2D micro-chamber for DC plasma working at low power

2014 15th International Conference on Thermal, Mechanical and Mulit-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE) Pub Date : 2014-04-07 DOI:10.1109/EUROSIME.2014.6813810

V. Rochus, V. Samara, B. Vereecke, P. Soussan, B. Onsia, X. Rottenberg

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Abstract

The plasma micro-chambers proposed in the literature make typically usage of relatively high RF power applied to cavities characterized by their 3D geometry, difficult to integrate on wafer. This work reports on the design, wafer-level fabrication and characterization of 2D DC plasma micro-chambers working at atmospheric pressure with noble and inert gases like helium and argon. The MEMS technology developed for this purpose allows the definition of small gaps in order to reduce the power consumption. The strike and sustain electrodes are made of Titanium Nitrite, material of choice for its hardness, and thus resistance to the ion bombardment, as well as his high melting point temperature, that allows the proximity and contact with high temperature plasmas. Measurements were performed, applying a high voltage to these electrodes, and measuring the relation between the voltage and the current when the plasma is ignited. Considering different gaps between the electrodes we can extract then the power consumed in the plasma and optimize the 2D micro-chamber.

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用于低功率直流等离子体的二维微室

文献中提出的等离子体微室通常使用相对较高的射频功率应用于具有3D几何形状的腔体，难以在晶圆上集成。本研究报告了二维直流等离子体微室的设计、晶圆级制造和表征，这些微室在常压下工作，使用惰性气体如氦和氩。为此目的开发的MEMS技术允许定义小间隙以降低功耗。打击和维持电极由亚硝酸钛制成，这种材料的选择是因为它的硬度，因此可以抵抗离子轰击，以及它的高熔点温度，这使得它可以接近和接触高温等离子体。测量是这样进行的:对这些电极施加高电压，并测量等离子体点燃时电压和电流之间的关系。考虑到电极之间的不同间隙，我们可以提取等离子体中消耗的能量，并对二维微室进行优化。

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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2014 15th International Conference on Thermal, Mechanical and Mulit-Physics Simulation and Experiments in Microelectronics and Microsystems (EuroSimE)

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