Singular multipliers on multiscale Zygmund sets
Odysseas Bakas, Valentina Ciccone, Francesco Di Plinio, Marco Fraccaroli, Ioannis Parissis, Marco Vitturi
Abstract
Given an Orlicz space $ L^2 \subseteq X \subseteq L^1$ on $[0,1]$, with submultiplicative Young function ${\mathrm{Y}_X}$, we fully characterize the closed null sets $Ξ$ of the real line with the property that Hörmander-Mihlin or Marcinkiewicz multiplier operators $\mathrm{T}_m$ with singularities on $Ξ$ obey weak-type endpoint modular bounds on $X$ of the type \[ \left|\left\{x\in \mathbb R : |\mathrm{T}_m f(x)| >λ\right\}\right| \leq C \int_{\mathbb R} \mathrm{Y}_X \left(\frac{|f|}λ\right), \qquad \forall λ>0. \] These sets $Ξ$ are exactly those enjoying a scale invariant version of Zygmund's $(L\sqrt{\log L},{L^2})$ improving inequality with $X$ in place of the former space, which is termed multiscale Zygmund property. Our methods actually yield sparse and quantitative weighted estimates for the Fourier multipliers $\mathrm{T}_m$ and for the corresponding square functions. In particular, our framework covers the case of singular sets $Ξ$ of finite lacunary order and thus leads to modular and quantitative weighted versions of the classical endpoint theorems of Tao and Wright for Marcinkiewicz multipliers. Moreover, we obtain a pointwise sparse bound for the Marcinkiewicz square function answering a recent conjecture of Lerner. On the other hand, examples of non-lacunary sets enjoying the multiscale Zygmund property for each $X=L^p$, $1<p\leq 2$ are also covered. The main new ingredient in the proofs is a multi-frequency, multi-scale projection lemma based on Gabor expansion, and possessing independent interest.