电子-质子束和等离子体束之间的成丝不稳定性对正电子的优先加速

M. Dieckmann, S. Spencer, M. Falk, G. Rowlands
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引用次数: 2

摘要

粒子池(PIC)模拟了电子-质子等离子体中电子和正电子的无碰撞射流,揭示了以电子动能为代价的正电子加速。喷流中主要的不稳定性是电子、质子和正电子之间的细丝不稳定性。在这项工作中,我们展示了在静止的初始未磁化的环境电子-质子等离子体和以非相对论速度穿过它的对等离子体束之间的丝状不稳定性,确实导致了优先的正电子加速。细丝的形成主要由与电流矢量方向相同的粒子填充。正电子丝被电磁场从电子束丝中分离出来。一些粒子可以越过场边界进入其他物种的细丝。正电子丝可以通过收集周围等离子体的电子来中和它们的净电荷,而质子则不容易跟随束流电子丝。因此,正电子细丝可以被压缩到比束流电子细丝更高的密度和温度。在不稳定性的指数增长阶段结束后发生的细丝合并导致电子束细丝的膨胀,从而放大了它们产生的磁场并在细丝中产生电场。束流电子在电场中损失了很大一部分动能。电子束中的一些正电子在感应电场的作用下被加速到其初始速度的两倍。模拟结果表明,在正电子灯丝中产生较弱的电场,灯丝中的粒子几乎没有改变其速度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Preferential acceleration of positrons by a filamentation instability between an electron–proton beam and a pair plasma beam
Particle-in-cell (PIC) simulations of collisionless jets of electrons and positrons in an ambient electron-proton plasma have revealed an acceleration of positrons at the expense of electron kinetic energy. The dominant instability within the jet was a filamentation instability between electrons, protons and positrons. In this work we show that a filamentation instability, between an initially unmagnetized ambient electron-proton plasma at rest and a beam of pair plasma that moves through it at a non-relativistic speed, indeed results in preferential positron acceleration. Filaments form that are filled predominantly with particles with the same direction of their electric current vector. Positron filaments are separated by electromagnetic fields from beam electron filaments. Some particles can cross the field boundary and enter the filament of the other species. Positron filaments can neutralize their net charge by collecting the electrons of the ambient plasma while protons cannot easily follow the beam electron filaments. Positron filaments can thus be compressed to a higher density and temperature than the beam electron filaments. Filament mergers, which take place after the exponential growth phase of the instability has ended, lead to an expansion of the beam electron filaments, which amplifies the magnetic field they generate and induces an electric field in this filament. Beam electrons lose a substantial fraction of their kinetic energy to the electric field. Some positrons in the beam electron filament are accelerated by the induced electric field to almost twice their initial speed. The simulations show that a weaker electric field is induced in the positron filament and particles in this filament hardly change their speed.
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