213 nm Nd-YAG pulsed laser damage of non-loaded and hydrogen-loaded silica-based fibers

Laser Damage Pub Date : 2020-10-20 DOI:10.1117/12.2574380

S. Heiden, P. Raithel, R. Yadav, K. Klein

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引用次数: 3

Abstract

An automated set-up for 213 nm UV laser damaging in parallel to spectral analyses will be used to show the spectral laser damaging in silica-based fibers with low hydroxyl content. The 213 nm wavelength is ideal, because it is close to the peak wavelength of one of the E’-centers in silica. Due to automation, short-term measurements down to 0.5 s and long-term measurements up to 2 days and more are possible. In addition, the spectral transmission changes are fitted with multiple Gaussian shaped bands. Although the basic attenuation in non-loaded fibers is high, the pulse energies are still high enough to generate defects along a 1 m long fiber. For the first time, to our knowledge, a transfer from E’γ to E’γ is observed within 1 s, with a laser repetition rate of 2 kHz. Due to optimal fitting, a band around 180 nm is likely influencing the UVC region. In hydrogen-loaded fibers, similar UV defects are seen. The related absorption bands can be optimally adopted to measurement results. The E’-centers play a minor role in short-term measurements because these defects are passivated during hydrogen-loading. Additionally, the band at 328 nm due to molecular chlorine will be reduced. The temporal behavior of all absorption band, including the predicted 180 nm band, are shown.

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213 nm Nd-YAG脉冲激光对硅基光纤的损伤

213 nm紫外激光损伤与光谱分析并行的自动化装置将用于显示光谱激光对羟基含量低的硅基纤维的损伤。213 nm波长是理想的，因为它接近二氧化硅中一个E '中心的峰值波长。由于自动化，短期测量低至0.5秒，长期测量长达2天或更长时间是可能的。此外，光谱透射变化用多个高斯形波段拟合。虽然在无载荷光纤中的基本衰减很大，但脉冲能量仍然高到足以沿1 m长的光纤产生缺陷。第一次，据我们所知，在1秒内观察到从E ' γ到E ' γ的转移，激光重复率为2 kHz。由于最佳拟合，180nm左右的波段可能影响UVC区域。在含氢纤维中，也可以看到类似的紫外线缺陷。相关的吸收带可以最佳地用于测量结果。E′中心在短期测量中起次要作用，因为这些缺陷在氢加载过程中被钝化。另外，328 nm处的波段由于氯分子的作用而减少。给出了所有吸收带的时间行为，包括预测的180 nm吸收带。

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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Laser Damage

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