An energy-stable variable-step L1 scheme for time-fractional Navier-Stokes equations

被引:6
作者
Gao, Ruimin [1 ]
Li, Dongfang [1 ,2 ]
Li, Yaoda [1 ]
Yin, Yajun [3 ]
机构
[1] Huazhong Univ Sci & Technol, Sch Math & Stat, Wuhan 430074, Peoples R China
[2] Huazhong Univ Sci & Technol, Hubei Key Lab Engn Modeling & Sci Comp, Wuhan 430074, Peoples R China
[3] Huazhong Univ Sci & Technol, State Key Lab Mat Proc & Die & Mould Technol, Wuhan 430074, Peoples R China
来源
PHYSICA D-NONLINEAR PHENOMENA | 2024年 / 467卷
基金
中国国家自然科学基金;
关键词
Time-fractional Navier-Stokes equation; Variable-step L1 scheme; Energy stability; Adaptive time-stepping strategy; Error estimation; DIFFERENTIAL-EQUATIONS; GALERKIN APPROXIMATION; NUMERICAL-METHODS; FINITE-ELEMENT; REGULARITY; STABILITY; EXISTENCE;
D O I
10.1016/j.physd.2024.134264
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
We propose a structure-preserving scheme and its error analysis for time-fractional Navier-Stokes equations (TFNSEs) with periodic boundary conditions. The equations are first rewritten as an equivalent system by eliminating the pressure explicitly. Then, the spatial and temporal discretization are done by the Fourier spectral method and variable-step L1 scheme, respectively. It is proved that the fully-discrete scheme is energy-stable and divergence-free. The energy is an asymptotically compatible one since it recovers the classical energy when alpha -> 1 . Moreover, optimal error estimates are presented very technically by the obtained boundedness of the numerical solutions and some Sobolev inequalities. To our knowledge, they are the first results of the construction and analysis of structure-preserving schemes for TFNSEs. Several interesting numerical examples are given to confirm the theoretical results at last.
引用
收藏
页数:11
相关论文
共 57 条
[1]   A priori estimates for solutions of boundary value problems for fractional-order equations [J].
Alikhanov, A. A. .
DIFFERENTIAL EQUATIONS, 2010, 46 (05) :660-666
[2]   A new difference scheme for the time fractional diffusion equation [J].
Alikhanov, Anatoly A. .
JOURNAL OF COMPUTATIONAL PHYSICS, 2015, 280 :424-438
[3]  
[Anonymous], 2012, Finite element methods for Navier-Stokes equations: theory and algorithms
[4]  
BAKER GA, 1982, MATH COMPUT, V39, P339, DOI 10.1090/S0025-5718-1982-0669634-0
[5]   Numerical simulation methods and analysis for the dynamics of the time-fractional KdV equation [J].
Cao, Haiyan ;
Cheng, Xiujun ;
Zhang, Qifeng .
PHYSICA D-NONLINEAR PHENOMENA, 2024, 460
[6]  
Carvalho-Neto P. M., 2013, FRACTIONAL DIFFERENT
[7]   An accurate and efficient algorithm for the time-fractional molecular beam epitaxy model with slope selection [J].
Chen, Lizhen ;
Zhang, Jun ;
Zhao, Jia ;
Cao, Waixiang ;
Wang, Hong ;
Zhang, Jiwei .
COMPUTER PHYSICS COMMUNICATIONS, 2019, 245
[8]   FRACTIONAL NAVIER-STOKES EQUATIONS [J].
Cholewa, Jan W. ;
Dlotko, Tomasz .
DISCRETE AND CONTINUOUS DYNAMICAL SYSTEMS-SERIES B, 2018, 23 (08) :2967-2988
[9]   Conditions for the Absence of Blowing Up Solutions to Fractional Differential Equations [J].
de Carvalho-Neto, Paulo M. ;
Fehlberg Junior, Renato .
ACTA APPLICANDAE MATHEMATICAE, 2018, 154 (01) :15-29
[10]   Mild solutions to the time fractional Navier-Stokes equations in RN [J].
de Carvalho-Neto, Paulo Mendes ;
Planas, Gabriela .
JOURNAL OF DIFFERENTIAL EQUATIONS, 2015, 259 (07) :2948-2980
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