The Nature of the Defects in Phosphate-Based Glasses Induced by Gamma Radiation

Advances in Glass Science and Technology Pub Date : 2018-06-06 DOI:10.5772/INTECHOPEN.74178

Quanlong He, Pengfei Wang, Min Lu, B. Peng

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引用次数: 4

Abstract

Final optics assembly is one of the most important parts in high energy and large-scale laser systems like US National Ignition Facility and SG III in China. Those final optics assembly are facing some severe tests, like the laser-induced damage caused by 3ω (351 nm) laser irradiation. Meanwhile, the irradiation of gamma ray and X-rays, will also cause the changes of optical properties in the investigated multi-component phos- phate glasses that have potential use in novel color separation optics in high power laser facilities. These changes of optical properties are associated with the defects induced by gamma radiation. In details, some defects contribute to the absorption in the UV region, which will deteriorate their UV performance. However, some of the induced defects can be eliminated by thermal treatment due to the release and capture of the electrons in conduction band. Besides, the doped Fe, Co, B, Ce and Sb will also affect the defect-state in phosphate-based glasses. In details, gamma radiation resistances of the phosphate glass can be greatly improved by CeO 2 and Sb 2 O 3 co-doping, and the introduction of B 2 O 3 reduces the connectivity of phosphate chains and thus increases the concentration of PO 3 -EC and PO 4 -EC defects.

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伽玛辐射致磷酸盐基玻璃缺陷的性质

最终光学组件是美国国家点火装置和中国SG III等高能和大型激光系统的重要组成部分之一。这些最终的光学组件面临着一些严峻的考验，比如由3ω (351nm)激光照射引起的激光损伤。同时，在伽玛射线和x射线的照射下，所研究的多组分php - phate玻璃的光学性质也会发生变化，在高功率激光设备的新型分色光学器件中具有潜在的应用前景。这些光学性质的变化与伽马辐射引起的缺陷有关。具体来说，一些缺陷会导致紫外区的吸收，从而降低其紫外性能。然而，由于导电带中电子的释放和捕获，一些诱导缺陷可以通过热处理消除。此外，Fe、Co、B、Ce和Sb的掺杂也会影响磷酸盐基玻璃的缺陷状态。其中，ceo2和sb2o3共掺杂可显著提高磷酸盐玻璃的抗伽马辐射能力，而b2o3的引入降低了磷酸链的连通性，从而增加了po3 -EC和po4 -EC缺陷的浓度。

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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Advances in Glass Science and Technology

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