Abstract
In this paper, we aim to design two energy-stable and efficient finite element schemes for simulating the ferrofluid flows based on the well-known Shliomis model. The model is a highly nonlinear, coupled, multi-physics system, consisting of the Navier–Stokes equations, magnetostatic equation, and magnetization field equation. We propose two reliable numerical algorithms with the following desired features: linearity and unconditional energy stability. Several key techniques are used to achieve the required features, including the auxiliary variable method, consistent terms method, prediction-correction method, and semi-implicit stabilization method. The first scheme is based on a hybrid continuous/discontinuous finite elements spatial approximation, and the second utilizes decoupled continuous finite element spatial discretization. We have rigorously demonstrated that the proposed schemes are unconditionally energy stable and carried out extensive numerical simulations to illustrate the accuracy and stability of the developed schemes, as well as some interesting controllable characteristics of the ferrofluid flows.
Recommended Citation
G. D. Zhang et al., "Energy-Stable and Efficient Finite Element Schemes for the Shliomis Model of Ferrofluid Flows," Advances in Computational Mathematics, vol. 51, no. 4, article no. 36, Springer, Aug 2025.
The definitive version is available at https://doi.org/10.1007/s10444-025-10249-5
Department(s)
Mathematics and Statistics
Keywords and Phrases
Energy stability; Ferrofluid; Ferrohydrodynamcis; Finite element method; Magnetic field; Shliomis
International Standard Serial Number (ISSN)
1572-9044; 1019-7168
Document Type
Article - Journal
Document Version
Citation
File Type
text
Language(s)
English
Rights
© 2025 Springer, All rights reserved.
Publication Date
01 Aug 2025
Comments
Central South University, Grant 42274101