缩放比例
分子动力学
统计物理学
量子
石墨烯
电子
输运现象
多尺度建模
声子
电子传输链
电子结构
线性比例尺
材料科学
物理
计算机科学
纳米技术
凝聚态物理
化学
量子力学
计算化学
数学
几何学
地理
生物化学
大地测量学
作者
Zheyong Fan,Yang Xiao,Yanzhou Wang,Penghua Ying,Shunda Chen,Haikuan Dong
标识
DOI:10.1088/1361-648x/ad31c2
摘要
We propose an efficient approach for simultaneous prediction of thermal and electronic transport properties in complex materials. Firstly, a highly efficient machine-learned neuroevolution potential (NEP) is trained using reference data from quantum-mechanical density-functional theory calculations. This trained potential is then applied in large-scale molecular dynamics simulations, enabling the generation of realistic structures and accurate characterization of thermal transport properties. In addition, molecular dynamics simulations of atoms and linear-scaling quantum transport calculations of electrons are coupled to account for the electron-phonon scattering and other disorders that affect the charge carriers governing the electronic transport properties. We demonstrate the usefulness of this unified approach by studying electronic transport in pristine graphene and thermoelectric transport properties of a graphene antidot lattice, with a general-purpose NEP developed for carbon systems based on an extensive dataset.
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