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Finite-temperature interplay of structural stability, chemical complexity, and elastic properties of bcc multicomponent alloys from <i>ab initio</i> trained machine-learning potentials

Konstantin Gubaev, Yuji Ikeda, Ferenc Tasnádi, Jörg Neugebauer, Alexander V. Shapeev, Blazej Grabowski, Fritz Körmann

2021Physical Review Materials23 citationsDOIOpen Access PDF

Abstract

High-throughput finite-temperature phase stability and materials property predictions directly from first-principles are extremely resource demanding. Here, the authors combine density functional theory calculations with accurate machine-learning potentials and an active learning scheme to obtain fast, yet highly accurate interatomic potentials. The approach is used to analyze the bcc-$\ensuremath{\omega}$ phase stability and elastic properties of a series of bcc TiZrHfTa${}_{x}$ alloys. The phase stability is evaluated by analyzing the projections of atomic displacements from molecular dynamics trajectories revealing fingerprints of bcc-$\ensuremath{\omega}$ martensitic transformations.

Topics & Concepts

Materials scienceStability (learning theory)Interatomic potentialStructural stabilityAb initioPhase (matter)Molecular dynamicsDensity functional theoryMartensiteOmegaThermodynamicsProperty (philosophy)Ab initio quantum chemistry methodsStatistical physicsCondensed matter physicsChemical physicsComputational chemistryMachine learningComputer sciencePhysicsMicrostructureMoleculeQuantum mechanicsMetallurgyStructural engineeringChemistryPhilosophyEpistemologyEngineeringMachine Learning in Materials ScienceTitanium Alloys Microstructure and PropertiesNuclear Materials and Properties
Finite-temperature interplay of structural stability, chemical complexity, and elastic properties of bcc multicomponent alloys from <i>ab initio</i> trained machine-learning potentials | Litcius