Unconditionally Maximum Bound Principle Preserving Linear Schemes for the Conservative Allen-Cahn Equation with Nonlocal Constraint

被引：57

作者：

Li, Jingwei ^{[1
,2
]}

Ju, Lili ^{[3
]}

Cai, Yongyong ^{[1
,2
]}

Feng, Xinlong ^{[4
]}

机构：

[1] Beijing Normal Univ, Lab Math & Complex Syst, Beijing 100875, Peoples R China

[2] Beijing Normal Univ, Sch Math Sci, Beijing 100875, Peoples R China

[3] Univ South Carolina, Dept Math, Columbia, SC 29208 USA

[4] Xinjiang Univ, Coll Math & Syst Sci, Urumqi 830046, Peoples R China

来源：

JOURNAL OF SCIENTIFIC COMPUTING | 2021年 / 87卷 / 03期

基金：

中国国家自然科学基金; 美国国家科学基金会;

关键词：

Modified Allen-Cahn equation; Maximum bound principle; Mass conservation; Exponential time differencing; Stabilizing technique; 35B50; 65M12; 35K55; 65R20; TIME DIFFERENCING SCHEMES; HILLIARD EQUATION; NUMERICAL APPROXIMATIONS; ENERGY; ALGORITHMS; EFFICIENT; ORDER;

D O I：

10.1007/s10915-021-01512-0

中图分类号：

O29 [应用数学];

学科分类号：

070104 ;

摘要：

In comparison with the Cahn-Hilliard equation, the classic Allen-Cahn equation satisfies the maximum bound principle (MBP) but fails to conserve the mass along the time. In this paper, we consider the MBP and corresponding numerical schemes for the modified Allen-Cahn equation, which is formed by introducing a nonlocal Lagrange multiplier term to enforce the mass conservation. We first study sufficient conditions on the nonlinear potentials under which the MBP holds and provide some concrete examples of nonlinear functions. Then we propose first and second order stabilized exponential time differencing schemes for time integration, which are linear schemes and unconditionally preserve the MBP in the time discrete level. Convergence of these schemes is analyzed as well as their energy stability. Various two and three dimensional numerical experiments are also carried out to validate the theoretical results and demonstrate the performance of the proposed schemes.

引用

页数：32

共 49 条

[1] MICROSCOPIC THEORY FOR ANTIPHASE BOUNDARY MOTION AND ITS APPLICATION TO ANTIPHASE DOMAIN COARSENING
ALLEN, SM
CAHN, JW
[J]. ACTA METALLURGICA, 1979, 27 (06): : 1085 - 1095
[2] A new class of time discretization schemes for the solution of nonlinear PDEs
Beylkin, G
Keiser, JM
Vozovoi, L
[J]. JOURNAL OF COMPUTATIONAL PHYSICS, 1998, 147 (02) : 362 - 387
[3] FREE ENERGY OF A NONUNIFORM SYSTEM .1. INTERFACIAL FREE ENERGY
CAHN, JW
HILLIARD, JE
[J]. JOURNAL OF CHEMICAL PHYSICS, 1958, 28 (02) : 258 - 267
[4] Chen W., 2019, J. Comput. Phys. X, V3
[5] Mass conserving Allen-Cahn equation and volume preserving mean curvature flow
Chen, Xinfu
Hilhorst, D.
Logak, E.
[J]. INTERFACES AND FREE BOUNDARIES, 2010, 12 (04) : 527 - 549
[6] NUMERICAL-ANALYSIS OF THE CAHN-HILLIARD EQUATION WITH A LOGARITHMIC FREE-ENERGY
COPETTI, MIM
ELLIOTT, CM
[J]. NUMERISCHE MATHEMATIK, 1992, 63 (01) : 39 - 65
[7] Exponential time differencing for stiff systems
Cox, SM
Matthews, PC
[J]. JOURNAL OF COMPUTATIONAL PHYSICS, 2002, 176 (02) : 430 - 455
[8] ON THE CAHN-HILLIARD EQUATION WITH A LOGARITHMIC FREE-ENERGY
DEBUSSCHE, A
DETTORI, L
[J]. NONLINEAR ANALYSIS-THEORY METHODS & APPLICATIONS, 1995, 24 (10) : 1491 - 1514
[9] Dong LX, 2019, COMMUN MATH SCI, V17, P921
[10] Du Q., 2019, CBMS-NSF Regional Conference Series in Applied Mathematics

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