In mathematics, an Euler product is an infinite product expansion, indexed by prime numbers p, of a Dirichlet series. The name arose from the case of the Riemann zeta-function, where such a product representation was proved by Euler.

In general, a Dirichlet series of the form

$\backslash sum\_\{n\}\; a(n)n^\{-s\}\backslash ,$

where a(n) is a multiplicative function of n may be written as

$\backslash prod\_\{p\}\; P(p,s)\backslash ,$

where P(p,s) is the sum

$1+a(p)p^\{-s\}\; +\; a(p^2)p^\{-2s\}\; +\; \backslash cdots\; .$

In fact, if we consider these as formal generating functions, the existence of such a formal Euler product expansion is a necessary and sufficient condition that a(n) be multiplicative: this says exactly that a(n) is the product of the a(p^k) when n factorises as the product of the powers p^k of distinct primes p.

In practice all the important cases are such that the infinite series and infinite product expansions are absolutely convergent in some region

Re(s) > C

that is, in some right half-plane in the complex numbers. This already gives some information, since the infinite product, to converge, must give a non-zero value; hence the function given by the infinite series is not zero in such a half-plane.

An important special case is that in which P(p,s) is a geometric series, because a(n) is totally multiplicative. Then we shall have

$P(p,s)=\backslash frac\{1\}\{1-a(p)p^\{-s\}\}$

as is the case for the Riemann zeta-function (with a(n) = 1), and more generally for Dirichlet characters. In the theory of modular forms it is typical to have Euler products with quadratic polynomials in the denominator here. The general Langlands philosophy includes a comparable explanation of the connection of polynomials of degree m, and the representation theory for GL_m.

List of Euler products

$\backslash frac\{1\}\{\backslash zeta(s)\; \}=\; \backslash prod\_\{p\}\; (1-p^\{-s\})=\; \backslash sum\_\{n=1\}^\{\backslash infty\}\backslash mu\; (n)n^\{-s\}$

References

• Tom M. Apostol, Introduction to Analytic Number Theory, (1976) Springer-Verlag, New York. ISBN 0387901639 (Provides an introductory discussion of the Euler product in the context of classical number theory.)

Zeta and L-functions

Produit eulérien