High Power Laser and Particle Beams, Volume. 34, Issue 12, 121004(2022)
Influence mechanism of atmosphere on the damage threshold induced by ultraviolet laser in vacuum window
References(17)
[1] Spaeth M L, Manes K R, Kalantar D H, et al. Description of the NIF Laser[J]. Fusion Science and Technology, 69, 25-145(2016).
[2] [2] Carr C W, Bude J, Miller P E, et al. Damage sources f the NIF Grating Debris Shield (GDS) methods f their mitigation[C]Proceedings of SPIE 10447, LaserInduced Damage in Optical Materials 2017. 2017: 1044702.
[3] [3] Liao Z M, Carr C W, Cross D, et al. Damage perfmance of fused silica debris shield at the National Ignition Facility[C]Proceedings of SPIE 11173, Laserinduced Damage in Optical Materials 2019. 2019: 111730Y.
[4] Chai Xiangxu, Li Ping, Zhao Junpu, et al. Laser-induced damage growth of large-aperture fused silica optics under high-fluence 351 nm laser irradiation[J]. Optik, 226, 165549(2021).
[5] Gingreau C, Lanternier T, Lamaignère L, et al. Impact of mechanical stress induced in silica vacuum windows on laser-induced damage[J]. Optics Letters, 43, 1706-1709(2018).
[6] Xu Shizhen, Zheng Wanguo, Sun Jiuxun, . Effect of gas atmosphere and pressure on 351 nm laser-induced damage threshold of fused silica[J]. High Power Laser and Particle Beams, 20, 1649-1652(2008).
[7] Demos S G, Burnham A, Wegner P, et al. Surface defect generation in optical materials under high fluence laser irradiation in vacuum[J]. Electronics Letters, 36, 566-567(2000).
[8] Huang Jin, Zhou Xinda, Zhou Xiaoyan, . Oxygen-deficiency of fused silica surfaces induced by ultra violet pulsed laser irradiation in high vacuum[J]. Chinese Journal of Vacuum Science and Technology, 34, 1393-1398(2014).
[9] Xia Li, Li Wei. Review of outgassing rate of the cryogenics-vessel material in vacuum[J]. Refrigeration and Air Conditioning, 30, 595-598(2016).
[10] Miao Xinxiang, Yuan Xiaodong, Lü Haibing, . Experimental study of laser-induced damage of optical components surface owing to particle contamination in high power laser facility[J]. Chinese Journal of Lasers, 42, 0602001(2015).
[11] Liu Taixiang, Yang Ke, Zhang Zhuo, et al. Hydrofluoric acid-based etching effect on surface pit, crack, and scratch and laser damage site of fused silica optics[J]. Optics Express, 27, 10705-10728(2019).
[12] Miao Xinxiang, Yuan Xiaodong, Lü Haibing. Contamination particles sensor based on microfiber[J]. High Power Laser and Particle Beams, 26, 114103(2014).
[13] Bude J, Miller P, Baxamusa S, et al. High fluence laser damage precursors and their mitigation in fused silica[J]. Optics Express, 22, 5839-5851(2014).
[14] Yu Hongwei, Zhang Rui, Rong Yuan, . Structure and thermal stability of fluororubber[J]. Special Purpose Rubber Products, 41, 59-64(2020).
[15] [15] Liu Yukui, Yang Jianbin, Xiao Xiangzheng. Design of vacuum engineering[M]. Beijing: Chemical Industry Press, 2016
[16] Boling N L, Crisp M D, Dubé G. Laser induced surface damage[J]. Applied Optics, 12, 650-660(1973).
[17] [17] Feng Yan, Dong Meng, Cheng Yongjun. Investigation of outgassing acteristic f synthetic rubber materials[C]Proceedings of 2014 Academic Annual Meeting of the Chinese Vacuum Society. 2014: 129134
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Xiangxu Chai, Guanzhong Wang, Xiaolin Tian, Liquan Wang, Ye Tian, Yukun Jing, Fa Zeng, Song Zhou, Yuanbin Chen. Influence mechanism of atmosphere on the damage threshold induced by ultraviolet laser in vacuum window[J]. High Power Laser and Particle Beams, 2022, 34(12): 121004
Paper Information
Category: High Power Laser Physics and Technology
Received: Apr. 23, 2022
Accepted: Aug. 19, 2022
Published Online: Nov. 10, 2022
The Author Email: Wang Liquan (wanglq1013@caep.cn)
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