A refined saturation theorem for polynomials and applications
Abstract
For a dynamical system (X,T), d∈N and distinct non-constant integral polynomials p1,…, pd vanishing at 0, the notion of regionally proximal relation along C=\p1,…,pd\ (denoted by RPC[d](X,T)) is introduced. It turns out that for a minimal system, RPC[d](X,T)= implies that X is an almost one-to-one extension of Xk for some k∈N only depending on a set of finite polynomials associated with C and has zero entropy, where Xk is the maximal k-step pro-nilfactor of X. Particularly, when C is a collection of linear polynomials, it is proved that RPC[d](X,T)= implies (X,T) is a d-step pro-nilsystem, which answers negatively a conjecture in 5p. The results are obtained by proving a refined saturation theorem for polynomials.
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