Litcius/Paper detail

PYSED: A tool for extracting kinetic-energy-weighted phonon dispersion and lifetime from molecular dynamics simulations

Ting Liang, Wenwu Jiang, Ke Xu, H. Bu, Zheyong Fan, Wengen Ouyang, Jianbin Xu

2025Journal of Applied Physics17 citationsDOIOpen Access PDF

Abstract

Machine learning potential-driven molecular dynamics (MD) simulations have significantly enhanced the predictive accuracy of thermal transport properties across diverse materials. However, extracting phonon-mode-resolved insights from these simulations remains a critical challenge. Here, we introduce pysed, a Python-based package built on the spectral energy density (SED) method, designed to efficiently compute kinetic-energy-weighted phonon dispersion and extract phonon lifetime from large-scale MD simulation trajectories. By integrating high-accuracy machine-learned neuroevolution potential (NEP) models, we validate and showcase the effectiveness of the implemented SED method across systems of varying dimensionalities. Specifically, the NEP-driven MD-SED accurately reveals how phonon modes are affected by strain in carbon nanotubes, as well as by interlayer coupling strengths and the twist angles in two-dimensional molybdenum disulfide. For three-dimensional systems, the SED method effectively establishes the thermal transport regime diagram for metal-organic frameworks, distinguishing between particlelike and wavelike propagation regions. Moreover, using bulk silicon as an example, we show that phonon SED can efficiently capture quantum dynamics based on path-integral trajectories. The pysed package bridges MD simulations with detailed phonon-mode insights, delivering a robust tool for investigating thermal transport properties with detailed mechanisms across various materials.

Topics & Concepts

PhononKinetic energyMolecular dynamicsDispersion (optics)Statistical physicsDynamics (music)PhysicsMaterials scienceCondensed matter physicsClassical mechanicsOpticsQuantum mechanicsAcousticsThermal properties of materialsMachine Learning in Materials ScienceAdvanced Thermoelectric Materials and Devices