Quasicrystal Scattering and the Riemann Zeta Function

Abstract

We construct a one-dimensional quasicrystal by placing scatterers at positions χn = (pn), the logarithms of the primes. This map compresses the primes to approximately constant density and yields a Fourier transform that is directly parameterized by the Riemann zeta function: the scattering amplitude χL(k) = Σ pn-2πik, and the non-trivial zeros of ζ(s) enter as poles of -ζ'/ζ in the spectral decomposition, producing peaks at positions γ/2π. We evaluate this Fourier transform analytically in the limit L∞ via Perron's formula and the residue theorem, showing that the normalized amplitude assigns each non-trivial zero ρm a coefficient proportional to pLβm - 1/2. We then prove, using the unconditional Fourier self-duality identity F[F[χ]] = χ(-\,·\,) in the space of tempered distributions, that these coefficients must all be O(1), which forces βm = 1/2 for every non-trivial zero.