English

The Lerch zeta function III. Polylogarithms and special values

Number Theory 2016-08-11 v2

Abstract

This paper studies algebraic and analytic structures associated with the Lerch zeta function, extending the complex variables viewpoint taken in part II. The Lerch transcendent Φ(s,z,c)\Phi(s, z, c) is obtained from the Lerch zeta function ζ(s,a,c)\zeta(s, a, c) by the change of variable z=e2πiaz=e^{2 \pi i a}. We show that it analytically continues to a maximal domain of holomorphy in three complex variables (s,z,c)(s, z, c) as a multivalued function defined over the base manifold C×P1(C{0,1,})×(CZ){\bf C} \times P^1({\bf C} \smallsetminus \{0, 1, \infty\}) \times ({\bf C}\smallsetminus {\bf Z}). and compute the monodromy functions defining the multivaluedness. For positive integer values s=m and c=1 this function is closely related to the classical m-th order polylogarithm Lim(z)Li_m(z) We study its behavior as a function of two variables (z,c)(z, c) for special values where s=m is an integer. For m1m \ge 1 it gives a one-parameter deformation of the polylogarithm, and satisfies a linear ODE with coefficients depending on c, of order m+1 of Fuchsian type. We determine its (m+1)-dimensional monodromy representation, which is a non-algebraic deformation of the monodromy of Lim(z).Li_m(z).

Keywords

Cite

@article{arxiv.1506.06161,
  title  = {The Lerch zeta function III. Polylogarithms and special values},
  author = {Jeffrey C. Lagarias and W. -C. Winnie Li},
  journal= {arXiv preprint arXiv:1506.06161},
  year   = {2016}
}

Comments

55 pages, 6 figures

R2 v1 2026-06-22T09:57:02.959Z