Litcius/Paper detail

Multiphase-field modeling of spinodal decomposition during intercalation in an Allen-Cahn framework

Simon Daubner, P. G. Kubendran Amos, Ephraim Schoof, Jay Santoki, Daniel Schneider, Britta Nestler

2021Physical Review Materials22 citationsDOIOpen Access PDF

Abstract

Owing to its unique thermodynamical description, phase separation has largely been modeled in the Cahn-Hilliard framework. In the present work, as a computationally efficient alternative, a multicomponent, multiphase-field model operating in Allen-Cahn framework is presented and subsequently employed to simulate spinodal decomposition. Stability analysis shows that the formulation can cover the effect of phase separation while simplifying the extension to multiple phases and incorporation of additional driving forces. Computational efficiency of the proposed approach is compared with the conventional technique by modeling intercalation in a representative one-dimensional domain. Moreover, intercalation within a multigrain system involving multiparticle interaction is studied. Our results suggest initiation of phase transformation at higher order junctions as well as a grain-by-grain intercalation behavior in a two-phase cathode material such as the well-studied ${\text{LiFePO}}_{4}$.

Topics & Concepts

Spinodal decompositionIntercalation (chemistry)Materials scienceSpinodalStability (learning theory)Phase (matter)Cahn–Hilliard equationField (mathematics)ThermodynamicsDecompositionPhase field modelsStatistical physicsChemical physicsComputer sciencePhysicsMathematicsChemistryPartial differential equationPure mathematicsOrganic chemistryQuantum mechanicsMachine learningSolidification and crystal growth phenomenaAluminum Alloy Microstructure PropertiesMagnetic properties of thin films