Evaluation of the symmetrized Mordell-Tornheim zeta function

Abstract

In this paper we evaluate the symmetrized Mordell-Tornheim zeta function defined as equation* ζn(w1, …, wn) = Σa1, …, an ∈ Z* \\ a1 + … + an = 0 1| a1w1 ·s anwn | equation* where n 1 is a positive integer representing the depth and w1, …, wn 1 are positive integers representing the weight w = w1 + … + wn of the function. Compared to the classical Mordell-Tornheim zeta function ζMT,n(w1, …, wn; wn+1) which is restricted to the positive orthant (hyperoctant), the symmetrized one spans the entire (n-1)-dimensional hyperplane. We show that when the depth and the weight of the function are equal, that is for ζn(1, …, 1), it has a remarkably simple representation in terms of standard functions: equation* ζn(1, …, 1) = Bn(f(1)(0), …, f(n)(0)) equation* where Bn is n-th complete exponential Bell polynomial and f(n)(0) is n-th derivative at x=0 of function f(x) defined as: equation* f(x) = -2x-x equation* Additionally, we show the value can be expressed using the following polynomials with positive integer coefficients over the values of zeta function: equation* ζn(1, …, 1) = Bn(0, (22 - 2) (2) ζ(2), …, (2n - 2) (n) ζ(n)) equation* or equivalently, over the values of eta function: equation* ζn(1, …, 1) = Bn(0, 22 (2) η(2), …, 2n (n) η(n)) equation* The list of explicit values for small 1 n 10 is available in the appendix.

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