[1] Gao X, Qiu R, Zhou G R, et al. Effect of subsurface impurities of fused silica on laser induced damage probability[J]. Infrared and Laser Engineering, 46, 0406002(2017).

[2] 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).

[3] Nasiri Z, Fallah H, Hajimahmoodzadeh M, et al. Investigation of the laser induced damage thresholds of all-dielectric and metal-dielectric mirrors for a continuous wave at 10.6 μm[J]. Optical Materials, 114, 110936(2021).

[4] Li C H, Kang X, Luan D, et al. Laser-irradiation-driven formation of oxygen-related defects and performance degradation in fused silica with nanosecond pulsed laser at 355 nm[J]. Optics and Laser Technology, 111, 727-733(2019).

[5] Chen Q, Wang H, Dai R, et al. Correlation between photoluminescence properties of surface defects and laser-induced damage threshold of fused silica[J]. Laser and Particle Beams, 2021, 1-6(2021).

[6] Li Yangliang, Shen Chao, Shao Li, et al. Automatic acquisition of dynamic characteristics of fused silicon particle ejection induced by laser[J]. Infrared and Laser Engineering, 49, 0305003(2020).

[7] [7] Zhu Jingguo, Xu Zhenyuan, Tian Ye, et al. Effect of external stress on laser damage properties of fused silica[JOL]. Chinese Journal of Lasers, [20220716]. http:kns.cnki.kcmsdetail31.1339.TN.20220713.1924.250.html.

[8] Huang Jin, Wang Fengrui, Liu Hongjie, et al. Non-destructive evaluation of UV pulse laser-induced damage performance of fused silica optics[J]. Scientific Reports, 7, 16239(2017).

[9] Cheng J, Yang Z, Wang C, et al. Effect of scratches on the damage characteristics of fused silica optics under extremely-high impact load[J]. International Journal of Mechanical Sciences, 219, 107099(2022).

[10] Zhao Linjie, Cheng Jian, Chen Mingjun, et al. New progress of CO₂ laser processing techniques for fused silica optics[J]. Journal of Mechanical Engineering, 56, 202-218(2020).

[11] Zhang Lijuan, Zhang Chuanchao, Chen Jing, et al. Formation and control of bubbles during the mitigation of laser-induced damage on fused silica surface[J]. Acta Physica Sinica, 67, 016103(2018).

[12] Bude J, Carr C W, Miller P E, et al. Particle damage sources for fused silica optics and their mitigation on high energy laser systems[J]. Optics Express, 25, 11414-11435(2017).

[13] He Yuhang, Li Qiang, Gao Bo, et al. Measurement of the transmission wavefront of a large-aperture aspheric lens based on computer-generated hologram[J]. Laser & Optoelectronics Progress, 56, 021202(2019).

[14] Zhong Bo, Chen Xianhua, Wang Jian, et al. Fabrication and test of high-precision off-axis aspheric lens[J]. Infrared and Laser Engineering, 47, 0718003(2018).

[15] [15] Williams W B. A novel fluescence based method of assessing subsurface damage in optical materials[D]. Nth Carolina: The University of Nth Carolina at lotte, 2009.

[16] Zhang Jianpu, Sun Huanyu, Wang Shiling, et al. Three-dimensional reconstruction technology of subsurface defectsin fused silica optical components[J]. Acta Optica Sinica, 40, 0216001(2020).

[17] Xu Junhai, Zhao Yuanan, Shao Jianda, et al. Absorption and laser induced damage threshold of TiO₂ single films under different process conditions[J]. Chinese Journal of Lasers, 39, 0407001(2012).

[18] Liu Hongjie, Wang Fengrui, Geng Feng, et al. Nondestructive detection of optics subsurface defects by fluorescence image technique[J]. Optics and Precision Engineering, 28, 50-59(2020).

[19] Nayak B K. Experimental and theoretical investigation of CO₂ laser drilling of fused silica[J]. Journal of Laser Micro Nanoengineering, 9, 79-82(2014).

[20] [20] Negres R A, Burke M W, Demange P, et al. Thermal imaging investigation of modified fused silica at surface damage sites f understing the underlying mechanisms of damage growth [C]Proceedings of SPIEThe International Society f Optical Engineering, 2007, 6403: 640306.

[21] Deng M, Song C, Shi F, et al. Layer-by-layer repair of small-scale damage of fused silica based on the magnetorheological method[J]. Micromachines, 12, 1233(2021).