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Main Authors: Cui, Bingyu, Wang, Yuqi
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.09962
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author Cui, Bingyu
Wang, Yuqi
author_facet Cui, Bingyu
Wang, Yuqi
contents We derive analytically, and validate numerically, the dispersion renormalization and attenuation of acoustic waves propagating through quenched disordered media in the long-wavelength limit. We consider weak spatial fluctuations in elastic moduli and/or mass density and compute the disorder-induced self-energies within the leading (Born) approximation. For sufficiently weak disorder, the results depend only on the variances of the fluctuations and are therefore insensitive to the detailed form of the underlying random distribution. For spatially uncorrelated elasticity disorder we obtain Rayleigh-type attenuation, $Γ(q)\propto q^{d+1}$ , together with a reduction of the sound speed. In contrast, density disorder produces Rayleigh-type attenuation but does not renormalize the acoustic dispersion to leading order. Molecular dynamics simulations and normal-mode analyses of disordered one- and two-dimensional lattices quantitatively confirm the theoretical predictions.
format Preprint
id arxiv_https___arxiv_org_abs_2605_09962
institution arXiv
publishDate 2026
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spellingShingle Attenuation of long-wavelength sound in quenched disordered media
Cui, Bingyu
Wang, Yuqi
Disordered Systems and Neural Networks
We derive analytically, and validate numerically, the dispersion renormalization and attenuation of acoustic waves propagating through quenched disordered media in the long-wavelength limit. We consider weak spatial fluctuations in elastic moduli and/or mass density and compute the disorder-induced self-energies within the leading (Born) approximation. For sufficiently weak disorder, the results depend only on the variances of the fluctuations and are therefore insensitive to the detailed form of the underlying random distribution. For spatially uncorrelated elasticity disorder we obtain Rayleigh-type attenuation, $Γ(q)\propto q^{d+1}$ , together with a reduction of the sound speed. In contrast, density disorder produces Rayleigh-type attenuation but does not renormalize the acoustic dispersion to leading order. Molecular dynamics simulations and normal-mode analyses of disordered one- and two-dimensional lattices quantitatively confirm the theoretical predictions.
title Attenuation of long-wavelength sound in quenched disordered media
topic Disordered Systems and Neural Networks
url https://arxiv.org/abs/2605.09962