Section24.5Multiplication and Inverses
Subsection24.5.1A series for Euler phi
We can now feel confident applying these amazing facts to calculate the Dirichlet series of \(\phi\) in terms of the Riemann \(\zeta\) function.
We'll use three facts here:
- \(\phi\star u=N\)
- \(\zeta\) is absolutely convergent for \(s>1\)
- The Dirichlet series of \(\phi\) is absolutely convergent as well, as \[0<\sum_{n=1}^\infty \frac{\phi(n)}{n^s}\leq \sum_{n=1}^\infty \frac{n}{n^s}=\sum_{n=1}^\infty\frac{1}{n^{s-1}}\] which converges by the integral test if \(s>2\) (it's also \(\zeta(s-1)\)).
But now we have three other facts.
- The series for \(u\) is \(\zeta(s)\).
- The series for \(N\) (from last time, or above) is \(\zeta(s-1)\).
- So \(P(s)\zeta(s)=\zeta(s-1)\) for \(s>2\).
Subsection24.5.2A general theorem
It turns out that such Euler products (and hence nice computations like this) show up quite frequently.
Proof
Subsection24.5.3A Missing Step: Convergence of Dirichlet Series
Before we start using this in the next section, we have to acknowledge there is a missing step thus far.
We don't actually know much about convergence of these series or products, much less that they converge to each other.Although it is fun to play around, and numerical experimentation will convince you they are very likely, we need more to really use these tools with abandon.
Our goal in this subsection is to prove for the Moebius \(\mu\) function and its series that it converges to the Euler product. Proofs for most other such functions (such as the Riemann zeta function) are similar enough to leave more general proofs to a graduate course.