English

Sharp extension inequalities on finite fields

Classical Analysis and ODEs 2024-07-15 v2 Number Theory

Abstract

Sharp restriction theory and the finite field extension problem have both received a great deal of attention in the last two decades, but so far they have not intersected. In this paper, we initiate the study of sharp restriction theory on finite fields. We prove that constant functions maximize the Fourier extension inequality from the parabola P1Fq2\mathbb{P}^1\subset \mathbb{F}^{2\ast}_q and the paraboloid P2Fq3\mathbb{P}^2\subset \mathbb{F}_q^{3\ast} at the euclidean Stein-Tomas endpoint; here, Fqd\mathbb{F}_q^{d\ast} denotes the (dual) dd-dimensional vector space over the finite field Fq\mathbb F_q with q=pnq=p^n elements, where pp is a prime number greater than 33 or 22, respectively. We fully characterize the maximizers for the L2L4L^2\to L^4 extension inequality from P2\mathbb{P}^2 whenever q1(mod4)q\equiv 1(\text{mod}\, 4). Our methods lead to analogous results on the hyperbolic paraboloid, whose corresponding euclidean problem remains open. We further establish that constants maximize the L2L4L^2\to L^4 extension inequality from the cone Γ3:={(ξ,τ,σ)Fq4:τσ=ξ2}{0}\Gamma^3:=\{(\boldsymbol{\xi},\tau, \sigma)\in \mathbb{F}^{4\ast}_q: \tau\sigma=\boldsymbol{\xi}^2\}\setminus \{{\bf 0}\} whenever q3(mod4)q\equiv 3(\text{mod}\, 4). By contrast, we prove that constant functions fail to be critical points for the corresponding inequality on Γ3{0}\Gamma^3\cup \{{\bf 0}\} over Fp4\mathbb{F}_p^4. While some inspiration is drawn from the euclidean setting, entirely new phenomena emerge which are related to the underlying arithmetic and discrete structures.

Keywords

Cite

@article{arxiv.2405.16647,
  title  = {Sharp extension inequalities on finite fields},
  author = {Cristian González-Riquelme and Diogo Oliveira e Silva},
  journal= {arXiv preprint arXiv:2405.16647},
  year   = {2024}
}

Comments

34 pages; v2: typos corrected, references added

R2 v1 2026-06-28T16:40:59.121Z