Litcius/Paper detail

Size-Dependent Nucleation in Crystal Phase Transition from Machine Learning Metadynamics

Pedro Antonio Santos-Flórez, Howard Yanxon, Byungkyun Kang, Yansun Yao, Qiang Zhu

2022Physical Review Letters25 citationsDOIOpen Access PDF

Abstract

In this Letter, we present a framework that combines machine learning potential (MLP) and metadynamics to investigate solid-solid phase transition. Based on the spectral descriptors and neural networks regression, we develop a scalable MLP model to warrant an accurate interpolation of the energy surface where two phases coexist. Applying it to the simulation of B4-B1 phase transition of GaN under 50 GPa with different model sizes, we observe sequential change of the phase transition mechanism from collective modes to nucleation and growths. When the size is at or below 128 000 atoms, the nucleation and growth appear to follow a preferred direction. At larger sizes, the nuclei occur at multiple sites simultaneously and grow to microstructures by passing the critical size. The observed change of the atomistic mechanism manifests the importance of statistical sampling with large system size in phase transition modeling.

Topics & Concepts

NucleationMetadynamicsPhase transitionMaterials scienceStatistical physicsChemical physicsCrystal (programming language)Phase (matter)Interpolation (computer graphics)Condensed matter physicsComputer sciencePhysicsMolecular dynamicsArtificial intelligenceThermodynamicsChemistryComputational chemistryQuantum mechanicsProgramming languageMotion (physics)Machine Learning in Materials ScienceAdvanced Electron Microscopy Techniques and ApplicationsMicrostructure and mechanical properties