Multiorders in amenable group actions

Abstract

The paper offers a thorough study of multiorders and their applications to measure-preserving actions of countable amenable groups. By a~ multiorder on a~countable group we mean any probability measure on the collection O of linear orders of type Z on G, invariant under the natural action of G on such orders. Every free measure-preserving G-action (X,μ,G) has a~multiorder (O,,G) as a factor and has the same orbits as the Z-action (X,μ,S), where S is the successor map determined by the multiorder factor. Moreover, the sub-sigma-algebra O associated with the multiorder factor is invariant under S, which makes the corresponding Z-action (O,, S) a factor of (X,μ,S). We prove that the entropy of any G-process generated by a finite partition of X, conditional with respect to O, is preserved by the orbit equivalence with (X,μ,S). Furthermore, this entropy can be computed in terms of the so-called random past, by a formula analogous to h(μ,T, P)=H(μ, P|P-) known for Z-actions. The above fact is then applied to prove a variant of a result by Rudolph and Weiss. The original theorem states that orbit equivalence between free actions of countable amenable groups preserves conditional entropy with respect to a~sub-sigma-algebra , as soon as the ``orbit change'' is measurable with respect to . In our variant, we replace the measurability assumption by a~simpler one: should be invariant under both actions and the actions on the resulting factor should be free. In conclusion we provide a characterization of the Pinsker sigma-algebra of any G-process in terms of an appropriately defined remote past arising from a multiorder.