A class of efficient high-order time-stepping methods for the anisotropic phase-field dendritic crystal growth model
DOI10.1016/j.cam.2024.116161zbMath1543.65173MaRDI QIDQ6591546
Publication date: 22 August 2024
Published in: Journal of Computational and Applied Mathematics (Search for Journal in Brave)
Runge-Kutta methodsauxiliary variablephase-fieldgradient flowsunconditional energy stabilitydendritic crystal growth
Stability and convergence of numerical methods for initial value and initial-boundary value problems involving PDEs (65M12) Multistep, Runge-Kutta and extrapolation methods for ordinary differential equations (65L06) Spectral, collocation and related methods for initial value and initial-boundary value problems involving PDEs (65M70) PDEs in connection with classical thermodynamics and heat transfer (35Q79)
Cites Work
- Unnamed Item
- Crystal growth of pure substances: phase-field simulations in comparison with analytical and experimental results
- Functional analysis, Sobolev spaces and partial differential equations
- An analysis of a phase field model of a free boundary
- Thermodynamically-consistent phase-field models for solidification
- Linear, first and second-order, unconditionally energy stable numerical schemes for the phase field model of homopolymer blends
- The scalar auxiliary variable (SAV) approach for gradient flows
- Modeling and numerical simulations of dendritic crystal growth
- Modeling melt convection in phase-field simulations of solidification
- Efficient linear, stabilized, second-order time marching schemes for an anisotropic phase field dendritic crystal growth model
- A novel decoupled and stable scheme for an anisotropic phase-field dendritic crystal growth model
- New efficient time-stepping schemes for the anisotropic phase-field dendritic crystal growth model
- Arbitrarily high order and fully discrete extrapolated RK-SAV/DG schemes for phase-field gradient flows
- Solving Ordinary Differential Equations I
- An Energy-Stable and Convergent Finite-Difference Scheme for the Phase Field Crystal Equation
- A stability property of implicit Runge-Kutta methods
- Stability Criteria for Implicit Runge–Kutta Methods
- Quantitative phase-field modeling of dendritic growth in two and three dimensions
- Energy-Decaying Extrapolated RK--SAV Methods for the Allen--Cahn and Cahn--Hilliard Equations
- A New Class of Efficient and Robust Energy Stable Schemes for Gradient Flows
- A ROBUST AND ACCURATE PHASE-FIELD SIMULATION OF SNOW CRYSTAL GROWTH
- Numerical approximations for a phase field dendritic crystal growth model based on the invariant energy quadratization approach
- Implicit Runge-Kutta Processes
- Integration Processes Based on Radau Quadrature Formulas
- A special stability problem for linear multistep methods
- A Stable Arbitrarily High Order Time-Stepping Method for Thermal Phase Change Problems
- On a novel full decoupling, linear, second-order accurate, and unconditionally energy stable numerical scheme for the anisotropic phase-field dendritic crystal growth model
This page was built for publication: A class of efficient high-order time-stepping methods for the anisotropic phase-field dendritic crystal growth model
