Improved the laser-induced damage threshold of fused silica by atmospheric pressure plasma processing

SPIE/SIOM Pacific Rim Laser Damage Pub Date : 2023-12-22 DOI:10.1117/12.3021232

Jun Chen, Lin Wang, Chaoyang Wei, Jianda Shao, Aihuan Dun

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Abstract

Fused silica optics are widely used in high-power laser systems and ultraviolet optical systems because of their excellent properties. Laser-induced damage threshold (LIDT) of fused silica is a key problem that limits the improvement of optical systems. Atmospheric pressure plasma processing (APPP) has great promise for improving LIDT because it involves lowcost, non-contact, and high-efficiency material removal based on its pure chemical etching mechanism. However, the deteriorated surface morphology after atmospheric plasma etching limits the further improvement of LIDT of fused silica. This study analyzes the exposure and passivation processes of subsurface scratches during atmospheric pressure plasma processing. The evolution process of interfacial contours related to the etching and deposition process is described. At the end, a series of etching experiments under different dwell times are carried out and a flexible medium polishing processing is used to improve the deteriorated surface quality. The results indicate that the LIDT of fused silica is significantly increased from 8.1 J/cm2 to 30.8 J/cm2 by APPP and flexible medium polishing processing. APPP is expected to be effective in improving the LIDT of fused silica.

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通过常压等离子加工提高熔融石英的激光诱导损伤阈值

熔融石英光学器件因其优异的性能而被广泛应用于高功率激光系统和紫外光学系统。熔融石英的激光诱导损伤阈值（LIDT）是限制光学系统改进的一个关键问题。大气压力等离子体处理（APPP）基于其纯化学蚀刻机制，可实现低成本、非接触和高效率的材料去除，因此在提高 LIDT 方面大有可为。然而，大气等离子体蚀刻后恶化的表面形态限制了熔融石英 LIDT 的进一步改善。本研究分析了常压等离子处理过程中表面下划痕的暴露和钝化过程。研究描述了与蚀刻和沉积过程相关的界面轮廓演变过程。最后，进行了一系列不同停留时间下的蚀刻实验，并采用柔性介质抛光处理来改善恶化的表面质量。结果表明，通过 APPP 和柔性介质抛光处理，熔融石英的 LIDT 从 8.1 J/cm2 显著提高到 30.8 J/cm2。预计 APPP 能有效改善熔融石英的 LIDT。

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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SPIE/SIOM Pacific Rim Laser Damage

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