193 纳米波长下 CaF2 光学元件的激光诱导损伤

Laser Damage Pub Date : 2023-11-24 DOI:10.1117/12.2685720

Jue Wang, Gerald P. Cox, Keith J. Donohue, Ronald W. Davis, Ying Shi, Cody V. Cushman, A. Rezikyan, Galan G. Moore, James E. Tingley, Keith J. Becken, Matthew R. Ross, Michael D. Thomas

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摘要

使用 ISO S-on-1 方法在 193 nm 波长的 CaF2 光学器件上进行了激光诱导损伤（LID）测试，S 值从标准的 200 到 103、104 和 105 次/点，流量从 0.1 J/cm2 到 4.0 J/cm2。使用平顶光束轮廓和 250 μm × 250 μm 的光束足迹，在标准的 200-on-1 试验中观察到了由吸收引起的 LID。通过增加脉冲数并降低通量，检测到了缺陷引发的 LID。吸收驱动的 LID 可归因于次表层损伤和双光子吸收。使用 FemtoFinish 抛光工艺消除了前者。后者是通过激光热量测量实验确定的。X 射线衍射和激光热量测量证实了晶体体积和表面抛光质量的改善。此外，还进行了加速寿命损伤测试（ALDT），脉冲数增加到 106 次/点。结果证实，要求苛刻的激光光学器件的寿命预测得到了提高。

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Laser-induced damage of CaF2 optics at 193 nm

Laser-induced damage (LID) tests were conducted on CaF2 optics at 193 nm using ISO S-on-1 method with the S varying from a standard 200 to 103, 104, and 105 shots/site and fluences ranging from 0.1 J/cm2 to 4.0 J/cm2. Using a flat-top beam profile and a beam footprint of 250 μm × 250 μm, absorption-derived LID was observed on the standard 200-on-1 test. Defect-initiated LID was detected by increasing the pulse count with a reduced fluence. The absorption-driven LID was attribute to subsurface damage and two-photon absorption. The former was eliminated by using a FemtoFinish polishing process. The latter was experimentally determined by using laser calorimetric measurement. Improved crystal bulk and surface finishing quality were confirmed by X-ray diffraction and laser calorimetric measurement. Accelerated lifetime damage test (ALDT) was further conducted with an increased pulse count up to 106 shots/site. The results confirm an enhanced lifespan prediction of the demanding laser optics.

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Laser Damage

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