Leonhard Euler proved the Euler product formula for the Riemann zeta function in his thesis ''Variae observationes circa series infinitas'' (''Various Observations about Infinite Series''), published by St Petersburg Academy in 1737. John Derbyshire (2003), chapter 7, "The Golden Key, and an Improved Prime Number Theorem"

The Euler product formula

The Euler product formula for the

Riemann zeta function The Riemann zeta function or Euler–Riemann zeta function, denoted by the Greek letter (zeta), is a mathematical function of a complex variable defined as \zeta(s) = \sum_^\infty \frac = \frac + \frac + \frac + \cdots for \operatorname(s) > ...

reads :

\zeta(s) = \sum_^\infty\frac = \prod_ \frac

where the left hand side equals the Riemann zeta function: :

\zeta(s) = \sum_^\infty\frac = 1+\frac+\frac+\frac+\frac+ \ldots

and the product on the right hand side extends over all prime numbers ''p'': :

\prod_ \frac = \frac\cdot\frac\cdot\frac\cdot\frac \cdots \frac \cdots

Proof of the Euler product formula

This sketch of a

proof Proof most often refers to: * Proof (truth), argument or sufficient evidence for the truth of a proposition * Alcohol proof, a measure of an alcoholic drink's strength Proof may also refer to: Mathematics and formal logic * Formal proof, a con ...

makes use of simple algebra only. This was the method by which

Euler Leonhard Euler ( , ; 15 April 170718 September 1783) was a Swiss mathematician, physicist, astronomer, geographer, logician and engineer who founded the studies of graph theory and topology and made pioneering and influential discoveries in ma ...

originally discovered the formula. There is a certain sieving property that we can use to our advantage: :

\zeta(s) = 1+\frac+\frac+\frac+\frac+ \ldots

\frac\zeta(s) =
\frac+\frac+\frac+\frac+\frac+ \ldots

Subtracting the second equation from the first we remove all elements that have a factor of 2: :

\left(1-\frac\right)\zeta(s) = 1+\frac+\frac+\frac+\frac+\frac+\frac+ \ldots

Repeating for the next term: :

\frac\left(1-\frac\right)\zeta(s) = \frac+\frac+\frac+\frac+\frac+\frac+ \ldots

Subtracting again we get: :

\left(1-\frac\right)\left(1-\frac\right)\zeta(s) = 1+\frac+\frac+\frac+\frac+\frac+ \ldots

where all elements having a factor of 3 or 2 (or both) are removed. It can be seen that the right side is being sieved. Repeating infinitely for

\frac

where

p

is prime, we get: :

\ldots \left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\zeta(s) = 1

Dividing both sides by everything but the ζ(''s'') we obtain: :

\zeta(s) = \frac

This can be written more concisely as an infinite product over all primes ''p'': :

\zeta(s) = \prod_ \frac

To make this proof rigorous, we need only to observe that when

\Re(s) > 1

, the sieved right-hand side approaches 1, which follows immediately from the convergence of the Dirichlet series for

\zeta(s)

The case s = 1

An interesting result can be found for ζ(1), the harmonic series: :

\ldots \left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\left(1-\frac\right)\zeta(1) = 1

which can also be written as, :

\ldots \left(\frac\right)\left(\frac\right)\left(\frac\right)\left(\frac\right)\left(\frac\right)\zeta(1) = 1

which is, :

\left(\frac\right)\zeta(1) = 1

as,

\zeta(1) = 1+\frac+\frac+\frac+\frac+ \ldots

thus, :

1+\frac+\frac+\frac+\frac+ \ldots = \frac

While the series ratio test is inconclusive for the left-hand side it may be shown divergent by bounding logarithms. Similarly for the right-hand side the infinite coproduct of reals greater than one does not guarantee divergence, e.g., :

\lim_ \left(1+\frac\right)^n = e

. Instead, the denominator may be written in terms of the

primorial In mathematics, and more particularly in number theory, primorial, denoted by "#", is a function from natural numbers to natural numbers similar to the factorial function, but rather than successively multiplying positive integers, the function ...

numerator so that divergence is clear :

\frac= e^=\sum_^\infty \frac\left(\sum_^\infty\sum_^n \frac\right)^m

given the trivial composed logarithmic divergence of an inverse prime series.

Another proof

Each factor (for a given prime ''p'') in the product above can be expanded to a geometric series consisting of the reciprocal of ''p'' raised to multiples of ''s'', as follows :

\frac = 1 + \frac + \frac + \frac + \ldots + \frac + \ldots

When

\Re(s) > 1

, this series

converges absolutely In mathematics, an infinite series of numbers is said to converge absolutely (or to be absolutely convergent) if the sum of the absolute values of the summands is finite. More precisely, a real or complex series \textstyle\sum_^\infty a_n is s ...

. Hence we may take a finite number of factors, multiply them together, and rearrange terms. Taking all the primes ''p'' up to some prime number limit ''q'', we have :

\left, \zeta(s) - \prod_\left(\frac\right)\ < \sum_^\infty \frac

where σ is the real part of ''s''. By the fundamental theorem of arithmetic, the partial product when expanded out gives a sum consisting of those terms ''n''^−''s'' where ''n'' is a product of primes less than or equal to ''q''. The inequality results from the fact that therefore only integers larger than ''q'' can fail to appear in this expanded out partial product. Since the difference between the partial product and ζ(''s'') goes to zero when σ > 1, we have convergence in this region.

References

* John Derbyshire, '' Prime Obsession: Bernhard Riemann and The Greatest Unsolved Problem in Mathematics'', Joseph Henry Press, 2003, {{isbn, 978-0-309-08549-6

Notes