[1] Koldunov M F, Manenkov A A, Pocotilo I L. They of laserinduced damage to optical coatings: inclusioninitiated thermal explosion mechanism[C]Proc of SPIE. 1994, 2114: 469487.

[2] Kozlowski M R, Chow R. The role of defects in laser damage of multilayer coatings[C]Proc of SPIE. 1994, 2114: 640649.

[3] Dijon J, Kaiser N, Schallenberg U B, et al. Influence of substrate cleaning on LIDT of 355 nm HR coatings[C]Proc of SPIE. 1997, 2966: 178186.

[4] Zhang Dawei, Shao Jia, Fan Shuhai, et al. The effects of ion cleaning on the roughness of substrates laser induced damage thresholds of films[C]Optical Interference Coatings. 2004: 345348

[5] Bevis R P, Sheehan L M, Smith D J, et al. The advantages of evapation of Hafnium in a reactive environment to manufacture high damage threshold multilayer coatings by electronbeam deposition[C]Proc of SPIE. 1999, 3738: 318324.

[6] Chow R, Falabella S, Loomis G E. Reactive evapoation of low defect density hafnia[J]. Applied Optics, 32, 5567-5574(1993).

[8] Liu Xiaofeng, Zhao Yuan’an. Characteristics of nodular defect in HfO₂/SiO₂ multilayer optical coatings[J]. Applied Surface Science, 256, 3783-3788(2010).

[9] Dijon J, Poulingue M, Hue J. Thermomechanical model of mirr laser damage at 1.06 μm: I. Nodule ejection[C]Proc of SPIE. 1999, 3578: 387397.

[10] Cheng Xinbin, Wei Zeyong, Zhang Jinlong. Physical insight toward electric field enhancement at nodular defects in optical coatings[J]. Optics Express, 23, 8609-8619(2015).

[11] Poulingue M, Dijon J, Rafin B, et al. Generation of defects with diamond silica particles inside highreflection coatings: influence on the laser damage threshold[C]Proc of SPIE. 1999, 3738: 325336.

[12] Shan Yongguang, He Hongbo, Wei Chaoyang. Geometrical characteristics and damage morphology of nodules grown from artificial seeds in multilayer coating[J]. Applied Optics, 49, 4290-4295(2010).

[13] Cheng Xinbin, Lequime M, Macleod H A, et al. Using monodisperse SiO2 microspheres to study laserinduced damage of nodules in HfO2SiO2 high reflects[C]Proc of SPIE. 2011: 816816.

[14] Defd J F, Kozlowski M R. Modeling of electricfield enhancement at nodular defects in dielectric mirr coatings[C]Proc of SPIE. 1993, 1848: 455472.

[15] Cheng Xinbin, Zhang Jinlong, Ding Tao. 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, 2, e80(2013).

[16] Yee K S. Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media[J]. IEEE Trans Antennas & Propagation, 14, 302-307(1966).

[17] Hue J, Garrec P, Dijon J, et al. Ron1 automatic mapping: a new tool f laser damage testing[C]Proc of SPIE. 1995, 2714: 90101.

[18] Han Jinghua, Li Yaguo, He Changtao. Effects of laser plasma on damage in optical glass induced by pulsed lasers[J]. Optical Engineering, 51, 121809(2012).

[20] Genin F Y, Stolz C J. Mphologies of laserinduced damage in hafniasilica multilayer mirr polarizer coatings[C]Proc of SPIE. 1996, 2870: 439448.

[21] Zhu Meiping, Yi Kui, Li Dawei. Influence of SiO₂ overcoat layer and electric field distribution on laser damage threshold and damage morphology of transport mirror coatings[J]. Optics Communications, 319, 75-79(2014).

[22] Zhao Yuan’an, Gao Weidong, Shao Jianda. Roles of absorbing defects and structural defects in multilayer under single-shot and multi-shot laser radiation[J]. Applied Surface Science, 227, 275-281(2004).

[23] Dijon J, Rafin B, Pelle C, et al. Onehundred Joule per square centimeter 1.06μm mirrs[C]Proc of SPIE. 2000, 3902: 158168.

[24] Cheng Xinbin, Shen Zhengxiang, Jiao Hongfei. Laser damage study of nodules in electron-beam-evaporated HfO₂/SiO₂ high reflectors[J]. Applied Optics, 50, 357-363(2011).

[25] Liu Xiaofeng, Zhao Yuan’an, Gao Yanqi. Investigations on the catastrophic damage in multilayer dielectric films[J]. Applied Optics, 52, 2194-2199(2013).