Infinite order linear differential equation satisfied by p-adic Hurwitz-type Euler zeta functions

Abstract

In 1900, at the international congress of mathematicians, Hilbert claimed that the Riemann zeta function ζ(s) is not the solution of any algebraic ordinary differential equations on its region of analyticity. In 2015, Van Gorder considered the question of whether ζ(s) satisfies a non-algebraic differential equation and showed that it formally satisfies an infinite order linear differential equation. Recently, Prado and Klinger-Logan extended Van Gorder's result to show that the Hurwitz zeta function ζ(s,a) is also formally satisfies a similar differential equation equation*HurDE T[ζ (s,a) - 1as] = 1(s-1)as-1. equation* But unfortunately in the same paper they proved that the operator T applied to Hurwitz zeta function ζ(s,a) does not converge at any point in the complex plane C. In this paper, by defining Tpa, a p-adic analogue of Van Gorder's operator T, we establish an analogue of Prado and Klinger-Logan's differential equation satisfied by ζp,E(s,a) which is the p-adic analogue of the Hurwitz-type Euler zeta functions equation*HEZ ζE(s,a)=Σn=0∞(-1)n(n+a)s. equation* In contrast with the complex case, due to the non-archimedean property, the operator Tpa applied to the p-adic Hurwitz-type Euler zeta function ζp,E(s,a) is convergent p-adically in the area of s∈Zp with s≠ 1 and a∈ K with |a|p>1, where K is any finite extension of Qp with ramification index over Qp less than p-1.