Abstract
Glasses1,2 are amorphous solids, in the sense that they display elastic behaviour. In crystalline solids, elasticity is associated with phonons, which are quantized vibrational excitations. Phonon-like excitations also exist in glasses at very high (terahertz; 1012 Hz) frequencies; surprisingly, these persist in the supercooled liquids3. A universal feature of such amorphous systems is the boson peak: the vibrational density of states has an excess compared to the Debye squared-frequency law. Here we investigate the origin of this feature by studying the spectra of inherent structures4 (local minima of the potential energy) in a realistic glass model. We claim that the peak is the signature of a phase transition in the space of the stationary points of the energy, from a minima-dominated phase (with phonons) at low energy to a saddle-point-dominated phase5,6,7 (without phonons). The boson peak moves to lower frequencies on approaching the phonon–saddle transition, and its height diverges at the critical point. Our numerical results agree with the predictions of euclidean random matrix theory8 on the existence of a sharp phase transition9 between an amorphous elastic phase and a phonon-free one.
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Acknowledgements
We thank O. Pilla, G. Ruocco and G. Viliani for discussions. We are grateful to the RTN3 collaboration for CPU time in their cluster. V.M.M. was supported in part by the European Commission and the Spanish OCYT.
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Grigera, T., Martín-Mayor, V., Parisi, G. et al. Phonon interpretation of the ‘boson peak’ in supercooled liquids. Nature 422, 289–292 (2003). https://doi.org/10.1038/nature01475
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DOI: https://doi.org/10.1038/nature01475
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