Extreme values of the Dedekind $Ψ$ function
Extreme values of the Dedekind $Ψ$ function
Let $Ψ(n):=n\prod_{p | n}(1+\frac{1}{p})$ denote the Dedekind $Ψ$ function. Define, for $n\ge 3,$ the ratio $R(n):=\frac{Ψ(n)}{n\log\log n}.$ We prove unconditionally that $R(n)< e^γ$ for $n\ge 31.$ Let $N_n=2...p_n$ be the primorial of order $n.$ We prove that the statement $R(N_n)>\frac{e^γ}{ζ(2)}$ for $n\ge 3$ is equivalent to the Riemann Hypothesis.
5 pages, to appear in Journal of Combinatorics and Number theory
Mathematics - Number Theory, FOS: Mathematics, Primorial number, Number Theory (math.NT), Dedekind psi function, Robin criterion, [MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT], Riemann hypothesis, 510
Mathematics - Number Theory, FOS: Mathematics, Primorial number, Number Theory (math.NT), Dedekind psi function, Robin criterion, [MATH.MATH-NT]Mathematics [math]/Number Theory [math.NT], Riemann hypothesis, 510
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