English

Enumerating low-frequency nonphononic vibrations in computer glasses

Soft Condensed Matter 2024-09-02 v2 Disordered Systems and Neural Networks

Abstract

In addition to Goldstone phonons that generically emerge in the low-frequency vibrational spectrum of any solid, crystalline or glassy, structural glasses also feature other low-frequency vibrational modes. The nature and statistical properties of these modes -- often termed `excess modes' -- have been the subject of decades-long investigation. Studying them, even using well-controlled computer glasses, has proven challenging due to strong spatial hybridization effects between phononic and nonphononic excitations, which hinder quantitative analyses of the nonphononic contribution DG(ω){\cal D}_{\rm G}(\omega) to the total spectrum D(ω){\cal D}(\omega), per frequency ω\omega. Here, using recent advances indicating that DG(ω) ⁣= ⁣D(ω)DD(ω){\cal D}_{\rm G}(\omega)\!=\!{\cal D}(\omega)-{\cal D}_{\rm D}(\omega), where DD(ω){\cal D}_{\rm D}(\omega) is Debye's spectrum of phonons, we present a simple and straightforward scheme to enumerate nonphononic modes in computer glasses. Our analysis establishes that nonphononic modes in computer glasses indeed make an additive contribution to the total spectrum, including in the presence of strong hybridizations. Moreover, it cleanly reveals the universal DG(ω) ⁣ ⁣ω4{\cal D}_{\rm G}(\omega)\!\sim\!\omega^4 tail of the nonphononic spectrum, and opens the way for related analyses of experimental spectra of glasses.

Keywords

Cite

@article{arxiv.2404.12735,
  title  = {Enumerating low-frequency nonphononic vibrations in computer glasses},
  author = {Edan Lerner and Avraham Moriel and Eran Bouchbinder},
  journal= {arXiv preprint arXiv:2404.12735},
  year   = {2024}
}

Comments

7 pages, 5 figures. V2: a reference added to a closely related analysis of experimental data, see arXiv:2404.16996

R2 v1 2026-06-28T15:59:35.669Z