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Low-Frequency Excess Vibrational Modes in Two-Dimensional Glasses

Lijin Wang, Grzegorz Szamel, Elijah Flenner

2021Physical Review Letters32 citationsDOIOpen Access PDF

Abstract

Glasses possess more low-frequency vibrational modes than predicted by Debye theory. These excess modes are crucial for the understanding of the low temperature thermal and mechanical properties of glasses, which differ from those of crystalline solids. Recent simulational studies suggest that the density of the excess modes scales with their frequency ω as ω^{4} in two and higher dimensions. Here, we present extensive numerical studies of two-dimensional model glass formers over a large range of glass stabilities. We find that the density of the excess modes follows D_{exc}(ω)∼ω^{2} up to around the boson peak, regardless of the glass stability. The stability dependence of the overall scale of D_{exc}(ω) correlates with the stability dependence of low-frequency sound attenuation. However, we also find that, in small systems, where the first sound mode is pushed to higher frequencies, at frequencies below the first sound mode, there are excess modes with a system size independent density of states that scales as ω^{3}.

Topics & Concepts

Materials scienceThermalMolecular vibrationRange (aeronautics)DebyeCondensed matter physicsNormal modeStability (learning theory)Molecular physicsDebye modelMode (computer interface)Thermal stabilityPhysicsFrequency dependenceLow frequencyThermal fluctuationsLength scaleScale (ratio)BosonThermodynamicsAtmospheric temperature rangeNumber densitySound (geography)Material Dynamics and PropertiesThermal properties of materialsAdvanced Physical and Chemical Molecular Interactions
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