Elastic moduli fluctuations predict wave attenuation rates in glasses

Abstract

The disorder-induced attenuation of elastic waves is central to the universal low-temperature properties of glasses. Recent literature offers conflicting views on both the scaling of the wave attenuation rate (ω) in the low-frequency limit (ω\!\!0), and on its dependence on glass history and properties. A theoretical framework -- termed Fluctuating Elasticity Theory (FET) -- predicts low-frequency Rayleigh scattering scaling in d spatial dimensions, (ω)\!\!γ\,ωd+1, where γ\!=\!γ(V c) quantifies the coarse-grained spatial fluctuations of elastic moduli, involving a correlation volume V c that remains debated. Here, using extensive computer simulations, we show that (ω)\!\!γ\,ω3 is asymptotically satisfied in two dimensions (d\!=\!2) once γ is interpreted in terms of ensemble -- rather than spatial -- averages, where V c is replaced by the system size. In so doing, we also establish that the finite-size ensemble-statistics of elastic moduli is anomalous and related to the universal ω4 density of states of soft quasilocalized modes. These results not only strongly support FET, but also constitute a strict benchmark for the statistics produced by coarse-graining approaches to the spatial distribution of elastic moduli.