Abstract
Combining atomistic simulations and machine learning techniques can expedite significantly the materials discovery process. We present an application of such methodological combination for the prediction of the melting transition and amorphous-solid behavior of the NaK alloy at the eutectic concentration. We show that efficient prediction of these properties is possible via machine learning methods trained on the topological local structural properties. The configurations resulting from Monte Carlo annealing of the NaK eutectic alloy are analyzed with topological attributes based on the Voronoi tessellation and using expectation-maximization clustering and Random Forest classification. We show that the Voronoi topological fingerprints make an accurate and fast prediction of the alloy thermal behavior by cataloguing the atomic configurations into three distinct phases: liquid, amorphous solid, and crystalline solid. Melting is found at 230 K by the sharp split of configurations classified as crystalline solid and as liquid. With the proposed metrics, an arrest-motion temperature is identified at 130–140 K through a top down clustering of the atomic configurations catalogued as amorphous solid. This statistical learning paradigm is not restricted to eutectic alloys or thermodynamics, extends the utility of topological attributes in a significant way, and harnesses the discovery of new material properties.
Highlights
The characterization of metallic amorphous solids is more complex than the identification of crystalline matter[1]
In this article we demonstrate that a topological inspection of the structure of the eutectic sodium-potassium (NaK) alloy using machine learning analyses predicts excellently the solidification fate of the liquid eutectic alloy leading to crystalline and amorphous solids
Our results demonstrate explicitly the power of machine learning in estimating thermodynamic behavior and simultaneously providing valuable guidance to machine learning of metal alloys condensed phases
Summary
Combining atomistic simulations and machine learning techniques can expedite significantly the materials discovery process. The configurations resulting from Monte Carlo annealing of the NaK eutectic alloy are analyzed with topological attributes based on the Voronoi tessellation and using expectation-maximization clustering and Random Forest classification. An arrest-motion temperature is identified at 130–140 K through a top down clustering of the atomic configurations catalogued as amorphous solid This statistical learning paradigm is not restricted to eutectic alloys or thermodynamics, extends the utility of topological attributes in a significant way, and harnesses the discovery of new material properties. In this article we demonstrate that a topological inspection of the structure of the eutectic sodium-potassium (NaK) alloy using machine learning analyses predicts excellently the solidification fate of the liquid eutectic alloy leading to crystalline and amorphous solids. This work is concluded in Conclusion with a discussion of the results
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