Journal ArticleDOI
An introduction to phase-field modeling of microstructure evolution
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In this article, the authors introduce the concept of diffuse interfaces, the phase-field variables, the thermodynamic driving force for microstructure evolution and the kinetic phasefield equations are discussed.Abstract:
The phase-field method has become an important and extremely versatile technique for simulating microstructure evolution at the mesoscale. Thanks to the diffuse-interface approach, it allows us to study the evolution of arbitrary complex grain morphologies without any presumption on their shape or mutual distribution. It is also straightforward to account for different thermodynamic driving forces for microstructure evolution, such as bulk and interfacial energy, elastic energy and electric or magnetic energy, and the effect of different transport processes, such as mass diffusion, heat conduction and convection. The purpose of the paper is to give an introduction to the phase-field modeling technique. The concept of diffuse interfaces, the phase-field variables, the thermodynamic driving force for microstructure evolution and the kinetic phase-field equations are introduced. Furthermore, common techniques for parameter determination and numerical solution of the equations are discussed. To show the variety in phase-field models, different model formulations are exploited, depending on which is most common or most illustrative.read more
Citations
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Journal ArticleDOI
An enhanced finite element technique for diffuse phase transition
Ingo Münch,M. Krauβ +1 more
TL;DR: A finite element technique to enhance phase-field simulations by enhanced field interpolation with higher polynomial functions on demand that preserves continuity of finite elements and is particularly advantageous in the context of parallelized computing.
Journal ArticleDOI
Thermodynamic principles for phase-field modeling of alloy solidification
TL;DR: In this paper, the thermodynamic principles for and the recent progress in the phase-field modeling of isothermal solidification of binary alloys are reviewed and the importance to solve directly the additional constraints in the modeling system self-consistently in thermodynamics is highlighted.
Book
Phase-field modeling of multi-domain evolution in ferromagnetic shape memory alloys and of polycrystalline thin film growth
TL;DR: In this article, a multi-phase field model is adopted to run numerical simulations in two different areas of scientific interest: polycrystalline thin films growth and the ferromagnetic shape memory effect.
Journal ArticleDOI
Phase-field study the effects of elastic strain energy on the occupation probability of Cr atom in Ni–Al–Cr alloy
TL;DR: In this paper, the occupation probability (OP) of Cr atom at α sublattices of Ni-Al-Cr alloy was studied by using phase-field microelasticity model.
Journal ArticleDOI
Evolution of Secondary Phases Formed upon Solidification of a Ni-Based Alloy
TL;DR: In this paper, the solidification of UNS N08028 alloy subjected to different cooling rates was studied, where primary austenite dendrites occur predominantly and different amounts of sigma phase form in the interdendritic regions.
References
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Journal ArticleDOI
Free Energy of a Nonuniform System. I. Interfacial Free Energy
John W. Cahn,John E. Hilliard +1 more
TL;DR: In this article, it was shown that the thickness of the interface increases with increasing temperature and becomes infinite at the critical temperature Tc, and that at a temperature T just below Tc the interfacial free energy σ is proportional to (T c −T) 3 2.
Journal ArticleDOI
Theory of Dynamic Critical Phenomena
TL;DR: The renormalization group theory has been applied to a variety of dynamic critical phenomena, such as the phase separation of a symmetric binary fluid as mentioned in this paper, and it has been shown that it can explain available experimental data at the critical point of pure fluids, and binary mixtures, and at many magnetic phase transitions.
Journal ArticleDOI
A microscopic theory for antiphase boundary motion and its application to antiphase domain coarsening
Samuel M. Allen,John W. Cahn +1 more
A microscopic theory for antiphase boundary motion and its application to antiphase domain coasening
TL;DR: In this paper, a microscopic diffusional theory for the motion of a curved antiphase boundary is presented, where the interfacial velocity is linearly proportional to the mean curvature of the boundary, but unlike earlier theories the constant of proportionality does not include the specific surface free energy.