Wenshuo Liang scite author profile

Theoretical studies on the MgCl2–KCl eutectic heavily rely on ab initio calculations based on density functional theory (DFT). However, neither large-scale nor long-time calculations are feasible in the framework of the ab initio method, which makes it challenging to accurately predict some properties. To address this issue, a scheme based on ab initio calculation, deep neural networks, and machine learning is introduced. By training on high-quality data sets generated by ab initio calculations, a deep potential (DP) is constructed to describe the interaction between atoms. This work shows that the DP enables higher efficiency and similar accuracy relative to DFT. By performing molecular dynamics simulations with DP, the microstructure and thermophysical properties of the MgCl2–KCl eutectic (32:68 mol %) are investigated. The structural evolution with temperature is analyzed through partial radial distribution functions, coordination numbers, angular distribution functions, and structural factors. Meanwhile, the estimated thermophysical properties are discussed, including density, thermal expansion coefficient, shear viscosity, self-diffusion coefficient, and specific heat capacity. It reveals that the Mg2+ ions in this system have a distorted tetrahedral geometry rather than an octahedral one (with vacancies). The microstructure of the MgCl2–KCl eutectic shows the feature of medium-range order, and this feature will be enhanced at a higher temperature. All predicted thermophysical properties are in good agreement with the experimental results. The hydrodynamic radius determined from the shear viscosity and self-diffusion coefficient shows that the Mg2+ ions have a strong local structure and diffuse as if with an intact coordination shell. Overall, this work provides a thorough understanding of the microstructure and enriches the data of the thermophysical properties of the MgCl2–KCl eutectic.

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First-principles molecular dynamics simulations on the local structure and thermo-kinetic properties of molten magnesium chloride

Liang

et al. 2020

Journal of Molecular Liquids

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Theoretical prediction on the local structure and transport properties of molten alkali chlorides by deep potentials

Liang

2021

Journal of Materials Science & Technology

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Electrical properties and Raman scattering investigation of Ag doped ZnO thin films

Kong

Ruan

et al. 2012

Solid State Communications

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Molecular Dynamics Simulations of Molten Magnesium Chloride Using Machine‐Learning‐Based Deep Potential

Liang

2020

Advcd Theory and Sims

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In previous work, molten magnesium chloride has been investigated using first-principles molecular dynamics (FPMD) simulations based on density functional theory (DFT). However, such simulations are computationally intensive and therefore are restricted in terms of simulated size and time. In this work, a machine learning-based deep potential (DP) is trained to accelerate the molecular dynamics simulation of molten magnesium chloride. The trained DP can accurately describe the energies and forces with the prediction errors in energy and force being 1.76 × 10 −3 eV/atom and 4.76 × 10 −2 eV Å −1 , respectively. Applying the deep potential molecular dynamics (DPMD) approach, simulations can be performed with more than 1000 atoms, which is infeasible for FPMD simulations. Additionally, the partial radial distribution functions, angle distribution functions, densities, and self-diffusion coefficients predicted by DPMD simulations are also in reasonable agreement with FPMD or experimental results. This work shows that the DP enables higher efficiency and similar accuracy relative to DFT, exhibiting a bright application prospect in modeling molten salt systems.

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Wenshuo Liang

Machine-Learning-Driven Simulations on Microstructure and Thermophysical Properties of MgCl₂–KCl Eutectic

First-principles molecular dynamics simulations on the local structure and thermo-kinetic properties of molten magnesium chloride

Theoretical prediction on the local structure and transport properties of molten alkali chlorides by deep potentials

Electrical properties and Raman scattering investigation of Ag doped ZnO thin films

Molecular Dynamics Simulations of Molten Magnesium Chloride Using Machine‐Learning‐Based Deep Potential

Contact Info

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About

Wenshuo Liang

Machine-Learning-Driven Simulations on Microstructure and Thermophysical Properties of MgCl2–KCl Eutectic

First-principles molecular dynamics simulations on the local structure and thermo-kinetic properties of molten magnesium chloride

Theoretical prediction on the local structure and transport properties of molten alkali chlorides by deep potentials

Electrical properties and Raman scattering investigation of Ag doped ZnO thin films

Molecular Dynamics Simulations of Molten Magnesium Chloride Using Machine‐Learning‐Based Deep Potential

Contact Info

Product

Resources

About

Machine-Learning-Driven Simulations on Microstructure and Thermophysical Properties of MgCl₂–KCl Eutectic