The paper focuses on developing efficient numerical schemes for the anisotropic Cahn-Hilliard (CH) model, which is an important phase-field model with applications in materials science, surface diffusion, and other areas.
The key contributions are:
Uniform-time-step WSBDF2 method: This method extends the previous BDF2 scheme by incorporating the concept of G-stability, allowing the authors to theoretically prove the energy stability of the uniform-time-step scheme.
Variable-time-step WSBDF2 method: The authors develop a new structure-preserving variable-time-step WSBDF2 method by combining the SAV approach with the variable-time-step technique. The energy stability of this scheme is also demonstrated using a different analytical approach.
Stabilization techniques: To mitigate the severe oscillations caused by the anisotropic term in the model, the authors incorporate two types of stabilization terms into both the uniform and variable-time-step schemes. Numerical experiments show that these stabilization terms maintain stability without affecting the accuracy and structure-preservation of the solutions.
Efficient implementation: The authors provide efficient implementation strategies for both the uniform and variable-time-step schemes, involving the solution of a few fourth-order equations per time step, making the methods highly efficient and easy to implement.
Overall, the paper presents novel numerical schemes for the anisotropic CH model that are theoretically proven to be energy-stable and mass-conservative, while also being computationally efficient.
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소스 콘텐츠 기반
arxiv.org
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