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Phase-field Modeling and Simulation of Solid-state Phase Transformations in Steels

Akinori Yamanaka

2023ISIJ International32 citationsDOIOpen Access PDF

Abstract

The phase-field method is used as a powerful and versatile computational method to simulate the microstructural evolution taking place during solid-state phase transformations in iron and steel. This review presents the basic theory of the phase-field method and reviews recent advances in the phase-field modeling and simulation of solid-state phase transformations in iron and steel, with particular attention being paid to the modeling of the austenite-to-ferrite, pearlitic, bainitic, and martensitic transformations. This review elucidates that the phase-field method is a promising computational approach to investigate the microstructural evolutions (e.g., interface migration, solute diffusion, and stress/strain evolutions) that take place during the phase transformations. It also indicates that further improvements are required to enhance the predictive accuracy of the phase-field models developed to date. Finally, this review discusses the critical challenges and perspectives for the further improvement of the phase-field modeling of solid-state phase transformations in steel, i.e., the modeling of heterogeneous nucleation, the abnormal effect of the diffusion interface, and material parameter identification.

Topics & Concepts

Phase (matter)Materials scienceNucleationMartensiteAusteniteField (mathematics)Phase field modelsFerrite (magnet)DiffusionMetallurgyMicrostructureThermodynamicsComposite materialChemistryMathematicsPhysicsPure mathematicsOrganic chemistryMicrostructure and Mechanical Properties of SteelsMetallurgy and Material FormingSolidification and crystal growth phenomena
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