排序方式: 共有124条查询结果,搜索用时 171 毫秒
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针对溶胶-凝胶技术制的单层SiO2化学膜,在室温下研究氨水-六甲基二硅胺烷(HMDS)气氛的量对膜层改性的影响,并在低真空条件下测试了其抗邻苯二甲酸二丁酯(DBP)污染性能。采用紫外-可见-近红外分光光度计(UV-Vis-NIR)、红外光谱仪和原子力显微镜分析了改性前后化学膜特性的演变。研究结果表明:经过DBP污染后,15~30 mL氨水-HMDS改性后化学膜的峰值透过率为99.8%,较改性前化学膜的峰值透过率提升了3.5%,此时化学膜表现出优异的抗污染特性。但是,随着氨水-HMDS处理量的进一步增多,化学膜的激光损伤阈值由改性前的的24.32 J/cm2降到19.36 J/cm2。本研究有助于优化改性参数,以提高化学膜的抗污染性能,在实际工程应用中具有重要的价值。 相似文献
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Incident laser modulation of a repaired damage site with a rim in fused silica rear subsurface
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Local CO2 laser treatment has proved to be an effective method to prevent the 351-nm laser-induced damage sites in a fused silica surface from exponentially growing, which is responsible for limiting the lifetime of optics in high fluence laser systems. However, the CO2 laser induced ablation crater is often surrounded by a raised rim at the edge, which can also result in the intensification of transmitted ultraviolet light that may damage the downstream optics. In this work, the three-dimensional finite-difference time-domain method is developed to simulate the distribution of electrical field intensity in the vicinity of the CO2 laser mitigated damage site located in the exit subsurface of fused silica. The simulated results show that the repaired damage sites with raised rims cause more notable modulation to the incident laser than those without rims. Specifically, we present a theoretical model of using dimpled patterning to control the rim structure around the edge of repaired damage sites to avoid damage to downstream optics. The calculated results accord well with previous experimental results and the underlying physical mechanism is analysed in detail. 相似文献
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利用光学元件激光损伤测试平台,测试了355 nm皮秒激光辐照下熔石英光学元件的初始损伤及损伤增长情况,并通过荧光检测分析了损伤区缺陷。研究结果表明:皮秒激光较高的峰值功率导致熔石英损伤阈值较低,前表面损伤阈值为3.98 J/cm2,后表面损伤阈值为2.91 J/cm2;前后表面损伤形貌存在较大差异,后表面比前表面损伤程度轻且伴随体内丝状损伤;随脉冲数的增加后表面损伤直径增长缓慢,损伤深度呈线性增长;皮秒激光的动态自聚焦和自散焦导致熔石英体内损伤存在细丝和炸裂点重复的现象;与纳秒激光损伤相比,损伤区缺陷发生明显改变。 相似文献
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以不同比例的重氮盐分别与聚双(N-羟基己氧基咔唑)磷腈(P-1)进行偶合反应,得到了一组以咔唑和对硝基偶氮咔唑为官能团的双功能型光折变聚合物P-2,P-3和P-4,用31 P NMR,1 H NMR,IR,TG,DSC和UV-Vis光谱对该组聚合物进行表征和分析,以325nm的激发波长对P-1,P-2,P-3和P-4进行固体荧光稳态发射光谱的测试。结果表明,该组聚合物具有良好的热稳定性(Td≈300℃)和较低的玻璃化温度(Tg≈30~40℃),P-1具有良好的荧光活性,硝基的引入,导致P-2,P-3和P-4的荧光发生不同程度的猝灭,咔唑与对硝基偶氮咔唑的数量及其空间分布排列的都会对其荧光性能产生影响。 相似文献
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针对短脉冲激光打靶用溅射防护聚合物薄膜做了初步研究。研究了氟化乙丙共聚物(FEP)、全氟烷氧基共聚物和乙烯-四氟乙烯共聚物三种厚度均为25μm的聚合物薄膜的透过率,结果表明FEP薄膜在355nm处光透过率达93%,有望用于激光打靶的溅射防护。进一步对FEP聚合物薄膜的波前畸变、激光损伤阈值进行了研究,结果表明φ80mm的聚合物薄膜在632.8nm处的透射波前畸变的峰谷值(PV值)为波长的1.006倍;在采用输出波长355nm,脉冲宽度9.3ns的Nd:YAG激光为照射光源波长处,薄膜零损伤概率时的最高激光能量密度为10.35J/cm2,100%损伤概率时的最低激光能量密度为11.48J/cm2。 相似文献
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Surface defects,stress evolution,and laser damage enhancement mechanism of fused silica under oxygen-enriched condition
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Wei-Yuan Luo 《中国物理 B》2022,31(5):54214-054214
Oxygen ions (O+) were implanted into fused silica at a fixed fluence of 1×1017 ions/cm2 with different ion energies ranging from 10 keV to 60 keV. The surface roughness, optical properties, mechanical properties and laser damage performance of fused silica were investigated to understand the effect of oxygen ion implantation on laser damage resistance of fused silica. The ion implantation accompanied with sputtering effect can passivate the sub-/surface defects to reduce the surface roughness and improve the surface quality slightly. The implanted oxygen ions can combine with the structural defects (ODCs and E' centers) to reduce the defect densities and compensate the loss of oxygen in fused silica surface under laser irradiation. Furthermore, oxygen ion implantation can reduce the Si-O-Si bond angle and densify the surface structure, thus introducing compressive stress in the surface to strengthen the surface of fused silica. Therefore, the laser induced damage threshold of fused silica increases and the damage growth coefficient decreases when ion energy up to 30 keV. However, at higher ion energy, the sputtering effect is weakened and implantation becomes dominant, which leads to the surface roughness increase slightly. In addition, excessive energy aggravates the breaking of Si-O bonds. At the same time, the density of structural defects increases and the compressive stress decreases. These will degrade the laser laser-damage resistance of fused silica. The results indicate that oxygen ion implantation with appropriate ion energy is helpful to improve the damage resistance capability of fused silica components. 相似文献
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