An Explicit Tauberian Theorem taking Averaged Inputs with an Application to Counting Abelian Number Fields

Abstract

Given a Dirichlet series L(s) = Σ an n-s, the asymptotic growth rate of Σn X an can be determined by a Tauberian theorem. Bounds on the error term are typically controlled by the size of |L(σ+it)| for fixed real part σ. We modify this approach to prove new Tauberian theorems with error terms depending only on the average size of L(σ+it) as t varies, and we take care to track explicit dependence on various parameters. This often leads to stronger error bounds, and introduces strong connections between asymptotic counting problems and moments of L-functions. We provide self-contained statements of Tauberian theorems in anticipation that these results can be used ``out of the box'' to prove new asymptotic expansions. We demonstrate this by proving square root saving error bounds for the number of Cn-extensions of Q of bounded discriminant when n=3, 4, 8, 16, or 2p for p an odd prime.