The Phase Field Method for Geometric Moving Interfaces and Their Numerical Approximations
It provides a comprehensive overview for researchers working on geometric moving interface problems, but is incremental as it surveys existing work without presenting new results.
This survey reviews recent numerical advances in the phase field method for geometric surface evolution, covering mathematical foundations, relationships to other formalisms, numerical analysis techniques, adaptive grid methods, and applications in materials science, fluid mechanics, biology, and image science.
This paper surveys recent numerical advances in the phase field method for geometric surface evolution and related geometric nonlinear partial differential equations (PDEs). Instead of describing technical details of various numerical methods and their analyses, the paper presents a holistic overview about the main ideas of phase field modeling, its mathematical foundation, and relationships between the phase field formalism and other mathematical formalisms for geometric moving interface problems, as well as the current state-of-the-art of numerical approximations of various phase field models with an emphasis on discussing the main ideas of numerical analysis techniques. The paper also reviews recent development on adaptive grid methods and various applications of the phase field modeling and their numerical methods in materials science, fluid mechanics, biology and image science.