抗反射涂层LBO晶体紫外非线性吸收的实时研究

Laser Damage Pub Date : 2022-12-02 DOI:10.1117/12.2641222
Erikas Atkočaitis, A. Melninkaitis
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引用次数: 0

摘要

吸光度通常被认为是光学元件的静态特性,可以通过标准化的测量程序来确定。虽然这种测量通常使用低光强的光学仪器进行,但在高功率激光应用中,照射条件却大不相同。由于高强度的光,光学器件可能变得不稳定:光学特性以非线性的方式变化,最终可能导致激光引起的损伤。为了研究这些影响,我们采用了共路干涉测量技术,结合高能量和高平均功率激光源,在1 MHz重复频率下工作,在355nm波长下输出10 ps脉冲。研究了在三硼酸锂(LBO)晶体上采用离子束溅射沉积的抗反射涂层(AR@355 nm)。我们的初步研究结果表明,在损伤影响点附近存在较强的非线性吸光度和疲劳,但损伤事件与临界吸光度水平没有直接关系。本文试图通过建立非线性吸收的数值模型来预测AR涂层光学元件的寿命。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Real-time investigation of the UV nonlinear absorptance in an anti-reflective coated LBO crystals
Absorptance is often considered a static feature of an optical element that is determined via standardized measurement procedures. Although such measurements are often performed using optical instruments with low light intensity, in high power laser applications irradiation conditions are considerably different. Optics might become unstable due to highly intense light: optical properties change in a nonlinear way and might eventually lead to laser-induced damage. To study these effects we employed the common-path interferometry technique in combination with a high energy and high average power laser source, operating at 1 MHz repetition rate and delivering 10 ps pulses at 355 nm wavelength. We investigated an anti-reflective (AR@355 nm) coating deposited using ion beam sputtering on a lithium triborate (LBO) crystal. Our preliminary results indicate both strong nonlinear absorptance and fatigue near the damaging fluence, however, damage events were not directly related to the critical absorptance level. An attempt is made to predict the lifetime of an AR coated optics by establishing a numerical model of nonlinear absorption.
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