[1] 花金荣,李莉,向霞,等.熔石英亚表面杂质颗粒附近光场调制的三维模拟［J］.物理学报, 2011, 60:044206.(Hua Jinrong, Li Li, Xiang Xia, et al. Three-dimensional numerical simulation of light field modulation in the vicinity of inclusions in silica subsurface. Acta Physica Sinica, 2011, 60:044206)

[2] Hopper R W, Uhlmann D R. Mechanism of inclusion damage in laser glass［J］. Journal of Applied Physics, 1970, 41(10):4023-4037.

[3] Feit M D, Campbell J H, Faux D, et al. Modeling of laser-induced surface cracks in silica at 355 nm［C］//Proc of SPIE. 1998, 3244:350.

[4] Neauport J, Lamaignere L, Bercegol H. Polishing-induced contamination of fused silica optics and laser induced damage density at 351 nm［J］. Optics Express, 2005, 13(25):10163-10171.

[5] 欧阳升,刘志超,许乔.熔石英表面加工引入金属微粒的三倍频激光损伤机制［J］.强激光与粒子束, 2011, 23(9):2423-2426.(Ouyang Sheng, Liu Zhichao, Xu Qiao. Mechanism of third-harmonic laser-induced damage on fused silica surface with processing-introduced metal absorbers. High Power Laser and Particle Beams, 2011, 23(9):2423-2426)

[6] Stevens-Kalceff M A, Stesmans A, Joe Wong. Defects induced in fused silica by high fluence ultraviolet laser pulses at 355 nm［J］. Applied Physics Letters, 2002, 80(5):757-760.

[7] Gao Xiang, Feng Guoying, Han Jinghua, et al. Investigation of laser-induced damage by various initiators on the subsurface of fused silica［J］. Optics Express, 2012, 20(20):22095-22101.

[8] Kozlowski M R, Carr J, Hutcheon I, et al. Depth profiling of polishing-induced contamination on fused silica surfaces［C］//Proc of SPIE. 1998, 3244:365-375.

[9] 周刚,马彬,焦宏飞,等.1064 nm高反射薄膜激光损伤阈值测量方法［J］.强激光与粒子束, 2011, 23(4):963-968.(Zhou Gang, Ma Bin, Jiao Hongfei, et al. Laser damage threshold measurements of 1064 nm high reflection mirrors. High Power Laser and Particle Beams, 2011, 23(4):963-968)

[10] 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.

[11] Dyan A, Enguehard F, Lallich S, et al. Scaling laws in laser-induced potassium dihydrogen phosphate crystal damage by nanosecond pulses at 3ω［J］. Opt Soc Am B, 2008, 25(6):1087-1095.

[12] Feit M D, Rubenchik A M. Influence of subsurface cracks on laser induced surface damage［C］//Proc of SPIE. 2004, 5273:264-272.

[13] Chan C H. Effective absorption for thermal blooming due to aerosols［J］. Applied Physics Letters, 1975, 26(11):628-630.

[14] Goldenberg H, Tranter C J. Heat flow in an infinite medium heated by a sphere［J］. British Journal of Applied Physics, 1952, 3(1):296-298.

[15] 欧阳升,刘志超,许乔.三倍频熔石英激光损伤的吸收前驱体［J］.应用光学, 2011, 32(6):1257-1262.(Ouyang Sheng, Liu Zhichao, Xu Qiao. Surface damage precursors in triple-frequency fused silica. Journal of Applied Optics, 2011, 32(6):1257-1262)

[16] Hulst H C. Light scattering by small particles［M］. American: Dover Publication, 1981.

[17] Gallais L, Voarino P, Amra C. Optical measurement of size and complex index of laser-damage precursors: the inverse problem［J］. Optical Society of America, 2004, 21(5):1073-1080.

[18] Burnham A K, Runkel M, Demos S G, et al. Effect of vacuum on the occurrence of UV-induced surface photoluminescence, transmission loss, and catastrophic surface damage［C］//Proc of SPIE. 2000, 4134:243-252.