Riemann Hypothesis on Grönwall's Function

EasyChair Preprint 9117, version 10

Abstract

Grönwall's function $G$ is defined for all natural numbers $n>1$ by $G(n)=\frac{\sigma(n)}{n \cdot \log \log n}$ where $\sigma(n)$ is the sum of the divisors of $n$ and $\log$ is the natural logarithm. We require the properties of extremely abundant numbers, that is to say left to right maxima of $n \mapsto G(n)$. We also use the colossally abundant and hyper abundant numbers. There are several statements equivalent to the famous Riemann hypothesis. We state that the Riemann hypothesis is true if and only if there exist infinitely many consecutive colossally abundant numbers $N< N'$ such that $G(N)< G(N')$. Using this new criterion, we prove that the Riemann hypothesis is true.

Keyphrases: Arithmetic Functions, Colossally abundant numbers, Extremely abundant numbers, Hyper abundant numbers, Riemann hypothesis

@booklet{EasyChair:9117,
  author    = {Frank Vega},
  title     = {Riemann Hypothesis on Grönwall's Function},
  howpublished = {EasyChair Preprint 9117},
  year      = {EasyChair, 2023}}