Vector Representations of Euler’s Formula and Riemann’s Zeta Function

Just as Gauss's interpretation of complex numbers as points in a number plane in the form of a suitably formulated axiom found its way into the vector representation of Fourier transforms, this is the case with Euler's formula and Riemann's Zeta function considered here. The description of the connection between variables through complex numbers as it is given in Euler's formula and emphasized by Riemann, is reflected here with great flexibility in the introduction of non-classically generalized complex numbers and the vector representation of the generalized Zeta function based on them. For describing such dependencies of two variables with the help of generalized complex numbers, we introduce manifolds underlying certain Lie groups as level sets of norms, antinorms or semi-antinorms. No undefined or "imaginary" quantities are used for this. In contrast to the approach of Hamilton and his numerous successors, the vector-valued vector product of non-classically generalized complex numbers is commutative and the whole number system satisfies a weak distributivity property as considered by Hankel, but not the strong one.