Pinned distance sets, k-simplices, Wolff's exponent in finite fields and sum-product estimates

Abstract

An analog of the Falconer distance problem in vector spaces over finite fields asks for the threshold α>0 such that |(E)| q whenever |E| qα, where E ⊂ Fqd, the d-dimensional vector space over a finite field with q elements (not necessarily prime). Here (E)=\(x1-y1)2+...+(xd-yd)2: x,y ∈ E\. In two dimensions we improve the known exponent to 43, consistent with the corresponding exponent in Euclidean space obtained by Wolff. The pinned distance set y(E)=\(x1-y1)2+...+(xd-yd)2: x∈ E\ for a pin y∈ E has been studied in the Euclidean setting. Peres and Schlag showed that if the Hausdorff dimension of a set E is greater than d+12 then the Lebesgue measure of y(E) is positive for almost every pin y. In this paper we obtain the analogous result in the finite field setting. In addition, the same result is shown to be true for the pinned dot product set y(E)=\x· y: x∈ E\. Under the additional assumption that the set E has cartesian product structure we improve the pinned threshold for both distances and dot products to d22d-1. A generalization of the Falconer distance problem is determine the minimal α>0 such that E contains a congruent copy of every k dimensional simplex whenever |E| qα. Here the authors improve on known results (for k>3) using Fourier analytic methods, showing that α may be taken to be d+k2.