Breathing mode oscillations in Hall effect thrusters occur depending on the operation parameters such as discharge voltage, anode mass flow, and magnetic field. Time-dependent laser-induced fluorescence is used to measure the ion velocity distribution functions (IVDFs) with a modulating anode voltage. [Diallo et al. RSI 2015] Experimental results suggest that the IVDFs vanish or shifts its peak to a small velocity near the maximum peak of the discharge current oscillation. A zero-dimensional plasma global model [Hara et al. PoP 2014] is used to analyze the ionization oscillation mode by forcing the electric field to oscillate with a certain strength and frequency. In this model, the neutral atom continuity equation, the ion continuity and momentum equations, and electron energy equation are taken into account. Global model suggests that the ion mean velocity can fluctuate in time and is in-phase with the electric field oscillation. A 1D hybrid simulation shows that there can be a region where ion distribution exists in slow velocity (~1000 m/s) due to reversed electric field during the oscillation.
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机译:霍尔效应推进器中的呼吸模式振荡取决于运行参数,例如放电电压,阳极质量流量和磁场。随时间变化的激光诱导荧光用于测量阳极电压调制的离子速度分布函数(IVDF)。 [Diallo等。 [RSI 2015]实验结果表明,IVDF的峰值在放电电流振荡的最大峰值附近消失或移动到很小的速度。零维等离子体整体模型[Hara等。 [PoP 2014]用于通过迫使电场以一定强度和频率振荡来分析电离振荡模式。在该模型中,考虑了中性原子连续性方程,离子连续性和动量方程以及电子能量方程。整体模型表明,离子平均速度会随时间波动,并且与电场振荡同相。一维混合仿真显示,由于振荡过程中的反向电场,可能存在一个区域,该区域中的离子分布以慢速(〜1000 m / s)存在。
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