Kuldeep Singh, Steffy Sara Varghese, Frank Verheest, Ioannis Kourakis
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引用次数: 0
摘要
磁层多尺度航天器(MMS)探测到地球磁尾重联喷流部位发生的静电孤立波(ESWs)特征(Liu et al.)。这些观察结果促使我们探索磁尾区快速和慢模离子声孤立波形成的机制。为此,我们建立了一个由非热电子和两个冷离子束组成的三组分磁化等离子体模型,它们分别与磁场平行和反平行。在这项工作中,我们研究了由两个逆流(漂移)离子束与超热电子背景相互作用组成的超热空间等离子体中离子声亚音速波的存在条件。采用精确(非摄动)非线性技术研究了波束速度和谱指数对亚音速演化的影响。线性分析表明,当波束速度低于阈值时,亚音速不稳定;因此,在这种情况下,只形成常规的超音速(快)波。另一方面,当光束速度超过阈值时,可能存在超音速或亚音速波。分析了束流速度和电子超热度对亚音速孤立波特性的综合影响。我们的结果与MMS航天器对慢速ESWs的观测结果很好地吻合。我们的发现将有助于揭示迄今为止尚未探索的亚音速波的动力学特征,这些亚音速波可能发生在地球磁尾的重连点。
On the Existence of Subsonic Solitary Waves Associated with Reconnection Jets in Earth’s Magnetotail
Abstract The Magnetospheric Multiscale Spacecraft (MMS) has detected the signature of electrostatic solitary waves (ESWs) occurring in the reconnection jet site of the Earth’s magnetotail (Liu et al.). These observations have motivated us to explore the mechanism underlying the formation of fast- and slow-mode ion-acoustic solitary waves in the magnetotail region. To this end, we have formulated a three-component magnetized plasma model consisting of nonthermal electrons and two cold ion beams streaming parallel and antiparallel to the magnetic field, respectively. In this work, we have examined the existence conditions for ion-acoustic subsonic waves in a suprathermal space plasma comprising two counterstreaming (drifting) ion beams interacting with a suprathermal electron background. An exact (nonperturbative) nonlinear technique has been adopted to examine the role of the beam velocity and the spectral index on the evolution of subsonic waves. Linear analysis reveals that subsonic waves are unstable when the beam velocity is lower than a threshold value; hence in this regime, only conventional supersonic (fast) waves are formed. On the other hand, when the beam velocity exceeds the threshold, either supersonic or subsonic waves may exist. The combined impact of the beam velocity and electron superthermality on the characteristics of subsonic solitary waves has been analyzed. Our results are shown to be in good agreement with observations of slow ESWs by the MMS spacecraft. Our findings will help to unfold the so-far unexplored dynamical characteristics of subsonic waves that may occur in the reconnection site of Earth’s magnetotail.
期刊介绍:
The Astrophysical Journal is the foremost research journal in the world devoted to recent developments, discoveries, and theories in astronomy and astrophysics.