Analysis of two discontinuous Galerkin finite element methods for the total pressure formulation of linear poroelasticity model

IF 2.2 2区数学 Q1 MATHEMATICS, APPLIED Applied Numerical Mathematics Pub Date : 2024-06-10 DOI:10.1016/j.apnum.2024.06.004

Linshuang He , Jun Guo , Minfu Feng

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Abstract

In this paper, we develop two discontinuous Galerkin (DG) finite element methods to solve the linear poroelasticity in the total pressure formulation, where displacement, fluid pressure, and total pressure are unknowns. The fully-discrete standard DG and conforming DG methods are presented based on the discontinuous approximations in space and the implicit Euler discretization in time. Compared to the standard DG method with penalty terms, the conforming DG method removes all stabilizers and maintains conforming finite element formulation by utilizing weak operators defined over discontinuous functions. The two methods provide locally conservative solutions and achieve locking-free properties in poroelasticity. We also derive the well-posedness and optimal a priori error estimates, which show that our methods satisfy parameter-robustness with respect to the infinitely large Lamé constant and the null-constrained specific storage coefficient. Several numerical experiments are performed to verify these theoretical results, even in heterogeneous porous media.

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线性孔弹性模型总压力公式的两种非连续伽勒金有限元方法分析

在本文中，我们开发了两种非连续伽勒金（DG）有限元方法，用于求解总压公式中的线性孔弹性，其中位移、流体压力和总压都是未知数。基于空间的非连续近似和时间的隐式欧拉离散，提出了完全离散的标准 DG 方法和符合 DG 方法。与带有惩罚项的标准 DG 方法相比，符合 DG 方法通过利用定义在不连续函数上的弱算子，去掉了所有稳定子，并保持了符合有限元的表述。这两种方法都能提供局部保守解，并在孔弹性中实现无锁定特性。我们还推导出好拟性和最佳先验误差估计，表明我们的方法在无限大拉梅常数和空约束比存储系数方面满足参数稳健性。为了验证这些理论结果，我们甚至在异质多孔介质中也进行了多次数值实验。

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来源期刊

Applied Numerical Mathematics 数学-应用数学

CiteScore

5.60

自引率

7.10%

发文量

225

审稿时长

7.2 months

期刊介绍： The purpose of the journal is to provide a forum for the publication of high quality research and tutorial papers in computational mathematics. In addition to the traditional issues and problems in numerical analysis, the journal also publishes papers describing relevant applications in such fields as physics, fluid dynamics, engineering and other branches of applied science with a computational mathematics component. The journal strives to be flexible in the type of papers it publishes and their format. Equally desirable are: (i) Full papers, which should be complete and relatively self-contained original contributions with an introduction that can be understood by the broad computational mathematics community. Both rigorous and heuristic styles are acceptable. Of particular interest are papers about new areas of research, in which other than strictly mathematical arguments may be important in establishing a basis for further developments. (ii) Tutorial review papers, covering some of the important issues in Numerical Mathematics, Scientific Computing and their Applications. The journal will occasionally publish contributions which are larger than the usual format for regular papers. (iii) Short notes, which present specific new results and techniques in a brief communication.

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