Dispersion and Littlewood's conjecture

TL;DR

The paper constructs a large set of real numbers for which a refined Diophantine approximation property holds for almost all other numbers, improving previous results and exploring applications to special number sets.

Contribution

It provides an explicit full-measure set with enhanced approximation properties and introduces new techniques using dispersion estimates and the Three Distance Theorem.

Findings

Constructed a full-measure set of lpha with strong approximation properties.

Achieved a significant quantitative improvement over previous results.

Showed the exceptional set has Fourier dimension zero and applied results to badly approximable numbers.

Abstract

Let $\varepsilon>0$. We construct an explicit, full-measure set of $\alpha \in[0,1]$ such that if $\gamma \in \mathbb{R}$ then, for almost all $\beta \in[0,1]$, if $\delta \in \mathbb{R}$ then there are infinitely many integers $n\geq 1$ for which \[ n \Vert n\alpha - \gamma \Vert \cdot \Vert n\beta - \delta \Vert < \frac{(\log \log n)^{3 + \varepsilon}}{\log n}. \] This is a significant quantitative improvement over a result of the first author and Zafeiropoulos. We show, moreover, that the exceptional set of $\beta$ has Fourier dimension zero, alongside further applications to badly approximable numbers and to lacunary diophantine approximation. Our method relies on a dispersion estimate and the Three Distance Theorem.