Numerical simulations of weakly and strongly magnetized relativistic jets embedded in a weakly magnetized and strongly magnetized stationary or weakly relativistic (υ = c/2) sheath have been performed. A magnetic field parallel to the flow is used in these simulations performed by the new general relativistic magnetohydrodynamic numerical code RAISHIN used in its relativistic magnetohydrodynamic (RMHD) configuration. In the numerical simulations, the Lorentz factor γ = 2.5 jet is precessed to break the initial equilibrium configuration. In the simulations, sound speeds are approx < c/3~(1/2) in the weakly magnetized simulations and approx < 0.3c in the strongly magnetized simulations. The Alfven wave speed is approx < 0.07c in the weakly magnetized simulations and approx < 0.56c in the strongly magnetized simulations. The results of the numerical simulations are compared to theoretical predictions from a normal mode analysis of the linearized RMHD equations capable of describing a uniform axially magnetized cylindrical relativistic jet embedded in a uniform axially magnetized relativistically moving sheath. The theoretical dispersion relation allows investigation of effects associated with maximum possible sound speeds, Alfven wave speeds near light speed, and relativistic sheath speeds. The prediction of increased stability of the weakly magnetized system resulting from c/2 sheath speeds and the stabilization of the strongly magnetized system resulting from c/2 sheath speeds is verified by the numerical simulation results.
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机译:进行了弱磁和强磁相对论射流的数值模拟,这些射流嵌入在弱磁和强磁固定或弱相对论(υ= c / 2)护套中。在新的相对论磁流体动力学数字代码RAISHIN的相对论磁流体动力学(RMHD)配置中使用的模拟中使用了与流动平行的磁场。在数值模拟中,洛伦兹因子γ= 2.5射流被推定为打破初始平衡构型。在模拟中,在弱磁化模拟中,声速约为展开▼
