Specific heat anomalies and local symmetry breaking in (anti-)fluorite materials: A machine learning molecular dynamics study

K Kobayashi and H Nakamura and M Okumura and M Itakura and M Machida, JOURNAL OF CHEMICAL PHYSICS, 162, 244508 (2025).

DOI: 10.1063/5.0262059

Understanding the high-temperature properties of materials with (anti-)fluorite structures is crucial for their application in nuclear reactors. In this study, we employ machine learning molecular dynamics (MLMD) simulations to investigate the high-temperature thermal properties of thorium dioxide, which has a fluorite structure, and lithium oxide, which has an anti-fluorite structure. Our results show that MLMD simulations effectively reproduce the reported thermal properties of these materials. A central focus of this work is the analysis of specific heat anomalies in these materials at high temperatures, commonly referred to as Bredig, pre-melting, or lambda- transitions. We demonstrate that a local order parameter, analogous to those used to describe liquid-liquid transitions in supercooled water and liquid silica, can effectively characterize these specific heat anomalies. The local order parameter identifies two distinct types of defective structures: lattice defect-like and liquid-like local structures. Above the transition temperature, liquid-like local structures predominate and the sub-lattice character of mobile atoms disappears.

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