English

A discretized Severi-type theorem with applications to harmonic analysis

Classical Analysis and ODEs 2021-01-26 v3 Algebraic Geometry

Abstract

In 1901, Severi proved that if ZZ is an irreducible hypersurface in P4(C)\mathbb{P}^4(\mathbb{C}) that contains a three dimensional set of lines, then ZZ is either a quadratic hypersurface or a scroll of planes. We prove a discretized version of this result for hypersurfaces in R4\mathbb{R}^4. As an application, we prove that at most δ2ε\delta^{-2-\varepsilon} direction-separated δ\delta-tubes can be contained in the δ\delta-neighborhood of a low-degree hypersurface in R4\mathbb{R}^4. This result leads to improved bounds on the restriction and Kakeya problems in R4\mathbb{R}^4. Combined with previous work of Guth and the author, this result implies a Kakeya maximal function estimate at dimension 3+1/283+1/28, which is an improvement over the previous bound of 33 due to Wolff. As a consequence, we prove that every Besicovitch set in R4\mathbb{R}^4 must have Hausdorff dimension at least 3+1/283+1/28. Recently, Demeter showed that any improvement over Wolff's bound for the Kakeya maximal function yields new bounds on the restriction problem for the paraboloid in R4\mathbb{R}^4.

Keywords

Cite

@article{arxiv.1801.05106,
  title  = {A discretized Severi-type theorem with applications to harmonic analysis},
  author = {Joshua Zahl},
  journal= {arXiv preprint arXiv:1801.05106},
  year   = {2021}
}

Comments

58 pages, 4 figures. v3: Typo corrected in Section 2 to match published version. Added journal-ref and DOI

R2 v1 2026-06-22T23:46:14.041Z