An unconditionally stable hybrid numerical method for solving the AllenCahn equation

Yibao Li; Hyun Geun Lee; Darae Jeong; Junseok Kim

doi:10.1016/j.camwa.2010.06.041

An unconditionally stable hybrid numerical method for solving the AllenCahn equation

Yibao Li, Hyun Geun Lee, Darae Jeong, Junseok Kim

Research output: Contribution to journal › Article › peer-review

126 Citations (Scopus)

Abstract

We present an unconditionally stable second-order hybrid numerical method for solving the AllenCahn equation representing a model for antiphase domain coarsening in a binary mixture. The proposed method is based on operator splitting techniques. The AllenCahn equation was divided into a linear and a nonlinear equation. First, the linear equation was discretized using a CrankNicolson scheme and the resulting discrete system of equations was solved by a fast solver such as a multigrid method. The nonlinear equation was then solved analytically due to the availability of a closed-form solution. Various numerical experiments are presented to confirm the accuracy, efficiency, and stability of the proposed method. In particular, we show that the scheme is unconditionally stable and second-order accurate in both time and space.

Original language	English
Pages (from-to)	1591-1606
Number of pages	16
Journal	Computers and Mathematics with Applications
Volume	60
Issue number	6
DOIs	https://doi.org/10.1016/j.camwa.2010.06.041
Publication status	Published - 2010

Keywords

AllenCahn equation
Finite difference
Motion by mean curvature
Operator splitting
Unconditionally stable

ASJC Scopus subject areas

Modelling and Simulation
Computational Theory and Mathematics
Computational Mathematics

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10.1016/j.camwa.2010.06.041

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title = "An unconditionally stable hybrid numerical method for solving the AllenCahn equation",

abstract = "We present an unconditionally stable second-order hybrid numerical method for solving the AllenCahn equation representing a model for antiphase domain coarsening in a binary mixture. The proposed method is based on operator splitting techniques. The AllenCahn equation was divided into a linear and a nonlinear equation. First, the linear equation was discretized using a CrankNicolson scheme and the resulting discrete system of equations was solved by a fast solver such as a multigrid method. The nonlinear equation was then solved analytically due to the availability of a closed-form solution. Various numerical experiments are presented to confirm the accuracy, efficiency, and stability of the proposed method. In particular, we show that the scheme is unconditionally stable and second-order accurate in both time and space.",

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T1 - An unconditionally stable hybrid numerical method for solving the AllenCahn equation

AU - Li, Yibao

AU - Lee, Hyun Geun

AU - Jeong, Darae

AU - Kim, Junseok

PY - 2010

Y1 - 2010

N2 - We present an unconditionally stable second-order hybrid numerical method for solving the AllenCahn equation representing a model for antiphase domain coarsening in a binary mixture. The proposed method is based on operator splitting techniques. The AllenCahn equation was divided into a linear and a nonlinear equation. First, the linear equation was discretized using a CrankNicolson scheme and the resulting discrete system of equations was solved by a fast solver such as a multigrid method. The nonlinear equation was then solved analytically due to the availability of a closed-form solution. Various numerical experiments are presented to confirm the accuracy, efficiency, and stability of the proposed method. In particular, we show that the scheme is unconditionally stable and second-order accurate in both time and space.

AB - We present an unconditionally stable second-order hybrid numerical method for solving the AllenCahn equation representing a model for antiphase domain coarsening in a binary mixture. The proposed method is based on operator splitting techniques. The AllenCahn equation was divided into a linear and a nonlinear equation. First, the linear equation was discretized using a CrankNicolson scheme and the resulting discrete system of equations was solved by a fast solver such as a multigrid method. The nonlinear equation was then solved analytically due to the availability of a closed-form solution. Various numerical experiments are presented to confirm the accuracy, efficiency, and stability of the proposed method. In particular, we show that the scheme is unconditionally stable and second-order accurate in both time and space.

KW - AllenCahn equation

KW - Finite difference

KW - Motion by mean curvature

KW - Operator splitting

KW - Unconditionally stable

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JO - Computers and Mathematics with Applications

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An unconditionally stable hybrid numerical method for solving the AllenCahn equation

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Keywords

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