Abstract
The present study attempts to find an alternate computational tool to model the complex physical interactions within the molten salt FLiNaK in a way that is both efficient and accurate. Additionally, this study seeks to describe the effects of several different types of impurities on the FLiNaK salt system. This study selects two different polarizable force fields, the AMOEBA polarizable approach and the polarizable ion model, to determine the density and the structure of the impure FLiNaK salt mixtures at typical operating temperatures in molten salt reactors (between 500-900 °C). This study conducts ab initio molecular dynamics (AIMD) simulations and classical molecular dynamics (CMD) for these salt mixtures to determine the correct parameter set for these two force fields. This study also uses an optimizer to minimize the difference between the forces calculated with AIMD and CMD simulation data. The AMOEBA polarizable approach is able to predict density for FLiNaK; however, it is unable to reliably predict other thermophysical properties due to the instability of its CMD simulations. The polarizable ion model is able to reliably determine density and salt structure for pure and impure FLiNaK mixtures. This model can be further used to determine other thermophysical properties. The polarizable ion model predicted densities for four impure salt mixtures: FLiNaK-MoF3, FLiNaK-UF3, FLiNaK-CsF, and FLiNaK-ZrF4. The predicted densities at 700 °C given in kg/m3 are 1929.94, 2454.15, 1650.67, and 1961.87, respectively with an error compared to the additive density model of -2.51%, -5.79%, -17.15%, and -1.67%, respectively. This study presents the radial distribution function and density correlation functions for each salt mixture. This study also presents a discussion of the shortcomings of the AMOEBA polarizable approach, as well as further work that may be done with these tools.
Degree
MS
College and Department
Ira A. Fulton College of Engineering; Chemical Engineering
Rights
https://lib.byu.edu/about/copyright/
BYU ScholarsArchive Citation
Thurgood, Jared, "A Polarizable Molecular Dynamics Potential for Molten Salt Property Prediction" (2023). Theses and Dissertations. 10094.
https://scholarsarchive.byu.edu/etd/10094
Date Submitted
2023-08-14
Document Type
Thesis
Handle
http://hdl.lib.byu.edu/1877/etd12932
Keywords
molecular dynamics, molten salt, FLiNaK, AMOEBA, polarizable ion model, polarization, impurities, density, RDF
Language
english