硼酚
石墨烯
多尺度建模
密度泛函理论
异质结
材料科学
热导率
原子间势
格子(音乐)
有限元法
纳米技术
统计物理学
计算机科学
分子动力学
计算化学
物理
热力学
化学
光电子学
复合材料
声学
作者
Bohayra Mortazavi,Evgeny V. Podryabinkin,Stephan Roche,Timon Rabczuk,Xiaoying Zhuang,Alexander V. Shapeev
出处
期刊:Materials horizons
[Royal Society of Chemistry]
日期:2020-01-01
卷期号:7 (9): 2359-2367
被引量:193
摘要
One of the ultimate goals of computational modeling in condensed matter is to be able to accurately compute materials properties with minimal empirical information. First-principles approaches such as the density functional theory (DFT) provide the best possible accuracy on electronic properties but they are limited to systems up to a few hundreds, or at most thousands of atoms. On the other hand, classical molecular dynamics (CMD) simulations and finite element method (FEM) are extensively employed to study larger and more realistic systems, but conversely depend on empirical information. Here, we show that machine-learning interatomic potentials (MLIPs) trained over short ab-initio molecular dynamics trajectories enable first-principles multiscale modeling, in which DFT simulations can be hierarchically bridged to efficiently simulate macroscopic structures. As a case study, we analyze the lattice thermal conductivity of coplanar graphene/borophene heterostructures, recently synthesized experimentally (Sci. Adv. 2019; 5: eaax6444), for which no viable classical modeling alternative is presently available. Our MLIP-based approach can efficiently predict the lattice thermal conductivity of graphene and borophene pristine phases, the thermal conductance of complex graphene/borophene interfaces and subsequently enable the study of effective thermal transport along the heterostructures at continuum level. This work highlights that MLIPs can be effectively and conveniently employed to enable first-principles multiscale modeling via hierarchical employment of DFT/CMD/FEM simulations, thus expanding the capability for computational design of novel nanostructures.
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