真空环境下熔融石英样品1064nm激光致损伤研究

R. Diaz, M. Chambonneau, P. Grua, J. Rullier, J. Natoli, L. Lamaignère
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摘要

在1064 nm处研究了真空对熔融石英组件出口表面纳秒激光损伤的影响。在本研究中,正如先前在空气中观察到的那样,当多个纵向模式激光脉冲引发时,在平面表面上系统地观察到激光诱导损伤部位周围的环状图案。与空气相比,印刷的图案明显更集中。得到的损伤形态与脉冲时间结构之间的相关性表明,激光驱动的烧蚀机制导致能量沉积的彻底印记。烧蚀过程被认为是由二氧化硅形成的等离子体的扩散膨胀引起的热电子对表面的激活。在真空中对光学光栅进行的额外实验有力地加强了这一解释,在该实验中,损坏部位没有显示出任何环状图案。定性地说,在真空中,与强度相关的环出现速度V∝I1/2不同于在空气中,V∝I1/3。这表明在真空中环形图案的形成机制与在空气中不同。此外,在空气中进行的实验表明,真空中激活锋传播的机制是不完善的。
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Study of laser-induced damage at 1064nm in fused silica samples in vacuum environment
The influence of vacuum on nanosecond laser-induced damage at the exit surface of fused silica components is investigated at 1064 nm. In the present study, as previously observed in air, ring patterns surrounding laserinduced damage sites are systematically observed on a plane surface when initiated by multiple longitudinal modes laser pulses. Compared to air, the printed pattern is clearly more concentrated. The obtained correlation between the damage morphology and the temporal structure of the pulses suggests a laser-driven ablation mechanism resulting in a thorough imprint of energy deposit. The ablation process is assumed to be subsequent to an activation of the surface by hot electrons related to the diffusive expansion of a plasma formed from silica. This interpretation is strongly reinforced with additional experiments performed on an optical grating in vacuum on which damage sites do not show any ring pattern. Qualitatively, in vacuum, the intensity-dependent ring appearance speed V ∝ I1/2 is shown to be different than in air where V ∝ I1/3 . This demonstrates that the mechanisms of formation of ring patterns are different in vacuum than in air. Moreover, the mechanism responsible of the propagation of the activation front in vacuum is shown to be outdone when experiments are performed in air.
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