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Main Authors: Xu, Xiaofeng, Zhang, Lian, Shi, Yin, Chen, Long-Qing, Xu, Jinchao
Format: Preprint
Published: 2021
Subjects:
Online Access:https://arxiv.org/abs/2108.06769
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author Xu, Xiaofeng
Zhang, Lian
Shi, Yin
Chen, Long-Qing
Xu, Jinchao
author_facet Xu, Xiaofeng
Zhang, Lian
Shi, Yin
Chen, Long-Qing
Xu, Jinchao
contents Modeling the chemical, electric, and thermal transport as well as phase transitions and the accompanying mesoscale microstructure evolution within a material in an electronic device setting involves the solution of partial differential equations often with integral boundary conditions. Employing the familiar Poisson equation describing the electric potential evolution in a material exhibiting insulator-to-metal transitions, we exploit a special property of such an integral boundary condition, and we properly formulate the variational problem and establish its well-posedness. We then compare our method with the commonly-used Lagrange multiplier method that can also handle such boundary conditions. Numerical experiments demonstrate that our new method achieves an optimal convergence rate in contrast to the conventional Lagrange multiplier method. Furthermore, the linear system derived from our method is symmetric positive definite, and can be efficiently solved by Conjugate Gradient method with algebraic multigrid preconditioning.
format Preprint
id arxiv_https___arxiv_org_abs_2108_06769
institution arXiv
publishDate 2021
record_format arxiv
spellingShingle Integral boundary conditions in phase field models
Xu, Xiaofeng
Zhang, Lian
Shi, Yin
Chen, Long-Qing
Xu, Jinchao
Numerical Analysis
Modeling the chemical, electric, and thermal transport as well as phase transitions and the accompanying mesoscale microstructure evolution within a material in an electronic device setting involves the solution of partial differential equations often with integral boundary conditions. Employing the familiar Poisson equation describing the electric potential evolution in a material exhibiting insulator-to-metal transitions, we exploit a special property of such an integral boundary condition, and we properly formulate the variational problem and establish its well-posedness. We then compare our method with the commonly-used Lagrange multiplier method that can also handle such boundary conditions. Numerical experiments demonstrate that our new method achieves an optimal convergence rate in contrast to the conventional Lagrange multiplier method. Furthermore, the linear system derived from our method is symmetric positive definite, and can be efficiently solved by Conjugate Gradient method with algebraic multigrid preconditioning.
title Integral boundary conditions in phase field models
topic Numerical Analysis
url https://arxiv.org/abs/2108.06769