A splitting method for numerical relativistic magnetohydrodynamics

Serguei Komissarov, David Phillips
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Abstract

We describe a novel splitting approach to numerical relativistic magnetohydrodynamics (RMHD) designed to expand its applicability to the domain of ultra-high magnetisation (high-$\sigma$). In this approach, the electromagnetic field is split into the force-free component and its perturbation due to the plasma inertia. Accordingly, the system of RMHD equations is extended to include the subsystem of force-free degenerate electrodynamics and the subsystem governing the plasma dynamics and the perturbation of the force-free field. The combined system of conservation laws is integrated simultaneously, to which aim various numerical techniques can be used, and the force-free field is recombined with its perturbation at the end of every timestep. To explore the potential of this splitting approach, we combined it with a 3rd-order WENO method, and carried out a variety of 1D and 2D test simulations. The simulations confirm the robustness of the splitting method in the high-$\sigma$ regime, and also show that it remains accurate in the low-$\sigma$ regime, all the way down to $\sigma$ = 0. Thus, the method can be used for simulating complex astrophysical flows involving a wide range of physical parameters. The numerical resistivity of the code obeys a simple ansatz and allows fast magnetic reconnection in the plasmoid-dominated regime. The results of simulations involving thin and long current sheets agree very well with the theory of resistive magnetic reconnection.
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相对论磁流体力学数值计算的分裂方法
我们描述了一种新颖的相对论磁流体力学(RMHD)数值分裂方法,旨在将其适用性扩展到超高磁化(高$\sigma$)领域。在这种方法中,电磁场被拆分为无力分量和等离子体惯性引起的扰动。相应地,RMHD方程系统被扩展到包括无力退化电动力学子系统和控制等离子体动力学和无力场扰动的子系统。同时对组合的守恒定律系统进行积分,以便使用各种数值技术,并在每个时间步结束时将无力场与其扰动重新组合。为了探索这种分裂方法的潜力,我们将其与三阶 WENO 方法相结合,并进行了各种一维和二维测试模拟。模拟结果证实了该分裂方法在高(sigma)量级下的稳健性,同时也表明该方法在低(sigma)量级下(一直到(sigma)=0)仍然是精确的。该代码的数值电阻率服从一个简单公设,允许在等离子体主导机制中进行快速磁性再连接,涉及细长电流片的模拟结果与电阻磁性再连接理论非常吻合。
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