Exotic Acoustic-Edge and Thermal Scaling in Disordered Hyperuniform Networks

Abstract

We develop a first-principles theory for the vibrational density of states (VDOS) and thermal properties of network materials built on stationary correlated disordered point configurations. For scalar (mass--spring) models whose dynamical matrix is a distance-weighted graph Laplacian, we prove that the limiting spectral measure is the pushforward of Lebesgue measure by a Fourier symbol that depends only on the edge kernel \(f\) and the two-point statistics \(g2\) (equivalently the structure factor \(S\)). For hyperuniform systems with small-k scaling \(S(k) kα\) and compensated kernels, the VDOS exhibits an algebraic pseudogap at low frequency, \(g(ω) ω\,2d/β-1\) with \(β=\4,α+2\\), which implies a low-temperature specific heat \(C(T) T\,2d/β\) and a heat-kernel decay \(Z(t) t-d/β\), defining a spectral dimension \(ds=2d/β\). This hyperuniformity-induced algebraic edge depletion could enable novel wave manipulation and low-temperature applications. Generalization to vector mechanical models and implications on material design are also discussed.

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