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Background

Fix an odd prime $p$ and set $\zeta=e^{2\pi i/p}$. We define the quadratic Gauss sum as

$$g=\sum_{n=0}^{p-1} \zeta^{n^2}.$$

It's pretty easy to show that

$$g^2= \begin{cases} p & \textrm{if } p\equiv 1 \mod 4 \\\ -p & \textrm{if } p\equiv 3 \mod 4, \end{cases}$$

and from this we can deduce quadratic reciprocity; it's harder to determine the modulus. We can actually find an explicit formula for $g$, namely:

$$g= \begin{cases} \sqrt{p} & \textrm{if } p\equiv 1 \mod 4 \\\ i\sqrt{p} & \textrm{if } p\equiv 3 \mod 4. \end{cases}$$

This is the result I refer to for the remainder of the question.

Question

Can we categorify this result?

By categorification, I mean the opposite of decategorification, and by decategorification, I mean the process of removing structure by e.g. taking the cardinality of a set or the dimension of a vector space. (Thus an example of categorification would be interpreting some combinatorial identity of positive integers as a bijection between sets.) This is intentionally vague, because there are plenty of people who have a much better idea of what constitutes categorification than I do, so feel free to interpret "categorification" liberally.

Motivation

Gauss's original proof of our result uses q-binomial coefficients. (A modern exposition of this proof can be found in "The determination of Gauss sums" by Bruce C. Berndt and Ronald J. Evans.)

Now, $q$-binomial coefficients can be categorified by Grassmannian varieties. What I mean by that is: the $q$-binomial coefficient $\binom{n}{k}_q$ is the number of $k$-dimensional subspaces of an $n$-dimensional vector space over the finite field $\mathbb{F}_q$, i.e. the cardinality of the Grassmannian $\textrm{Gr}(n,k)$. Basically, I'm wondering if there is some way this can be connected to the formula for the quadratic Gauss sum, seeing as how the formula is clearly related to the properties of $q$-binomial coefficients.

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    $\begingroup$ The paper, "arxiv.org/abs/math.CT/0212377" makes precise and proves the following principle, "if an arithmetic statement about the objects can be proved by pretending that they are complex numbers, then there also exists an honest proof". $\endgroup$ Jan 3, 2013 at 18:02
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    $\begingroup$ Thanks for your comment. I've heard of that result before somewhere, but never managed to track down a reference. It's very interesting, but doesn't really answer my question. If I had some result about objects that decategorified to this Gauss sum identity, then this paper might give me a proof "for free"; the problem is, I don't know what to prove about the objects yet! $\endgroup$ Jan 5, 2013 at 0:48

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Since you are using an vague definition of categorification, the following maybe relevant. Gauss sums appear in the theory of (pre)-modular categories. The Gauss sum can be viewed as the sum of values of the quadratic form $$\zeta\colon \mathbb{Z}/p\mathbb{Z}\longrightarrow \mathbb{C}^\times, \quad n\longmapsto \zeta^{n^2}.$$ According to [1], "Premodular or ribbon categories are categorical generalizations of quadratic forms of finite abelian groups". As a reference for this analogy, see for example Example 8.13.5 and Section 8.4 of [2]. Any quadratic form $\omega\colon G\to \mathbb{C}^\times$ of an abelian group $G$ gives rise to a tensor category $\mathcal{C}(G,\omega)$ with simple objects $X_g$ corresponding to the elements $g$ of $G$.

A pre-modular category is, a tensor category with duals, a braiding, which is a collection of functorial isomorphisms $c_{X,Y}\colon X\otimes Y\to Y\otimes X$, and other favourable properties like having a finite set of simple objects. To any pre-modular category one can associate the datum of an $S$-matrix which has a motivation from Physics which is a driving force behing the theory of modular categories. The $S$-matrix of the category $\mathcal{C}(G,\omega)$ now corresponds to $\left(b(g,h)\right)_{g,h\in G}$, where $$b(g,h)=\frac{\omega(gh)}{\omega(g)\omega(h)}.$$ In general, the $S$-matrix is defined by $S_{X,Y}=\operatorname{Tr}(c_{Y,X}c_{X,Y})$ for representatives of simple objects $X,Y$ in a pre-modular category $\mathcal{C}$. This used the categorical trace $\operatorname{Tr}$ of $\mathcal{C}$ which is defined using duality. A pre-modular category is modular if the $S$-matrix is non-degenerate. For $\mathcal{C}(G,\omega)$, this condition is equivalent to non-negeneracy of $\omega$.

Therefore, picking $G=\mathbb{Z}/p\mathbb{Z}$ with the above pairing $\omega=\zeta$ gives a modular tensor category categorifying (the group algebra of) $\mathbb{Z}/p\mathbb{Z}$, which is its Grothendieck ring, together with the Gauss sum, which is given by the sum $$g=\sum_{g\in G} \theta_{X_g}\dim (X_g)^2,$$ where $\dim(X_g)$ is the categorical dimension of an object $X_g$, and $\theta_{X_g}$ is the scalar defining the so-called twist isomorphism of $X_g$. In the case of $\mathcal{C}(G,\omega)$, $\theta_{X_g}=b(g,g)$. Gauss sums an invariant for general pre-modular categories.

[1] S.-H. Ng, A. Schopieray, and Y. Wang: Higher Gauss Sums of Modular Categories. https://arxiv.org/pdf/1812.11234.pdf

[2] P. Etingof, S. Gelaki, D. Nikshych, V. Ostrik: Tensor Categories, Mathematical Surveys and Monographs, AMS

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