Particle simulations of ion-extraction process from a decaying plasma assisted by radio-frequency plasma heating

Plasma Sources Science and Technology Pub Date : 2023-12-18 DOI:10.1088/1361-6595/ad1014

Jing-Yu Sun, Xing Chen, Kai Zhao, Cheng Yuan, Xiao-Yong Lu, Fei Gao, You-Nian Wang

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Abstract

In this study, two-dimensional kinetic particle simulations were employed to examine the potential of radio-frequency (rf) plasma heating in enhancing ion extraction efficiency in a decaying plasma with the configuration of parallel plates. The numerical results suggest that the application of rf power based on the direct current electrostatic method leads to a remarkable increase in the ion extraction flux, thereby reducing the time required for ion extraction. The increase in the ion extraction flux is attributed to the enhancement of the penetration ability of the rf electric field into the plasma, especially in cases of high rf frequencies, which can elevate the bulk electron temperature to approach 10 eV. The propagation speed of ion rarefaction waves is enhanced by the increased electron temperature, speeding up the process of ion extraction. The study also found that an increase in rf voltage causes more intense plasma oscillations to screen out the rf disturbance, further increasing the electron temperature. Furthermore, as ion extraction continues, the heating effect of rf frequencies was found to be enhanced due to the decay of plasma density.

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射频等离子体加热辅助衰变等离子体离子萃取过程的粒子模拟

本研究采用二维动力学粒子模拟来研究射频（rf）等离子体加热在提高平行板配置衰变等离子体中离子萃取效率方面的潜力。数值结果表明，基于直流静电法的射频功率应用可显著提高离子萃取通量，从而缩短离子萃取所需的时间。离子萃取通量的增加归因于射频电场对等离子体穿透能力的增强，尤其是在高射频频率的情况下，它能使电子体温度升高到接近 10 eV。离子稀释波的传播速度因电子温度升高而增强，从而加快了离子萃取过程。研究还发现，增加射频电压会引起更强烈的等离子体振荡以屏蔽射频干扰，从而进一步提高电子温度。此外，随着离子萃取的继续，研究发现由于等离子体密度的衰减，射频频率的加热效应也会增强。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Plasma Sources Science and Technology

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