Fundamentals of collisionless shocks for astrophysical application, 2. Relativistic shocks

IF 27.8 1区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS
A. M. Bykov, R. A. Treumann
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引用次数: 109

Abstract

In this concise review of the recent developments in relativistic shock theory in the Universe we restrict ourselves to shocks that do not exhibit quantum effects. On the other hand, emphasis is given to the formation of shocks under both non-magnetised and magnetised conditions. We only briefly discuss particle acceleration in relativistic shocks where much of the results are still preliminary. Analytical theory is rather limited in predicting the real shock structure. Kinetic instability theory is briefed including its predictions and limitations. A recent self-similar relativistic shock theory is described which predicts the average long-term shock behaviour to be magnetised and to cause reasonable power-law distributions for energetic particles. The main focus in this review is on numerical experiments on highly relativistic shocks in (i)?pair and (ii)?electron-nucleon plasmas and their limitations. These simulations do not validate all predictions of analytic and self-similar theory and so far they do not solve the injection problem and the self-modification by self-generated cosmic rays. The main results of the numerical experiments discussed in this review are: (i)?a confirmation of shock evolution in non-magnetised relativistic plasma in 3D due to either the lepton-Weibel instability (in pair plasmas) or to the ion-Weibel instability; (ii)?the sensitive dependence of shock formation on upstream magnetisation which causes suppression of Weibel modes for large upstream magnetisation ratios σ>10?3; (iii)?the sensitive dependence of particle dynamics on the upstream magnetic inclination angle θ Bn , where particles of θ Bn >34° cannot escape upstream, leading to the distinction between ‘subluminal’ and ‘superluminal’ shocks; (iv)?particles in ultra-relativistic shocks can hardly overturn the shock and escape to upstream; they may oscillate around the shock ramp for a long time, so to speak ‘surfing it’ and thereby becoming accelerated by a kind of SDA; (v)?these particles form a power-law tail on the downstream distribution; their limitations are pointed out; (vi)?recently developed methods permit the calculation of the radiation spectra emitted by the downstream high-energy particles; (vii)?the Weibel-generated downstream magnetic fields form large-amplitude vortices which could be advected by the downstream flow to large distances from the shock and possibly contribute to an extended strong field region; (viii)?if cosmic rays are included, Bell-like modes can generate upstream magnetic turbulence at short and, by diffusive re-coupling, also long wavelengths in nearly parallel magnetic field shocks; (ix)?advection of such large-amplitude waves should cause periodic reformation of the quasi-parallel shock and eject large-amplitude magnetic field vortices downstream where they contribute to turbulence and to maintaining an extended region of large magnetic fields.

天体物理应用中无碰撞冲击的基本原理,2。相对论的冲击
在这篇对宇宙相对论激波理论最新发展的简明回顾中,我们将自己限制在不表现出量子效应的激波上。另一方面,重点讨论了非磁化和磁化条件下冲击的形成。我们只简要地讨论了相对论性激波中的粒子加速,其中大部分结果仍处于初步阶段。解析理论在预测实际冲击结构方面是相当有限的。简要介绍了动力学不稳定性理论,包括它的预测和局限性。描述了一个最近的自相似相对论激波理论,该理论预测了磁化的平均长期激波行为,并导致高能粒子的合理幂律分布。这篇综述的主要重点是在(i)?配对和(ii)?电子-核子等离子体及其局限性。这些模拟并不能验证解析理论和自相似理论的所有预测,到目前为止,它们还没有解决注入问题和自生宇宙射线的自修正问题。本文讨论的主要数值实验结果有:(i)?证实了非磁化相对论等离子体在三维中由于轻子-维贝尔不稳定性(在对等离子体中)或离子-维贝尔不稳定性而产生的激波演化;(2)吗?激波形成对上游磁化的敏感依赖性,在较大的上游磁化比σ>10?(3)吗?粒子动力学对上游磁倾角θ Bn的敏感依赖,其中θ Bn >34°的粒子不能逃离上游,导致“亚光速”和“超光速”冲击的区分;(四)?处于超相对论激波中的粒子很难推翻激波向上游逃逸;它们可能在激波坡道周围振荡很长一段时间,也就是说“冲浪”,从而被一种SDA加速;(v) ?这些粒子在下游分布上形成幂律尾巴;指出了它们的局限性;(六)?最近发展的方法允许计算下游高能粒子发射的辐射光谱;(七)?威贝尔产生的下游磁场形成了大振幅涡旋,这些涡旋可以被下游气流平流到距离激波较远的地方,可能有助于扩大强磁场区域;(八)?如果包括宇宙射线,贝尔模式可以产生上游的短波长磁湍流,通过扩散再耦合,也可以在几乎平行的磁场冲击中产生长波;(九)?这种大振幅波的平流应该引起准平行激波的周期性改造,并在下游喷射出大振幅磁场涡,在那里它们有助于湍流并维持一个大磁场的扩展区域。
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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来源期刊
The Astronomy and Astrophysics Review
The Astronomy and Astrophysics Review 地学天文-天文与天体物理
CiteScore
45.00
自引率
0.80%
发文量
7
期刊介绍: The Astronomy and Astrophysics Review is a journal that covers all areas of astronomy and astrophysics. It includes subjects related to other fields such as laboratory or particle physics, cosmic ray physics, studies in the solar system, astrobiology, instrumentation, and computational and statistical methods with specific astronomical applications. The frequency of review articles depends on the level of activity in different areas. The journal focuses on publishing review articles that are scientifically rigorous and easily comprehensible. These articles serve as a valuable resource for scientists, students, researchers, and lecturers who want to explore new or unfamiliar fields. The journal is abstracted and indexed in various databases including the Astrophysics Data System (ADS), BFI List, CNKI, CNPIEC, Current Contents/Physical, Chemical and Earth Sciences, Dimensions, EBSCO Academic Search, EI Compendex, Japanese Science and Technology, and more.
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