Constants of de Bruijn-Newman type in analytic number theory and statistical physics

Abstract

One formulation in 1859 of the Riemann Hypothesis (RH) was that the Fourier transform Hf(z) of f for z ∈ C has only real zeros when f(t) is a specific function (t). P\'olya's 1920s approach to RH extended Hf to Hf,λ, the Fourier transform of eλ t2 f(t). We review developments of this approach to RH and related ones in statistical physics where f(t) is replaced by a measure d (t). P\'olya's work together with 1950 and 1976 results of de Bruijn and Newman, respectively, imply the existence of a finite constant DN = DN () in (-∞, 1/2] such that H,λ has only real zeros if and only if λ ≥ DN; RH is then equivalent to DN ≤ 0. Recent developments include the Rodgers and Tao proof of the 1976 conjecture that DN ≥ 0 (that RH, if true, is only barely so) and the Polymath 15 project improving the 1/2 upper bound to about 0.22. We also present examples of 's with differing H,λ and DN () behaviors; some of these are new and based on a recent weak convergence theorem of the authors.