A relativistic particle pusher for ultra-strong electromagnetic fields

Jérôme Pétri
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引用次数: 8

Abstract

Abridged. Kinetic plasma simulations are nowadays commonly used to study a wealth of non-linear behaviours and properties in laboratory and space plasmas. In particular, in high-energy physics and astrophysics, the plasma usually evolves in ultra-strong electromagnetic fields produced by intense laser beams for the former or by rotating compact objects such as neutron stars and black holes for the latter. In these ultra-strong electromagnetic fields, the gyro-period is several orders of magnitude smaller than the timescale on which we desire to investigate the plasma evolution. Some approximations are required like for instance artificially decreasing the electromagnetic field strength which is certainly not satisfactory. The main flaw of this downscaling is that it cannot reproduce particle acceleration to ultra-relativistic speeds with Lorentz factor above $\gamma \approx 10^3-10^4$. In this paper, we design a new algorithm able to catch particle motion and acceleration to Lorentz factor up to $10^{15}$ or even higher by using Lorentz boosts to special frames where the electric and magnetic field are parallel. Assuming that these fields are locally uniform in space and constant in time, we solve analytically the equation of motion in a tiny region smaller than the length scale of the spatial and temporal gradient of the field.
一个用于超强电磁场的相对论粒子推进器
节选。目前,动力学等离子体模拟通常用于研究实验室和空间等离子体的大量非线性行为和特性。特别是在高能物理学和天体物理学中,等离子体通常在超强电磁场中演化,前者是由强激光束产生的,后者是由旋转致密物体(如中子星和黑洞)产生的。在这些超强电磁场中,陀螺周期比我们希望研究等离子体演化的时间尺度小几个数量级。需要一些近似,例如人为地降低电磁场强度,这肯定是不令人满意的。这种缩小尺度的主要缺陷是,它不能再现粒子加速到超过$\gamma \approx 10^3-10^4$的洛伦兹系数的超相对论速度。在本文中,我们设计了一种新的算法,通过在电场和磁场平行的特殊帧上使用洛伦兹提升,可以捕捉到粒子运动和加速度到$10^{15}$甚至更高。假设这些场在空间上是局部均匀的,在时间上是恒定的,我们在小于场的时空梯度的长度尺度的极小区域内解析求解运动方程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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