scientific article; zbMATH DE number 7479362
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Publication:5035925
zbMath1499.65504MaRDI QIDQ5035925
Ting Li, Pengzhan Huang, Yin-Nian He
Publication date: 22 February 2022
Full work available at URL: https://www.global-sci.org/intro/article_detail/ijnam/19951.html
Title: zbMATH Open Web Interface contents unavailable due to conflicting licenses.
PDEs in connection with fluid mechanics (35Q35) Liquid crystals (76A15) Finite element, Rayleigh-Ritz and Galerkin methods for initial value and initial-boundary value problems involving PDEs (65M60) Error bounds for initial value and initial-boundary value problems involving PDEs (65M15)
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Cites Work
- A splitting in time scheme and augmented Lagrangian method for a nematic liquid crystal problem
- Optimal error estimates of semi-implicit Galerkin method for time-dependent nematic liquid crystal flows
- Multirate iterative scheme based on multiphysics discontinuous Galerkin method for a poroelasticity model
- A decoupled finite element method with diferent time steps for the nonstationary Darcy-Brinkman problem
- An overview on numerical analyses of nematic liquid crystal flows
- Stabilized finite element method for the stationary Navier-Stokes equations
- A Decoupling Method with Different Subdomain Time Steps for the Non-Stationary Navier-Stokes ⁄ Darcy Model
- Mixed formulation, approximation and decoupling algorithm for a penalized nematic liquid crystals model
- A Posteriori Error Estimates of Stabilization of Low-Order Mixed Finite Elements for Incompressible Flow
- Finite Element Approximations of the Ericksen–Leslie Model for Nematic Liquid Crystal Flow
- Nonlinear theory of defects in nematic liquid crystals; Phase transition and flow phenomena
- Fourier Spectral Approximation to a Dissipative System Modeling the Flow of Liquid Crystals
- A fast numerical method for solving coupled Burgers' equations
- A decoupling method with different subdomain time steps for the nonstationary stokes–darcy model
- A Finite Element Algorithm for Nematic Liquid Crystal Flow Based on the Gauge-Uzawa Method
- Linearized FE Approximations to a Nonlinear Gradient Flow
- A Time-Splitting Finite-Element Stable Approximation for the Ericksen--Leslie Equations
- Numerical Simulations of Hydrodynamics of Nematic Liquid Crystals: Effects of Kinematic Transports
- New Splitting Methods for Convection-Dominated Diffusion Problems and Navier-Stokes Equations
- A linear mixed finite element scheme for a nematic Ericksen–Leslie liquid crystal model
- Stabilization of Low-order Mixed Finite Elements for the Stokes Equations
- The Gauge--Uzawa Finite Element Method. Part I: The Navier--Stokes Equations
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