Power measurement analysis of moderate pressure capacitively coupled discharges

S. Hussain, Abhishek Verma, K. Bera, Shahid Rauf, M. Goeckner
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Abstract

This study examines the transition of 13.56 MHz, capacitively coupled plasmas (CCP) from low to intermediate pressure regimes. Here, we investigate power deposition/plasma production in argon, nitrogen, and oxygen discharges as a function of pressure. These three feed gases were chosen as they provide a set of electropositive and electronegative gases and they are widely discussed in the existing literature. Experiments were conducted for all combinations of pressures: 0.5, 1.5, and 2.5 Torr, and nominal power density between 0.1 and 0.7 W/cm2 for each feed gas at a fixed electrode gap of 24 mm, a commonly employed gap in many industrial processes. Our study shows that increasing pressure results in an increase in current at a given electrode bias in argon and oxygen discharges, while there is no discernible pressure-induced change in nitrogen discharges. We attribute this increase to an increase in plasma density, which might result from a change in power deposition or ionization processes. It is likely that heating via secondary electrons becomes more important at intermediate pressures, resulting in increased plasma density and current. Specifically, based on our measurements, it appears that the mechanisms through which power is deposited into the plasma change with increasing pressure for both argon and oxygen discharges but not for nitrogen discharges. Our experimental results align with the outcomes of our simulations and the simulation results of CCP discharges conducted by other researchers under similar conditions.
中等压力电容耦合放电的功率测量分析
本研究探讨了 13.56 MHz 电容耦合等离子体 (CCP) 从低压到中压的转变。在此,我们研究了氩气、氮气和氧气放电中的功率沉积/等离子体产生与压力的函数关系。之所以选择这三种给料气体,是因为它们提供了一组电正性和电负性气体,并且在现有文献中得到了广泛讨论。对所有压力组合进行了实验:在固定电极间隙为 24 毫米(这是许多工业流程中常用的间隙)的条件下,每种原料气体的额定功率密度介于 0.1 和 0.7 W/cm2 之间。我们的研究表明,在氩气和氧气放电中,增加压力会导致给定电极偏压下的电流增加,而在氮气放电中则没有明显的压力变化。我们将这种增加归因于等离子体密度的增加,这可能是功率沉积或电离过程发生变化的结果。在中等压力下,通过次级电子进行加热可能变得更加重要,从而导致等离子体密度和电流增加。具体来说,根据我们的测量结果,氩气和氧气放电的功率沉积到等离子体的机制似乎会随着压力的增加而改变,但氮气放电则不会。我们的实验结果与我们的模拟结果以及其他研究人员在类似条件下进行的 CCP 放电模拟结果一致。
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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