阴极与磁分离矩阵位置关系对霍尔推力器放电过程的影响

IF 1.6 3区 物理与天体物理 Q3 PHYSICS, FLUIDS & PLASMAS
Xifeng Cao, Hongning Ma, Guojun Xia, Hui Liu, Fangzhou Zhao, Yuhang Wang, Juhui Chen
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引用次数: 0

摘要

摘要以往的研究表明,霍尔推力器羽流区外阴极的安装位置与磁分离矩阵之间存在明显的耦合关系。本文采用细胞内粒子模拟的方法,对阴极与磁分离矩阵不同位置关系下的推力器放电过程进行了比较。通过比较电子传导、电势、等离子体密度等微观参数的分布,试图解释放电差异的形成机理。仿真结果表明,磁分离矩阵内外阴极对电势分布和等离子体密度有显著影响。当阴极位于磁分离矩阵外侧时,羽流区域上方电位相对较低,且羽流区域上方存在较强的电位梯度。这种势梯度更有利于离子在羽流上方的径向扩散,这是羽流发散强的主要原因。离子密度的分布也与电位的分布一致。当阴极位于磁分离矩阵外侧时,离子在羽流区域的径向扩散增强。同时,通过对电子传导结果的比较,发现从阴极发射的电子轨迹在磁分离矩阵的内外两侧存在显著差异。这主要是因为电子受到磁尖的磁镜像效应的影响,使得电子很难在磁分离矩阵上移动。这是造成电位分布差异的主要原因。本文还对几种条件下宏观参数的模拟结果进行了比较,结果与实验结果一致。阴极位于磁分离矩阵内侧,可以有效减小羽散角,提高推力。在本文中,阴极沿径向从R = 50 mm移动到R = 35 mm,推力增加3.6 mN,羽散角减小23.77%。结合电离区和峰值离子密度的比较,可以发现推力变化的主要原因是羽流区离子径向扩散的变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Influence of the position relationship between cathode and magnetic separatrix on the discharge process of Hall thruster
Abstract Previous studies have shown that there is an obvious coupling relationship between the installation location of the external cathode and the magnetic separatrix in the plume region of Hall thruter. In this paper, the particle-in-cell simulation method is used to compare the thruster discharge process under the conditions of different position relationships between the cathode and the magnetic separatrix. By comparing the distribution of electron conduction, potential, plasma density, and other microscopic parameters, we try to explain the formation mechanism of the discharge difference. The simulation results show that the cathode inside and outside the magnetic separatrix has a significant effect on the distribution of potential and plasma density. When the cathode is located outer side of the magnetic separatrix, the potential above the plume region is relatively low, and there is a strong potential gradient above the plume region. This potential gradient is more conducive to the radial diffusion of ions above the plume, which is the main reason for the strong divergence of the plume. The distribution of ion density is also consistent with the distribution of potential. When the cathode is located outer side of the magnetic separatrix, the radial diffusion of ions in the plume region is enhanced. Meanwhile, by comparing the results of electron conduction, it is found that the trajectories of electrons emitted from the cathode are significantly different inner and outer sides of the magnetic separatrix. This is mainly because the electrons are affected by the magnetic mirror effect of the magnetic tip, which makes it difficult for the electrons to move across the magnetic separatrix. It is the main reason for the difference in potential distribution. In this paper, the simulation results of macroscopic parameters under several conditions are also compared, which are consistent with the experimental results. The cathode is located inner side of the magnetic separatrix, which can effectively reduce the plume divergence angle and improve the thrust. In this paper, the cathode moves from R = 50 mm to R = 35 mm along the radial direction, the thrust increases by 3.6 mN, and the plume divergence angle decreases by 23.77%. Combined with the comparison of the ionization region and the peak ion density, it can be found that the main reason for the change in thrust is the change in the radial diffusion of ions in the plume region.
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来源期刊
Plasma Science & Technology
Plasma Science & Technology 物理-物理:流体与等离子体
CiteScore
3.10
自引率
11.80%
发文量
3773
审稿时长
3.8 months
期刊介绍: PST assists in advancing plasma science and technology by reporting important, novel, helpful and thought-provoking progress in this strongly multidisciplinary and interdisciplinary field, in a timely manner. A Publication of the Institute of Plasma Physics, Chinese Academy of Sciences and the Chinese Society of Theoretical and Applied Mechanics.
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