A proof of Newman's conjecture for the extended Selberg class

Abstract

Newman's conjecture (proved by Rodgers and Tao in 2018) concerns a certain family of deformations \t(s)\t ∈ R of the Riemann xi function for which there exists an associated constant ∈ R (called the de Bruijn-Newman constant) such that all the zeros of t lie on the critical line if and only if t ≥ . The Riemann hypothesis is equivalent to the statement that ≤ 0, and Newman's conjecture states that ≥ 0. In this paper we give a new proof of Newman's conjecture which avoids many of the complications in the proof of Rodgers and Tao. Unlike the previous best methods for bounding , our approach does not require any information about the zeros of the zeta function, and it can be readily be applied to a wide variety of L-functions. In particular, we establish that any L-function in the extended Selberg class has an associated de Bruijn-Newman constant and that all of these constants are nonnegative. Stated in the Riemann xi function case, our argument proceeds by showing that for every t < 0 the function t can be approximated in terms of a Dirichlet series ζt(s)=Σn=1∞(t4 2 n)n-s whose zeros then provide infinitely many zeros of t off the critical line.