Thermodynamic integration by neural network potentials based on first-principles dynamic calculations

被引:12
|
作者
Fukushima, Shogo [1 ]
Ushijima, Eisaku [1 ]
Kumazoe, Hiroyuki [1 ]
Koura, Akihide [1 ]
Shimojo, Fuyuki [1 ]
Shimamura, Kohei [2 ]
Misawa, Masaaki [3 ]
Kalia, Rajiv K. [4 ]
Nakano, Aiichiro [4 ]
Vashishta, Priya [4 ]
机构
[1] Kumamoto Univ, Dept Phys, Kumamoto 8608555, Japan
[2] Kobe Univ, Grad Sch Syst Informat, Kobe, Hyogo 6578501, Japan
[3] Kyushu Sangyo Univ, Fac Sci & Engn, Fukuoka, Fukuoka 8138503, Japan
[4] Univ Southern Calif, Collab Adv Comp & Simulat, Los Angeles, CA 90089 USA
来源
PHYSICAL REVIEW B | 2019年 / 100卷 / 21期
关键词
1ST-ORDER PHASE-TRANSITIONS; FREE-ENERGY CALCULATIONS; MOLECULAR-DYNAMICS; FEEDFORWARD NETWORKS; EQUILIBRIUM; SIMULATIONS; SURFACES; SOLIDS;
D O I
10.1103/PhysRevB.100.214108
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Simulation-size effect in evaluating the melting temperature of material is studied systematically by combining thermodynamic integration (TI) based on first-principles molecular-dynamics (FPMD) simulations and machine learning. Since the numerical integration to determine the free energies of two different phases as a function of temperature is very time consuming, the FPMD-based TI method has only been applied to small systems, i.e., less than 100 atoms. To accelerate the numerical integration, we here construct an interatomic potential based on the artificial neural-network (ANN) method, which retains the first-principles accuracy at a significantly lower computational cost. The free energies of the solid and liquid phases of rubidium are accurately obtained by the ANN potential, where its weight parameters are optimized to reproduce FPMD results. The ANN results reveal a significant size dependence up to 500 atoms.
引用
收藏
页数:8
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