# High moments of the Estermann function

**Authors:** Sandro Bettin

arXiv: 1701.06601 · 2019-03-27

## TL;DR

This paper analyzes the moments of the Estermann function at the central point for prime moduli, deriving asymptotics and power-saving error terms, and explores related moments of continued fraction functions.

## Contribution

It provides the first computation of moments of the Estermann function at the central point for prime moduli and connects these to moments of continued fraction functions.

## Key findings

- Asymptotic formulas for moments of the Estermann function at s=1/2.
- Power saving error terms in moments of Dirichlet L-functions.
- Asymptotic behavior of moments of continued fraction-based functions.

## Abstract

For $a/q\in\mathbb{Q}$ the Estermann function is defined as $D(s,a/q):=\sum_{n\geq1}d(n)n^{-s}\operatorname{e}(n\frac aq)$ if $\Re(s)>1$ and by meromorphic continuation otherwise. For $q$ prime, we compute the moments of $D(s,a/q)$ at the central point $s=1/2$, when averaging over $1\leq a<q$.   As a consequence we deduce the asymptotic for the iterated moment of Dirichlet $L$-functions $\sum_{\chi_1,\dots,\chi_k\mod q}|L(\frac12,\chi_1)|^2\cdots |L(\frac12,\chi_k)|^2|L(\frac12,\chi_1\cdots \chi_k)|^2$, obtaining a power saving error term.   Also, we compute the moments of certain functions defined in terms of continued fractions. For example, writing $f_{\pm}(a/q):=\sum_{j=0}^r (\pm1)^jb_j$ where $[0;b_0,\dots,b_r]$ is the continued fraction expansion of $a/q$ we prove that for $k\geq2$ and $q$ primes one has $\sum_{a=1}^{q-1}f_{\pm}(a/q)^k\sim2 \frac{\zeta(k)^2}{\zeta(2k)} q^k$ as $q\to\infty$.

## Full text

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## References

46 references — full list in the complete paper: https://tomesphere.com/paper/1701.06601/full.md

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Source: https://tomesphere.com/paper/1701.06601