In-situ cleaning organic contaminants on SiO2 sol-gel antireflection film by low-pressure air plasma

Laser Damage Pub Date : 2021-10-12 DOI:10.1117/12.2599668
Yuhai Li, Q. Bai, R. Shen, Peng Zhang, L. Lu, Xiao-Qing Yuan, X. Miao, W. Han, Hao Liu, Lin Huang, Caizhen Yao
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Abstract

Organic contaminants on optical components can degrade optical properties, thus limiting the energy enhancement of highpeak- power laser systems. It is still challenging to remove organic contaminants on the SiO2 sol-gel antireflection film and avoid damage. In this work, a low-pressure air plasma in-situ cleaning technique and a chemical reaction model of plasma cleaning were proposed to study the removal of organic contaminants. The optical properties of sol-gel AR films suffered from organic contaminants were evaluated by transmittance and laser-induced damage threshold, which recovered completely after 5 minutes of plasma cleaning without damage. Meanwhile, the hydrophilicity of the surface and the surface free energy were significantly increased after plasma treating. Surface composition analysis indicated that the CH and C-C bonds were reduced considerably, while abundant C=C and C=O bonds were produced after plasma cleaning. Optical emission spectrum analyzed the reactive species and its concentration in the air plasma as a reference for simulation. The chemical interaction process of oxygen radicals with organic contaminants was simulated by reactive molecular dynamics. The results can provide a guide for optical components in-situ cleaning.
低压空气等离子体原位清洗SiO2溶胶-凝胶增透膜上的有机污染物
光学元件上的有机污染物会降低光学性能,从而限制了高能激光系统的能量增强。如何去除SiO2溶胶-凝胶增透膜上的有机污染物并避免其损坏仍然是一个挑战。本文提出了一种低压空气等离子体原位清洗技术和等离子体清洗的化学反应模型来研究有机污染物的去除。通过透光率和激光损伤阈值来评价受有机污染物影响的溶胶-凝胶AR膜的光学性能,等离子清洗5分钟后完全恢复,无损伤。同时,等离子体处理后表面亲水性和表面自由能均显著提高。表面组成分析表明,等离子体清洗后,CH和C-C键明显减少,而大量的C=C和C=O键产生。光学发射光谱分析了空气等离子体中的反应物质及其浓度,作为模拟参考。用反应分子动力学方法模拟了氧自由基与有机污染物的化学相互作用过程。研究结果可为光学元件的原位清洗提供指导。
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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