The multilinear circle method and a question of Bergelson
Abstract
Let k∈ Z+ and (X, B(X), μ) be a probability space equipped with a family of commuting invertible measure-preserving transformations T1,…, Tk X X. Let P1,…, Pk∈ Z[ n] be polynomials with integer coefficients and distinct degrees. We establish pointwise almost everywhere convergence of the multilinear polynomial ergodic averages \[AN; X, T1,…, TkP1,…, Pk(f1,…, fk)(x) = 1NΣn=1Nf1(T1P1(n)x)·s fk(TkPk(n)x), x∈ X, \]cas N∞ for any functions f1, …, fk∈ L∞(X). Besides a couple of results in the bilinear setting (when k=2 and then only for single transformations), this is the first pointwise result for general polynomial multilinear ergodic averages in arbitrary measure-preserving systems. This answers a question of Bergelson from 1996 in the affirmative for any polynomials with distinct degrees, and makes progress on the Furstenberg-Bergelson-Leibman conjecture. In this paper, we build a versatile multilinear circle method by developing the Ionescu-Wainger multiplier theorem for the set of canonical fractions, which gives a positive answer to a question of Ionescu and Wainger from 2005. We also establish sharp multilinear Lp-improving bounds and an inverse theorem in higher order Fourier analysis for averages over polynomial corner configurations, which we use to establish a multilinear analogue of Weyl's inequality and its real counterpart, a Sobolev smoothing inequality.
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