Topological realizations of families of ergodic automorphisms, multitowers and orbit equivalence |
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Authors: | Isaac Kornfeld Nicholas Ormes |
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Affiliation: | (1) Department of Mathematics, Northwestern University, 60208 Evanston, IL, USA;(2) Department of Mathematics, University of Denver, 80208 Denver, CO, USA |
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Abstract: | We study minimal topological realizations of families of ergodic measure preserving automorphisms (e.m.p.a.'s). Our main result is the following theorem. Theorem: Let {Tp:p∈I} be an arbitrary finite or countable collection of e.m.p.a.'s on nonatomic Lebesgue probability spaces (Y p v p ). Let S be a Cantor minimal system such that the cardinality of the set ε S of all ergodic S-invariant Borel probability measures is at least the cardinality of I. Then for any collection {μ p :pεI} of distinct measures from ε S there is a Cantor minimal system S′ in the topological orbit equivalence class of S such that, as a measure preserving system, (S 1,μ p ) is isomorphic to Tp for every p∈I. Moreover, S′ can be chosen strongly orbit equivalent to S if and only if all finite topological factors of S are measure-theoretic factors of Tp for all p∈I. This result shows, in particular, that there are no restrictions at all for the topological realizations of countable families of e.m.p.a.'s in Cantor minimal systems. Namely, for any finite or countable collection {T 1,T2,…} of e.m.p.a.'s of nonatomic Lebesgue probability spaces, there is a Cantor minimal systemS, whose collection {μ1,μ2…} of ergodic Borel probability measures is in one-to-one correspondence with {T 1,T2,…}, and such that (S,μ i ) is isomorphic toT i for alli. Furthermore, since realizations are taking place within orbit equivalence classes of a given Cantor minimal system, our results generalize the strong orbit realization theorem and the orbit realization theorem of [18]. Those theorems are now special cases of our result where the collections {T p}, {T p }{μ p } consist of just one element each. Research of I.K. was supported by NSF grant DMS 0140068. |
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