Abstract
The (Li,Be)Fx fluoride salt is an ionic liquid with complex non-ideal thermodynamic behaviour due to the formation of short-range order. In this work, we explore the relationship between local structure, thermo-physical and thermodynamic properties in this system using a multidisciplinary approach that couples molecular dynamics simulations using the Polarizable Ion Model (PIM) and thermodynamic modelling assessment using the CALPHAD method. The density, thermal expansion, viscosity, thermal conductivity, molar and mixing enthalpies and heat capacity of the (Li,Be)Fx melt are extracted from the polarizable ionic interaction potentials and investigated across a wide range of compositions and temperatures. The agreement with the available experimental data is generally very good. The local structure is also examined in detail, in particular the transition between a molecular liquid with Li+, BeF42− and F− predominant species at low BeF2 content, and a polymeric liquid at high BeF2 content, with the formation of polymers (Be2F73−, Be3F104−, Be4F135−, etc.), and finally of a three-dimensional network of corner-sharing tetrahedrally coordinated Be2+ cations for pure BeF2. Based on the available experimental information and the output of the MD simulations, we moreover develop for the first time a coupled structural-thermodynamic model for the LiF-BeF2 system based on the quasi-chemical formalism in the quadruplet approximation, that provides a physical description of the melt and reproduces (in addition to the thermodynamic data) the chemical speciation of beryllium polymeric species predicted from the simulations.
Highlights
The LiF-BeF2 system has been widely investigated in the past due to its importance for the development of the Molten Salt Reactor technology and because of its interesting and peculiar structural properties from theoretical perspectives. 7LiF-BeF2 (FLIBE) was selected as fuel carrier for the Molten Salt Reactor Experiment (MSRE) in 1965–1969 [1] due to its favorable neutronic and thermophysical properties, and is nowadays still a primary choice for some Molten Salt Reactor (MSR) designs or as primary coolant in Advanced High Temperature Reactors (AHTRs) [1,2]
We explore this relationship and report a comprehensive model coupling structure, thermodynamic, and thermo-physical properties in the LiF-BeF2 system, illustrating the case of a polymeric liquid
Density and molar volume The density of the salt mixtures was calculated for each composition and temperature based on the mean volume of the cubic simulation cell after the 500 ps equilibration in the NPT ensemble at 0 GPa
Summary
The LiF-BeF2 system has been widely investigated in the past due to its importance for the development of the Molten Salt Reactor technology and because of its interesting and peculiar structural properties from theoretical perspectives. 7LiF-BeF2 (FLIBE) was selected as fuel carrier for the Molten Salt Reactor Experiment (MSRE) in 1965–1969 [1] due to its favorable neutronic and thermophysical properties, and is nowadays still a primary choice for some Molten Salt Reactor (MSR) designs or as primary coolant in Advanced High Temperature Reactors (AHTRs) [1,2]. It is one of the options for liquid blanket systems in fusion reactors [3]. We explore this relationship and report a comprehensive model coupling structure, thermodynamic, and thermo-physical properties in the LiF-BeF2 system, illustrating the case of a polymeric liquid
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