Processing of Dielectric Optical Coatings by Nanosecond and Femtosecond UV Laser Ablation

Laser Chemistry Pub Date : 2008-10-16 DOI:10.1155/2008/623872

J. Ihlemann, J. Békési, J. Klein-Wiele, P. Simon

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引用次数: 5

Abstract

Microprocessing of dielectric optical coatings by UV laser ablation is demonstrated. Excimer laser ablation at deep UV wavelengths (248 nm, 193 nm) is used for the patterning of thin oxide films or layer stacks. The layer removal over extended areas as well as sub-μm-structuring is possible. The ablation of SiO2, Al2O3, HfO2, and Ta2O5 layers and layer systems has been investigated. Due to their optical, chemical, and thermal stability, these inorganic film materials are well suited for optical applications, even if UV-transparency is required. Transparent patterned films of SiO2 are produced by patterning a UV-absorbing precursor SiOx suboxide layer and oxidizing it afterwards to SiO2. In contrast to laser ablation of bulk material, in the case of thin films, the layer-layer or layer-substrate boundaries act as predetermined end points, so that precise depth control and a very smooth surface can be achieved. For large area ablation, nanosecond lasers are well suited; for patterning with submicron resolution, femtosecond excimer lasers are applied. Thus the fabrication of optical elements like dielectric masks, pixelated diffractive elements, and gratings can be accomplished.

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纳秒和飞秒紫外激光烧蚀加工介质光学涂层

介绍了用紫外激光烧蚀技术对介质光学涂层进行微加工的方法。准分子激光烧蚀在深紫外波长(248 nm, 193 nm)是用于图案化薄氧化膜或层堆栈。在扩展区域上的层去除以及亚μm结构是可能的。研究了SiO2、Al2O3、HfO2和Ta2O5层及层系的烧蚀过程。由于其光学、化学和热稳定性，这些无机薄膜材料非常适合光学应用，即使需要紫外线透明度。通过将吸收紫外线的前驱体SiOx亚氧化物层进行图案化，然后将其氧化为SiO2，制备了透明的SiO2图案化薄膜。与激光烧蚀大块材料相反，在薄膜的情况下，层-层或层-衬底边界充当预定的终点，因此可以实现精确的深度控制和非常光滑的表面。对于大面积烧蚀，纳秒激光是非常合适的;对于亚微米分辨率的图形，应用飞秒准分子激光器。因此，可以完成诸如介电掩模、像素化衍射元件和光栅等光学元件的制造。

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 Chemistry

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