Influence of ultra-sonic frequency during substrate cleaning on the laser resistance of antireflection coatings

Laser Damage Pub Date : 2019-11-20 DOI:10.1117/12.2536442

T. Gischkat, D. Schachtler, Z. Balogh-Michels, R. Botha, André Mocker, B. Eiermann, Sven Günther

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引用次数: 2

Abstract

Cleaning of substrates prior to optical coating is an important step in the manufacturing of high performance optical components. It is well known that the ultra-sonic frequency used during substrate cleaning has a strong influence on the quality of the cleaning process and the number of remaining particles on the surface. Therefore, we have investigated the influence of ultra-sonic frequency during substrate cleaning on the laser resistance of antireflection coatings. For this purpose, a SiO2 / Ta2O5 AR-coating for a normal angle of incidence at 1064 nm was deposited onto fused silica substrates. Prior to deposition, the substrates were cleaned with cleaning processes. The applied ultra-sonic frequencies were 40, 80, 120 and 500 kHz. After deposition the LIDT was measured using a 1064 nm ns-pulsed laser test bench. It turned out that the different ultra-sonic-cleaning processes have a strong influence on the number of remaining particles on the surface of the cleaned samples. The counted number of particles with sizes greater < 83 nm were between 1320 and 12 particles for the different applied ultra-sonic frequencies. In consequence the different cleaned and AR-coated samples show different laser damage behavior. Nevertheless the measured particle density does not totally explain the differences in laser resistance.

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基材清洗过程中超声波频率对增透涂层抗激光性能的影响

光学镀膜前的基片清洗是制造高性能光学元件的重要步骤。众所周知，基材清洗时使用的超声波频率对清洗过程的质量和表面残留颗粒的数量有很大的影响。因此，我们研究了基材清洗过程中超声波频率对增透涂层抗激光性能的影响。为此，在熔融二氧化硅衬底上沉积了一层法向入射角为1064 nm的SiO2 / Ta2O5 ar涂层。在沉积之前，用清洗工艺清洗衬底。应用的超声波频率分别为40、80、120和500 kHz。沉积后，利用1064 nm脉冲激光试验台测量LIDT。结果表明，不同的超声波清洗工艺对清洗样品表面残留颗粒的数量有很大的影响。在不同的超声波频率下，粒径< 83 nm的粒子数在1320 ~ 12个之间。因此，不同的清洁和ar涂层样品表现出不同的激光损伤行为。然而，测量的粒子密度并不能完全解释激光电阻的差异。

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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