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Classical nucleation theory predicts the shape of the nucleus in homogeneous solidification

Bingqing Cheng, Michele Ceriotti, Gareth A. Tribello

2020The Journal of Chemical Physics13 citationsDOIOpen Access PDF

Abstract

Macroscopic models of nucleation provide powerful tools for understanding activated phase transition processes. These models do not provide atomistic insights and can thus sometimes lack material-specific descriptions. Here, we provide a comprehensive framework for constructing a continuum picture from an atomistic simulation of homogeneous nucleation. We use this framework to determine the equilibrium shape of the solid nucleus that forms inside bulk liquid for a Lennard-Jones potential. From this shape, we then extract the anisotropy of the solid-liquid interfacial free energy, by performing a reverse Wulff construction in the space of spherical harmonic expansions. We find that the shape of the nucleus is nearly spherical and that its anisotropy can be perfectly described using classical models.

Topics & Concepts

AnisotropyNucleationClassical nucleation theoryHomogeneousNucleusPhase transitionStatistical physicsPhysicsSpace (punctuation)Classical mechanicsMaterials sciencePhase (matter)Spherical harmonicsHarmonicWork (physics)Condensed matter physicsThermalSurface (topology)Phase spaceFree spaceMicroscopic theorySolidification and crystal growth phenomenananoparticles nucleation surface interactionsMicrostructure and mechanical properties