一种采用晶体涂层的高功率处理可变形反射镜系统

Laser Damage Pub Date : 2022-12-02 DOI:10.1117/12.2641048

G. Cole, C. Nguyen, D. Follman, G. Truong, Egbert Krause, Tobias Böhme

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引用次数: 1

摘要

我们概述了一种基于改进Thorlabs DMH40的高功率处理可变形反射镜装置的开发，该装置采用低损耗基板转移晶体涂层作为反射元件。在标准产品中，该系统具有金属涂层(Ag或Al)直径18 mm × 150 μm厚的BK10玻璃基板，安装在40段压电驱动器上，实现高达4阶的Zernike补偿，峰谷行程可达±17.6 μm。在本文描述的改进变体中，金属涂层被替换为高反射率(~99.998%)和低应力(压缩，~130 MPa)单晶GaAs/AlGaAs Bragg堆叠，通过直接键合转移到薄玻璃基板上。在保持类似物理性能的同时，该定制系统在功率处理方面表现出了显著的增强，通过激光诱导损伤测试(由Spica Technologies, Inc.进行)，在1070 nm处产生75 MW/cm2的连续波损伤阈值，1/e2光斑直径为32.8 μm。

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A high-power-handling deformable mirror system employing crystalline coatings

We outline the development of a high-power-handling deformable mirror device, based on a modified Thorlabs DMH40, employing a low-loss substrate-transferred crystalline coating as the reflective element. In standard products, this system features a metal coated (Ag or Al) 18 mm diameter × 150 μm thick BK10 glass substrate mounted to a 40-segment piezoelectric actuator, enabling Zernike compensation up to 4th order, with a peak-to-valley stroke up to ±17.6 μm. In the modified variant described here, the metal coating is replaced with a high-reflectivity (~99.998%) and low-stress (compressive, ~130 MPa) monocrystalline GaAs/AlGaAs Bragg stack transferred to the thin glass substrate via direct bonding. While maintaining similar physical performance, this custom system exhibits a substantial enhancement in power handling, with laser-induced damage tests (performed by Spica Technologies, Inc.) yielding a continuous-wave damage threshold of 75 MW/cm2 at 1070 nm with a 1/e2 spot diameter of 32.8 μm.

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Laser Damage

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