# Fourier restriction in low fractal dimensions

**Authors:** Bassam Shayya

arXiv: 1905.09513 · 2023-06-22

## TL;DR

This paper investigates Fourier restriction estimates on fractal sets with varying dimensions, extending known results and employing weighted inequalities to cover different fractal regimes, thereby advancing the understanding of restriction phenomena.

## Contribution

It introduces a unified approach to Fourier restriction estimates on fractal sets by using weighted functions and covers new regimes of fractal dimensions, improving upon previous theorems.

## Key findings

- Established restriction estimates for small fractal dimensions using existing methods.
- Proved a weighted Hölder-type inequality for intermediate dimensions.
- Extended restriction results to larger fractal dimensions by leveraging recent fractal restriction theorems.

## Abstract

Let $S \subset \Bbb R^n$ be a smooth compact hypersurface with a strictly positive second fundamental form, $E$ be the Fourier extension operator on $S$, and $X$ be a Lebesgue measurable subset of $\Bbb R^n$. If $X$ contains a ball of each radius, then the problem of determining the range of exponents $(p,q)$ for which the estimate $\| Ef \|_{L^q(X)} \leq C \| f \|_{L^p(S)}$ holds is equivalent to the restriction conjecture. In this paper, we study the estimate under the following assumption on the set $X$: there is a number $0 < \alpha \leq n$ such that $|X \cap B_R| \leq c \, R^\alpha$ for all balls $B_R$ in $\Bbb R^n$ of radius $R \geq 1$. On the left-hand side of this estimate, we are integrating the function $|Ef(x)|^q$ against the measure $\chi_X dx$. Our approach consists of replacing the characteristic function $\chi_X$ of $X$ by an appropriate weight function $H$, and studying the resulting estimate in three different regimes: small values of $\alpha$, intermediate values of $\alpha$, and large values of $\alpha$. In the first regime, we establish the estimate by using already available methods. In the second regime, we prove a weighted H\"{o}lder-type inequality that holds for general non-negative Lebesgue measurable functions on $\Bbb R^n$, and combine it with the result from the first regime. In the third regime, we borrow a recent fractal Fourier restriction theorem of Du and Zhang and combine it with the result from the second regime. In the opposite direction, the results of this paper improve on the Du-Zhang theorem in the range $0 < \alpha < n/2$.

## Full text

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## References

23 references — full list in the complete paper: https://tomesphere.com/paper/1905.09513/full.md

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Source: https://tomesphere.com/paper/1905.09513