[1] Song Feng, Liu Shujing, Yan Boxia. Laser cleaning-a novel cleaning method[J]. Cleaning World, 2004, 20(5): 43-48.

[2] Ye Yayun, Qi Yang, Yuan Xiaodong, et al.. Laser cleaning of the contamination on the surface of sandstones and optics[J]. Chinese J Laser, 2012, 39(S1): S103006.

[3] Ye Yayun, Qi Yang, Qin Lang, et al.. Laser cleaning of contaminations on the surface of stone relics[J]. Chinese J Lasers, 2013(9): 0903005.

[4] Lu Y, Song W, Hong M, et al.. Theoretical modeling for laser cleaning of micro-particles from solid surface[C]. MRS Proceedings, 1997: 399.

[5] Watkins K G. Mechanisms of laser cleaning[C]. Roceeding of OPIE High-Power Lasers in Manufacturing, 2000, 3888: 165-174.

[6] Lee K C, Lin J. Transient deformation of thin metal sheets during pulsed laser forming[J]. Optics & Laser Technology, 2002, 34(8): 639-648.

[7] Bloisi F, Blasio G D, Vicari L, et al.. One-dimensional modelling of‘verso’laser cleaning[J]. Journal of Modern Optics, 2006, 53(8): 1121-1129.

[8] Kim D, Oh B, Jang D, et al.. Experimental and theoretical analysis of the laser shock cleaning process for nanoscale particle removal [J]. Applied Surface Science, 2007, 253(19): 8322-8327.

[9] Arnold N. Theoretical description of dry laser cleaning[J]. Applied Surface Science, 2003, 208: 15-22.

[10] Autric M, Oltr R. Basic processes of pulsed laser materials interaction: Applications to laser cleaning of oxidized surfaces[C]. Proceeding of SPIE Xv International Symposium on Gas Flow, Chemical Lasers, and High-Power Lasers, 2005, 5777: 982-985.

[11] Brygo, F, Semerok A, Oltra R, et al.. Laser heating and ablation at high repetition rate in thermal confinement regime[J]. Applied Surface Science, 2006, 252(23): 8314-8318.

[12] Coutouly J F, Deprez P, Breaban F, et al.. Optimisation of a paint coating ablation process by CO2 TEA laser: Thermal field modelling and real-time monitoring of the process[J]. Journal of Materials Processing Technology, 2009, 209(17): 5730-5735.

[13] Shi S D, Li W, Du P, et al.. Removing paint from a metal substrate using a flattened top laser[J]. Chinese Physics B, 2012, 21(10): 104209.

[14] Zou W F, Xie Y M, Xiao X, et al.. Application of thermal stress model to paint removal by Q-switched Nd∶YAG laser[J]. Chinese Physics B, 2014, 23(7): 074205.

[15] Vatry A, Marchand A, Delaporte P, et al.. Tokamak-like dust removal induced by laser irradiation[J]. Journal of Nuclear Materials, 2011, 415(1): S1115-S1118.

[16] Vatry A, Marchand A, Delaporte P, et al.. Studies of laser-induced removal mechanisms for tokamak-like particles[J]. Applied Surface Science, 2011, 257(12): 5384-5388.

[17] Tull B R, Carey J E, Sheehy M A, et al.. Formation of silicon nanoparticles and web-like aggregates by femtosecond laser ablation in a background gas[J]. Applied Physics A, 2006, 83(3): 341-346.

[18] Glover T E, Ackerman G D, Lee R W, et al.. Metal-insulator transitions in an expanding metallic fluid: Particle formation during femtosecond laser ablation[J]. Chemical Physics, 2004, 299(2-3): 171-181.

[19] Wang Zemin, Zeng Xiaoyan, Huang Weiling. Parameters and mechanisms of laser cleaning rubber layer on a tyre mould[J]. Chinese J Lasers, 2000, 27(11): 1050-1054.

[20] Liu K, Garmire E. Paint removal using lasers[J]. Applied Optics, 1995, 34(21): 4409-4415.

[21] Shi Shudong, Du Peng, Li Wei, et al.. Research on paint removal with 1064 nm quasi-continuous-wave laser[J]. Chinese J Lasers, 2012, 39(9): 0903001.

[22] Zhang Heng, Liu Weiwei, Dong Yazhou, et al.. Experimental and mechanism researchon paint removal with low frequency YAG pulsed laser[J]. Laser & Optoelectronics Progress, 2013, 50(12): 121401.

[23] Dolgaev S, Simakin A, Voronov V, et al.. Nanoparticles produced by laser ablation of solids in liquid environment[J]. Applied Surface Science, 2002, 186(1): 546-551.

[24] Rosa G, Psyllaki P, Oltra R, et al.. Simultaneous laser generation and laser ultrasonic detection of the mechanical breakdown of a coating-substrate interface[J]. Ultrasonics, 2001, 39(5): 355-365.

[25] Wang H, Qian M L, Liu W. Laser ultrasonic characterization of adhesive bonds between epoxy coating and aluminum substrate[J]. Ultrasonics, 2006, 44: e1349-e1353.

[26] Reader J, Corliss C H, Wiese W L, et al.. Wavelengths and transition probabilities for atoms and atomic ions: Part 1. Wavelengths, part 2. Transition probabilities[J]. NSRDS-NBS, 1980, 68: 1.