Actinide molten salts: A machine-learning potential molecular dynamics study

Manh Thuong Nguyen; Roger Rousseau; Patricia D. Paviet; Vassiliki Alexandra Glezakou

doi:10.1021/acsami.1c11358

Actinide molten salts: A machine-learning potential molecular dynamics study

Manh Thuong Nguyen, Roger Rousseau, Patricia D. Paviet, Vassiliki Alexandra Glezakou

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

Actinide molten salts represent a class of important materials in nuclear energy. Understanding them at a molecular level is critical for the proper and optimal design of relevant technological applications. Yet, owing to the complexity of electronic structure due to the 5f orbitals, computational studies of heavy elements in condensed phases using ab initio potentials to study the structure and dynamics of these elements embedded in molten salts are difficult. This lack of efficient computational protocols makes it difficult to obtain information on properties that require extensive statistical sampling like transport properties. To tackle this problem, we adopted a machine-learning approach to study ThCl4-NaCl and UCl3-NaCl binary systems. The machine-learning potential with the density functional theory accuracy allows us to obtain long molecular dynamics trajectories (ns) for large systems (103 atoms) at a considerably low computing cost, thereby efficiently gaining information about their bonding structures, thermodynamics, and dynamics at a range of temperatures. We observed a considerable change in the coordination environments of actinide elements and their characteristic coordination sphere lifetime. Our study also suggests that actinides in molten salts may not follow well-known entropy-scaling laws.

Original language	English
Pages (from-to)	53398-53408
Number of pages	11
Journal	ACS Applied Materials and Interfaces
Volume	13
Issue number	45
DOIs	https://doi.org/10.1021/acsami.1c11358
State	Published - Nov 17 2021
Externally published	Yes

Funding

M.-T.N., R.R., and P.D.P. gratefully acknowledge the support of the Laboratory Directed Research and Development (LDRD) Program for the Chemistry of Molten Salt Reactors (CheMSR) Agile Initiative (Award number 73757) at Pacific Northwest National Laboratory (PNNL), a multiprogram national laboratory operated by Battelle for the U.S. Department of Energy (DOE) under Contract No. DE-AC05-76RL01830. V.-A.G. acknowledges support by the U.S. DOE Office of Science, Office of Basic Energy Sciences, Chemical Sciences, Geosciences, and Biosciences Division (project 72353 Interfacial Structure and Dynamics in Ion Separations). This research used resources of the National Energy Research Scientific Computing Center, a DOE Office of Science User Facility supported by the Office of Science of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231. We also thank PNNL Research Computing for computer support.

Keywords

heavy elements
machine learning
molecular dynamics
molten salts
nuclear energy materials

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abstract = "Actinide molten salts represent a class of important materials in nuclear energy. Understanding them at a molecular level is critical for the proper and optimal design of relevant technological applications. Yet, owing to the complexity of electronic structure due to the 5f orbitals, computational studies of heavy elements in condensed phases using ab initio potentials to study the structure and dynamics of these elements embedded in molten salts are difficult. This lack of efficient computational protocols makes it difficult to obtain information on properties that require extensive statistical sampling like transport properties. To tackle this problem, we adopted a machine-learning approach to study ThCl4-NaCl and UCl3-NaCl binary systems. The machine-learning potential with the density functional theory accuracy allows us to obtain long molecular dynamics trajectories (ns) for large systems (103 atoms) at a considerably low computing cost, thereby efficiently gaining information about their bonding structures, thermodynamics, and dynamics at a range of temperatures. We observed a considerable change in the coordination environments of actinide elements and their characteristic coordination sphere lifetime. Our study also suggests that actinides in molten salts may not follow well-known entropy-scaling laws.",

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AB - Actinide molten salts represent a class of important materials in nuclear energy. Understanding them at a molecular level is critical for the proper and optimal design of relevant technological applications. Yet, owing to the complexity of electronic structure due to the 5f orbitals, computational studies of heavy elements in condensed phases using ab initio potentials to study the structure and dynamics of these elements embedded in molten salts are difficult. This lack of efficient computational protocols makes it difficult to obtain information on properties that require extensive statistical sampling like transport properties. To tackle this problem, we adopted a machine-learning approach to study ThCl4-NaCl and UCl3-NaCl binary systems. The machine-learning potential with the density functional theory accuracy allows us to obtain long molecular dynamics trajectories (ns) for large systems (103 atoms) at a considerably low computing cost, thereby efficiently gaining information about their bonding structures, thermodynamics, and dynamics at a range of temperatures. We observed a considerable change in the coordination environments of actinide elements and their characteristic coordination sphere lifetime. Our study also suggests that actinides in molten salts may not follow well-known entropy-scaling laws.

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Actinide molten salts: A machine-learning potential molecular dynamics study

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