基于有限元方法的Cahn-Hilliard方程能量不变二次化数值模拟

Numerical Simulation of Energy Invariant Quadratic Cahn-Hilliard Equation Based on Finite Element Method

下载PDF

导出

摘要文章分析了Cahn-Hilliard方程的能量不变二次化法的能量稳定性。首先分析了Cahn-Hilliard方程是满足能量耗散,即能量随时间的推移呈衰减趋势,并且这种随时间衰减的性质能得到保持。其次,对定义的自由能被积函数变换成新的二次函数,即能量不变二次化法同样验证了它的能量衰减性质,并给出了Cahn-Hilliard方程能量不变二次化法的能量稳定性。结果表明,该数值格式是无条件稳定,即能量稳定性与时间步长是无关的。最后我们基于有限元方法给出了一个数值算例,来有效的模拟Cahn-Hilliard方程相位变化情况。 The article analyzes the energy stability of the energy-invariant quadratic method of the Cahn-Hilliard equation. Firstly, it is analyzed that the Cahn-Hilliard equation is satisfying energy dissipation, i.e., the energy tends to decay with time, and this decaying property with time can be maintained. Secondly, the defined free energy quadratic function is transformed into a new quadratic function, i.e., the energy-invariant quadratic method is similarly verified for its energy-decaying property, and the energy stability of the energy-invariant quadratic method of the Cahn-Hilliard equation is given. The results show that the numerical format is unconditionally stable, i.e. the energy stability is independent of the time step. Finally we give a numerical example based on the finite element method to effectively simulate the phase variation of the Cahn-Hilliard equation.

作者闫军平何巧玲

机构地区石河子大学理学院

出处《应用数学进展》 2021年第6期1904-1910,共7页 Advances in Applied Mathematics

关键词有限元方法能量不变二次化法 CAHN-HILLIARD方程稳定性分析

分类号 G63 [文化科学—教育学]

引文网络
相关文献

参考文献3

1赵鑫,孙建强,何雪珺.Cahn-Hilliard方程的高阶保能量散逸性方法[J].计算数学,2015,37(2):137-147. 被引量：2
2姚廷富,李顺利.基于能量不变二次化法的Cahn-Hilliard方程的数值误差分析[J].华南师范大学学报（自然科学版）,2020,52(6):90-96. 被引量：1
3邹乐强,刘丽杰,韦雷雷.四阶Cahn-Hilliard方程的间断有限元方法[J].工程数学学报,2020,37(4):478-486. 被引量：1

二级参考文献14

1Furihata D. A stable and conservative finite difference scheme for the Cahn-Hilliard equation[J]. Numer. Math., 2001, 87: 675-699.
2Celledoni E, Grimm V, McLachlan R I, McLaren D I, ect Preserving energy resp. dissipation in numerical PDEs, using the average Vector Field method[J]. Comput. Phys., (2012, 231: 6770-6789.
3Bridges T J, Reich S. Numerical methods for Hamiltonian PDEs[J]. J. Phys. A: Math. Gem, 2006, 39: 5287-5320.
4McLachlan R I and Quispel N R W and Robidoux N. Geometric integration using discrete gradi- ents[J]. Phil. Trans. Roy. Soc. A, 1999, 357: 32-56.
5Furihata D, Matsuo T. Discrete variational derivative method, A structure-preserving numerical method for partial differential equations[C]. CRC Press, 2010.
6Quispel G R W and McLaren D I. A new class of energy-preserving numerical integration method[J]. Phys. A: Math. Theor., 2008, 41: 045206(7pp).
7Celledoni E, Mclaren D, McLachlan R I, Owren B, Quispel G R. Wright, Energy-Preserving Methods and B-Series, 21 Nordic Seminar on Computational Mechanics(NSCM-21), 2008.
8Celledoni E, McLachlan R I, Owren B and Quispel G R W. Energy-preserving integrators and the structure of B-series, NTNU Report 5: 2009.
9Chen Jingbo and Qin Mengzhao. multi-symplectic fourier pseudospectral method for the nonlinear schrSdinger equation[J]. Electronic Transactions on Numerical Analysis., 2001, 12: 193-204.
10Briges W L and Henson V E. The DFT:An Owner's Manual for the Discrete Fourier Transform[J]. SIAM, 1995.

共引文献1

1何雪珺,赵鑫,孙建强.高阶平均向量场方法在Allen-Cahn方程中的应用[J].重庆师范大学学报（自然科学版）,2016,33(1):86-91.

1许江波,费东阳,孙浩珲,崔易仑.节理千枚岩能量传递与动力学特性[J].东北大学学报（自然科学版）,2021,42(7):986-995. 被引量：8
2杨井荣,柳军.基于有序树的时空关联规则数据挖掘的应用[J].计算机技术与发展,2021,31(6):19-23. 被引量：6
3闵凡奇,吕桃林,解晶莹,高云智.LiNi_(x)Co_(y)Al_(z)O_(2)锂离子电池SOC估算及衰减特性[J].电池,2021,51(3):225-228. 被引量：1
4霍雨佳,杜发喜.复合材料机翼前缘抗鸟撞分析[J].成都大学学报（自然科学版）,2021,40(2):197-201. 被引量：3
5付云霞,管勇,王晓丹,王建收,尹政,周晓雪,王青,徐美君.大型河口三角洲地面沉降机制研究——以黄河三角洲为例[J].海岸工程,2021,40(2):83-95. 被引量：4
6赵伟国,李清华,亢艳东.离心泵叶片吸力面粗糙带抑制空化效果研究[J].农业机械学报,2021,52(6):169-176. 被引量：6
7李慧斌,陈华勇,Robin Neupane,阮合春,李霄.冰滑坡涌浪下冰碛坝溃决机理试验研究[J].水土保持通报,2021,41(2):25-34. 被引量：1
8黄先贵,平建华,禹言,朱亚强,张敏.基于氚同位素的安阳河中下游流域地下水更新能力研究[J].现代地质,2021,35(3):693-702. 被引量：5

应用数学进展

2021年第6期

浏览历史

内容加载中请稍等...

基于有限元方法的Cahn-Hilliard方程能量不变二次化数值模拟

参考文献3

二级参考文献14

共引文献1

相关作者

相关机构

相关主题

浏览历史