The pointwise convergence of Fourier Series (I). On a conjecture of Konyagin

Abstract

We provide a near-complete classification of the Lorentz spaces for which the sequence \Sn\n∈ N of partial Fourier sums is almost everywhere convergent along lacunary subsequences. Moreover, under mild assumptions on the fundamental function , we identify := L L L as the largest Lorentz space on which the lacunary Carleson operator is bounded as a map to L1,∞. In particular, we disprove a conjecture stated by Konyagin in his 2006 ICM address. Our proof relies on a newly introduced concept of a "Cantor Multi-tower Embedding," a special geometric configuration of tiles that can arise within the time-frequency tile decomposition of the Carleson operator. This geometric structure plays an important role in the behavior of Fourier series near L1, being responsible for the unboundedness of the weak-L1 norm of a "grand maximal counting function" associated with the mass levels.