A Structure-Preserving Semi-implicit IMEX Finite Volume Scheme for Ideal Magnetohydrodynamics at all Mach and Alfvén Numbers

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Walter Boscheri, Andrea Thomann
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Abstract

We present a divergence-free semi-implicit finite volume scheme for the simulation of the ideal magnetohydrodynamics (MHD) equations which is stable for large time steps controlled by the local transport speed at all Mach and Alfvén numbers. An operator splitting technique allows to treat the convective terms explicitly while the hydrodynamic pressure and the magnetic field contributions are integrated implicitly, yielding two decoupled linear implicit systems. The linearity of the implicit part is achieved by means of a semi-implicit time linearization. This structure is favorable as second-order accuracy in time can be achieved relying on the class of semi-implicit IMplicit–EXplicit Runge–Kutta (IMEX-RK) methods. In space, implicit cell-centered finite difference operators are designed to discretely preserve the divergence-free property of the magnetic field on three-dimensional Cartesian meshes. The new scheme is also particularly well suited for low Mach number flows and for the incompressible limit of the MHD equations, since no explicit numerical dissipation is added to the implicit contribution and the time step is scale independent. Likewise, highly magnetized flows can benefit from the implicit treatment of the magnetic fluxes, hence improving the computational efficiency of the novel method. The convective terms undergo a shock-capturing second order finite volume discretization to guarantee the effectiveness of the proposed method even for high Mach number flows. The new scheme is benchmarked against a series of test cases for the ideal MHD equations addressing different acoustic and Alfvén Mach number regimes where the performance and the stability of the new scheme is assessed.

Abstract Image

所有马赫数和阿尔弗文数下理想磁流体力学的保结构半隐式 IMEX 有限体积方案
我们提出了一种用于模拟理想磁流体动力学(MHD)方程的无发散半隐式有限体积方案,该方案在所有马赫数和阿尔弗文数条件下,在由局部传输速度控制的大时间步长内都是稳定的。通过算子拆分技术,可以显式处理对流项,同时对流体动力压力和磁场贡献进行隐式积分,从而产生两个解耦线性隐式系统。隐式部分的线性是通过半隐式时间线性化实现的。这种结构非常有利,因为依靠半隐式 IMplicit-EXplicit Runge-Kutta (IMEX-RK) 方法可以实现时间上的二阶精度。在空间,设计了以单元为中心的隐式有限差分算子,以便在三维笛卡尔网格上离散地保留磁场的无发散特性。新方案还特别适用于低马赫数流动和 MHD 方程的不可压缩极限,因为在隐式贡献中不添加显式数值耗散,而且时间步长与尺度无关。同样,高磁化流动也可以受益于对磁通量的隐式处理,从而提高新方法的计算效率。对流项进行了冲击捕获二阶有限体积离散化处理,以保证所提议的方法即使在高马赫数流动时也能有效。新方法以一系列针对不同声学和阿尔弗韦恩马赫数机制的理想 MHD 方程测试案例为基准,评估了新方法的性能和稳定性。
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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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