Microscopic origin of liquid viscosity from unstable localized modes
| Autor: | Huang, Long-Zhou, Cui, Bingyu, Vaibhav, Vinay, Baggioli, Matteo, Wang, Yun-Jiang |
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| Rok vydání: | 2024 |
| Předmět: | |
| Druh dokumentu: | Working Paper |
| Popis: | Viscosity is the resistance of a liquid to flow, governed by atomic-scale friction between its constituent atoms. While viscosity can be directly computed using the Green-Kubo formalism, this method does not fully elucidate the physical mechanisms underlying such momentum transport coefficient. In fact, the microscopic origin of liquid viscosity remains poorly understood. In this work, we calculate the viscosity of a $\mathrm{Cu_{50}Zr_{50}}$ metallic liquid and a Kob-Andersen model in a large range of temperatures and compare the results with a theoretical formula based on nonaffine linear response and instantaneous normal mode theory. This analysis reveals that only unstable localized instantaneous normal modes (ULINMs) contribute to viscosity, providing a microscopic definition of viscosity as diffusive momentum transport facilitated by local structural excitations mediated by ULINMs as precursors. Leveraging on the concept of configurational entropy, a quantitative model to connect viscosity with ULINMs is also proposed and validated in both the Arrhenius and non-Arrhenius regimes. In summary, our work provides a microscopic definition of liquid viscosity and highlights the fundamental role of ULINMs as its building blocks, ultimately opening the path to an atomic-scale prediction of viscosity in liquids and glasses. Comment: v1: comments welcome! |
| Databáze: | arXiv |
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