The weak-type Carleson theorem via wave packet estimates

Abstract

We prove that the weak-Lp norms, and in fact the sparse (p,1)-norms, of the Carleson maximal partial Fourier sum operator are (p-1)-1 as p 1+. This is an improvement on the Carleson-Hunt theorem, where the same upper bound on the growth order is obtained for the restricted weak-Lp type norm, and which was the strongest quantitative bound prior to our result. Furthermore, our sparse (p,1)-norms bound imply new and stronger results at the endpoint p=1. In particular, we obtain that the Fourier series of functions from the weighted Arias de Reyna space QA∞(w) , which contains the weighted Antonov space L L L( T; w), converge almost everywhere whenever w∈ A1. This is an extension of the results of Antonov and Arias De Reyna, where w must be Lebesgue measure. The backbone of our treatment is a new, sharply quantified near-L1 Carleson embedding theorem for the modulation-invariant wave packet transform. The proof of the Carleson embedding relies on a newly developed smooth multi-frequency decomposition which, near the endpoint p=1, outperforms the abstract Hilbert space approach of past works, including the seminal one by Nazarov, Oberlin and Thiele. As a further example of application, we obtain a quantified version of the family of sparse bounds for the bilinear Hilbert transforms due to Culiuc, Ou and the first author.