Detection of a low-frequency ion instability in a magnetic nozzle

A Caldarelli, F Filleul, K Takahashi, R W Boswell, C Charles, J E Cater, N Rattenbury
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Abstract

A low-frequency ion instability, with frequency fI between the ion gyrofrequency and the lower hybrid frequency fc,i<fIfLH, is detected in an argon plasma expanding in a magnetic nozzle for magnetic fields between 240<Bz,max<700 G. The frequency of the instability exhibits a linear dependence with magnetic field strength, and the wave amplitude has a radial maximum that would match the location of a conical density structure, i.e. high-density cones. For all of the magnetic field cases analysed, the high-frequency spectra showed upper and lower sidebands centred around the driving frequency and at a separation equal to the instability frequency, 27.12 MHz ±fI kHz. Measurements of the perpendicular wavenumber would satisfy, for certain magnetic field strengths, the dispersion relation of both an electrostatic ion cyclotron wave (ICW) and of an ion acoustic wave. It is hypothesised that the observed low-frequency wave could be an acoustic-like instability propagating perpendicular to the magnetic field, which develops as an ICW at some magnetic field strengths. From the data collected, it is suggested that the high-frequency sidebands may be caused by modulation of the low-frequency wave.
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检测磁性喷嘴中的低频离子不稳定性
在磁性喷嘴中膨胀的氩等离子体中检测到了低频离子不稳定性,其频率fI介于离子陀螺频率和较低的混合频率fc,i<fI≪fLH之间,磁场强度在240<Bz,max<700 G之间。在分析的所有磁场情况下,高频频谱都显示出以驱动频率为中心的上下边带,其间隔等于不稳定频率(27.12 MHz±fI kHz)。在某些磁场强度下,垂直波长的测量结果符合静电离子回旋波(ICW)和离子声波的频散关系。根据假设,观测到的低频波可能是垂直于磁场传播的类似声波的不稳定性,在某些磁场强度下会发展成 ICW。从收集到的数据来看,高频边带可能是由低频波的调制引起的。
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