my point exactly.

magicdice I think that may be beyond the scope of many answerbankers...! no offence to them!  I got a first in my MMath degree and firstly i don't think i could answer that and secondly even if i could i couldn't be bothered to go look thru my notes and find out and then type it up... anyway i'm more of a stats person. sorry!

The extract below from http://www.coolissues.com/mathematics/Riemann/riemann.ht m
lost all of the equations, (written in pink Greek letters) when I pasted it into the answer square.  However, the zeros appear to "lie in the strip of the s-plane for which x is between 0 and 1 inclusive".  Even the bits in English are all Greek to me but you might like to take a look.

Introduction

The famous conjecture known as Riemann' s hypothesis1 is to classical analysis what Fermat's last theorem is to arithmetic. Euler (1737) noted that the formula
  
the sum extending to all positive integers n, and the product to all positive primes p. The necessary conditions of convergence hold for complex values of s with real part >1. Considering  as a function of  of the complex variable s, Riemann (1859) proved that  satisfies a functional equation
   =   
which led Riemann to the theorem that all the zeros of  , except those at s=-2,-4,-6, . . . , lie in the strip of the s-plane for which  where x is the real part of s. Riemann conjectured that all the zeros in the strip should lie on the line x= �. Attempts to prove or disprove this conjecture have generated a vast and intricate department of analysis, especially since Hardy (1914) proved that  has an infinity of zeros on x= � .2 The question is still open in 2000. A prize is available to prove or disprove Riemann's hypothesis.3

I did A Level maths and you lost me after the first sentence of the question :-(