节瘤缺陷平坦化提高高反射膜的激光损伤阈值
谢凌云, 何涛, 张锦龙, 焦宏飞, 马彬, 王占山, 程鑫彬. 节瘤缺陷平坦化提高高反射膜的激光损伤阈值[J]. 强激光与粒子束, 2018, 30(9): 092001.
Xie Lingyun, He Tao, Zhang Jinlong, Jiao Hongfei, Ma Bin, Wang Zhanshan, Cheng Xinbin. Improve the LIDT of high-reflection coatings by planarizing nodular defects[J]. High Power Laser and Particle Beams, 2018, 30(9): 092001.
[1] Bloembergen N. Role of cracks, pores, and absorbing inclusions on laser induced damage threshold at surfaces of transparent dielectrics[J]. Applied Optics, 1973, 12(4):661-664.
[2] Kozlowski M R, Chow R. Role of defects in laser damage of multilayer coatings[C]//Proc of SPIE. 1994, 2114:640-649.
[3] Cheng Xinbin, Ding Tao, He Wenyan, et al. Using engineered nodules to study laser-induced damage in optical thin films with nanosecond pulses[C]//Proc of SPIE. 2011:819002.
[4] 谢凌云,程鑫彬,张锦龙,等.节瘤缺陷激光损伤的研究进展[J].强激光与粒子束, 2016, 28:090201.(Xie Lingyun, Cheng Xinbin, Zhang Jinlong, et al. Research progress of laser-induced damage of nodular defects. High Power Laser and Particle Beams, 2016, 28:090201)
[5] Dijon J, Poulingue M, Hue J. Thermomechanical model of mirror laser damage at 1.06 μm: I. Nodule ejection[C]//Proc of SPIE. 1999, 3578:387-397.
[6] Stolz C J, Feit M D, Pistor T V. Laser intensification by spherical inclusions embedded within multilayer coatings[J]. Applied Optics, 2006, 45(7):1594-1601.
[7] Cheng Xinbin, Zhang Jinlong, Ding Tao, et al. The effect of an electric field on the thermomechanical damage of nodular defects in dielectric multilayer coatings irradiated by nanosecond laser pulses[J]. Light: Science & Applications, 2013, 2(6):e80.
[8] Cheng Xinbin, Tuniyazi A, Wei Zeyong, et al. Physical insight toward electric field enhancement at nodular defects in optical coatings[J]. Optics Express, 2015, 23(7):8609-8619.
[9] Bennett J M. How to clean surfaces[C]//Proc of SPIE. 2004, 5273:195-206.
[10] Rigatti A L. Cleaning process versus laser-damage threshold of coated optical components[C]//Proc of SPIE. 2005, 5647:136-140.
[11] Stolz C J, Sheehan L M, Von Gunten M K, et al. Advantages of evaporation of hafnium in a reactive environment for manufacture of high-damage-threshold multilayer coatings by electron-beam deposition[C]//Proc of SPIE. 1999, 3738:318-324.
[12] Papandrew A B, Stolz C J, Wu Z, et al. Laser conditioning characterization and damage threshold prediction of hafnia/silica multilayer mirrors by photothermal microscopy[C]//Proc of SPIE. 2001, 4347:53-61.
[13] Wolfe J E, Qiu S R, Stolz C J. Fabrication of mitigation pits for improving laser damage resistance in dielectric mirrors by femtosecond laser machining[J]. Applied Optics, 2011, 50:C457-C462.
[14] Stolz C J, Wolfe J E, Adams J J, et al. High laser-resistant multilayer mirrors by nodular defect planarization[J]. Applied Optics, 2014, 53(4):A291-A296.
[15] Stolz C J, Wolfe J E, Mirkarimi P B, et al. Defect insensitive 100 J/cm2 multilayer mirror coating process[C]//Proc of SPIE. 2013:888502.
谢凌云, 何涛, 张锦龙, 焦宏飞, 马彬, 王占山, 程鑫彬. 节瘤缺陷平坦化提高高反射膜的激光损伤阈值[J]. 强激光与粒子束, 2018, 30(9): 092001. Xie Lingyun, He Tao, Zhang Jinlong, Jiao Hongfei, Ma Bin, Wang Zhanshan, Cheng Xinbin. Improve the LIDT of high-reflection coatings by planarizing nodular defects[J]. High Power Laser and Particle Beams, 2018, 30(9): 092001.
PDF全文
