High Order Asymptotic Preserving and Classical Semi-implicit RK Schemes for the Euler–Poisson System in the Quasineutral Limit

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-06-06 DOI:10.1007/s10915-024-02577-3
K. R. Arun, N. Crouseilles, S. Samantaray
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Abstract

In this paper, the design and analysis of high order accurate IMEX finite volume schemes for the compressible Euler–Poisson (EP) equations in the quasineutral limit is presented. As the quasineutral limit is singular for the governing equations, the time discretisation is tantamount to achieving an accurate numerical method. To this end, the EP system is viewed as a differential algebraic equation system (DAEs) via static condensation. As a consequence of this vantage point, high order linearly semi-implicit (SI) time discretisation are realised by employing a novel combination of the direct approach used for implicit discretisation of DAEs and, two different classes of IMEX-RK schemes: the additive and the multiplicative. For both the time discretisation strategies, in order to account for rapid plasma oscillations in quasineutral regimes, the nonlinear Euler fluxes are split into two different combinations of stiff and non-stiff components. The high order scheme resulting from the additive approach is designated as a classical scheme while the one generated by the multiplicative approach possesses the asymptotic preserving (AP) property. Time discretisations for the classical and the AP schemes are performed by standard IMEX-RK and SI-IMEX-RK methods, respectively so that the stiff terms are treated implicitly and the non-stiff ones explicitly. In order to discretise in space a Rusanov-type central flux is used for the non-stiff part, and simple central differencing for the stiff part. Results of numerical experiments are presented, which confirm that the high order schemes based on the SI-IMEX-RK time discretisation achieve uniform second order convergence with respect to the Debye length and are AP in the quasineutral limit.

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准中性极限中欧拉-泊松系统的高阶渐近保留和经典半隐式 RK 方案
本文介绍了准中性极限下可压缩欧拉-泊松(EP)方程的高阶精确 IMEX 有限体积方案的设计与分析。由于准中性极限的控制方程是奇异的,因此时间离散化相当于实现精确的数值方法。为此,我们通过静态凝聚将 EP 系统视为微分代数方程系统 (DAE)。基于这一有利条件,我们采用了一种新颖的方法,将用于 DAEs 隐式离散化的直接方法与两类不同的 IMEX-RK 方案(加法方案和乘法方案)相结合,实现了高阶线性半隐式 (SI) 时间离散化。在这两种时间离散化策略中,为了考虑到等离子体在准中性状态下的快速振荡,非线性欧拉通量被分成两种不同的刚性和非刚性成分组合。由加法产生的高阶方案被称为经典方案,而由乘法产生的方案则具有渐近保留(AP)特性。经典方案和 AP 方案分别采用标准 IMEX-RK 方法和 SI-IMEX-RK 方法进行时间离散处理,从而使刚性项得到隐式处理,非刚性项得到显式处理。为了进行空间离散,对非刚性部分采用了 Rusanov 型中心通量,对刚性部分采用了简单的中心差分。数值实验结果表明,基于 SI-IMEX-RK 时间离散化的高阶方案在德拜长度方面实现了统一的二阶收敛,并且在准中性极限中是 AP。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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