Fast Generation of Spectrally-Shaped Disorder

Abstract

Media with correlated disorder display unexpected transport properties, but it is still a challenge to design structures with desired spectral features at scale. In this work, we introduce an optimal formulation of this inverse problem by means of the non-uniform fast Fourier transform, thus arriving at an algorithm capable of generating systems with arbitrary spectral properties, with a computational cost that scales O(N N) with system size. The method is extended to accommodate arbitrary real-space interactions, such as short-range repulsion, to simultaneously control short- and long-range correlations. We thus generate the largest-ever stealthy hyperuniform configurations in 2d (N = 109) and 3d (N > 107). By an Ewald sphere construction we link the spectral and optical properties at the single-scattering level, and show that these structures in 2d and 3d generically display transmission gaps, providing a concrete example of fine-tuning of a physical property at will. We also show that large 3d power-law hyperuniformity in particle packings leads to single-scattering properties near-identical to those of simple hard spheres. Finally, we show that enforcing large spectral power at a small number of peaks with the right symmetry leads to the non-deterministic generation of quasicrystalline structures in both 2d and 3d.