Ultradense Sphere Packings Derived From Disordered Stealthy Hyperuniform Ground States
Abstract
Disordered stealthy hyperuniform (SHU) packings are an emerging class of exotic amorphous two-phase materials endowed with novel physical properties. Such packings of identical spheres have been created from SHU point patterns via a modified collective-coordinate optimization scheme that includes a soft-core repulsion, besides the standard `stealthy' pair potential. Using the distributions of minimum pair distances and nearest-neighbor distances, we find that when the stealthiness parameter is lower than 0.5, the maximal values of φ, denoted by φ, decrease to zero on average as the particle number N increases if there are no soft-core repulsions. By contrast, the inclusion of soft-core repulsions results in very large φ independent of N, reaching up to φ=1.0, 0.86, 0.63 in the zero- limit and decreasing to φ=1.0, 0.67, 0.47 at =0.45 for d=1,2,3, respectively. We obtain explicit formulas for φ as functions of and N for a given d. For d=2,3, our soft-core SHU packings for small become configurationally very close to the jammed hard-particle packings created by fast compression algorithms, as measured by the pair statistics. As increases beyond 0.20, the packings form fewer contacts and linear polymer-like chains. The resulting structure factors S(k) and pair correlation functions g2(r) reveal that soft-core repulsions significantly alter the short- and intermediate-range correlations in the SHU ground states. We also compute the spectral density _V(k), which can be used to estimate various physical properties (e.g., electromagnetic properties, fluid permeability, and mean survival time) of SHU two-phase dispersions. Our results offer a new route for discovering novel disordered hyperuniform two-phase materials with unprecedentedly high density.
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