local zeta-function

In number theory, a local zeta-function is a generating function Z(t) for the number of solutions of a set of equations defined over a finite field F, in extension fields F_k of F. The analogy with the Riemann zeta function

\zeta(s)

comes via consideration of the logarithmic derivative

\zeta'(s)/\zeta(s)

. Given F, there is, up to isomorphism, just one field F_k with F_k:F = k, for k = 1,2, ... . Given polynomial equations - or an algebraic variety V - defined over F, we can count the number N_k of solutions in F_k; and create the generating function G(t) = N₁.t + N₂.t²/2 + ... . The correct definition for Z(t) is to make log Z equal to G, and so Z = exp(G); we will have Z(0) = 1 since G(0) = 0, and Z(t) is a priori a formal power series. For example, assume all the N_k are 1 (this happens for example if we start with an equation like X = 0, so that geometrically we are taking V a point). Then G(t) = log(1 - t) is the expansion of a logarithm (for |t| < 1). In this case we have Z(t) = 1/(1 - t). To take something more interesting, let V be the projective line over F. If F has q elements, then this has q + 1 points, including as we must the one point at infinity. Therefore we shall have N_k = q^k + 1 and G(t) = log(1 - t) + log(1 - qt), for |t| small enough. In this case we have Z(t) = 1/{(1 - t)(1 - qt)}. The relationship between the definitions of G and Z can be explained in a number of ways. In practice it makes Z a rational function of t, something that is interesting even in the case of V an elliptic curve over finite field. It is the functions Z that are designed to multiply, to get global zeta functions. Those involve different finite fields (for example the whole family of fields Z/p.Z as p runs over all prime numbers. In that relationship, the variable t undergoes substitution by p^-s, where s is the complex variable traditionally used in Dirichlet series. This explains too why the logarithmic derivative with respect to s is used. With that understanding, the products of the Z in the two cases come out as

\zeta(s)

and

\zeta(s)\zeta(s-1)

Riemann hypothesis for curves over finite fields

For projective curves over F that are non-singular, it can be shown that Z(t) = P(t)/{(1 - t)(1 - qt)}, with P(t) a polynomial, of degree 2g where g is the genus of C. The Riemann hypothesis for curves over finite fields states that the roots of P have absolute value q^-1/2, where q = |F|. For example, for the elliptic curve case there are two roots, and it is easy to show their product is q^-1. Hasse's theorem is that they have the same absolute value; and this has immediate consequences for the number of points. Weil proved this for the general case, around 1940 (Comptes Rendus note, April 1940): he spent much time in the years after that, writing up the algebraic geometry involved). This led him to the general Weil conjectures, finally proved a generation later. See etale cohomology for the basic formulae of the general theory.

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