# Explicit $L^2$ bounds for the Riemann $\zeta$ function

**Authors:** Daniele Dona, Harald A. Helfgott, Sebastian Zuniga Alterman

arXiv: 1906.01097 · 2024-02-20

## TL;DR

This paper provides explicit $L^2$ bounds for the tails of the Riemann zeta function, using two different methods optimized for different ranges, aiding in rigorous integral computations involving $	eta$.

## Contribution

It introduces two novel approaches for bounding weighted $L^2$ norms of $	eta$ tails, improving accuracy across different ranges of $T$ and $\sigma$.

## Key findings

- Bounds are of the correct order for $0<\sigma	extless 1$.
- Methods are practical for rigorous computation of improper integrals.
- Bounds for the $L^2$ norm of $	eta$ in $[1,T]$ are also provided.

## Abstract

Explicit bounds on the tails of the zeta function $\zeta$ are needed for applications, notably for integrals involving $\zeta$ on vertical lines or other paths going to infinity. Here we bound weighted $L^2$ norms of tails of $\zeta$.   Two approaches are followed, each giving the better result on a different range. The first one is inspired by the proof of the standard mean value theorem for Dirichlet polynomials. The second approach, superior for large $T$, is based on classical lines, starting with an approximation to $\zeta$ via Euler-Maclaurin.   Both bounds give main terms of the correct order for $0<\sigma\leq 1$ and are strong enough to be of practical use for the rigorous computation of improper integrals.   We also present bounds for the $L^{2}$ norm of $\zeta$ in $[1,T]$ for $0\leq\sigma\leq 1$.

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Source: https://tomesphere.com/paper/1906.01097