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