[1] G V Ostrovskaya. Efficiency of optical-to-acoustic energy conversion upon the interaction of a pulsed laser radiation with a liquid: I. Calculation of the efficiency upon acoustooptic interaction[J]. Technical Physics, 2002, 47(10): 1299-1305.

[2] D Breitling, H Schittenhelm, P Berger, et al.. Shadowgraphic and interferometric investigations on NdYAG laser-induced vapor/plasma plumes for different processing wavelengths [C]. SPIE, 2001, 4184: 534-538.

[3] Zong Siguang, Wang Jiangan, Wang Yuhong, et al.. Sound radialization of high power laser induced cavitation bubble[J]. Laser and Infrared, 2008, 38(8): 757-761.

[4] J M H Teichman, R D Glickman, K F Chan, et al.. Plasma bubble formation induced by holmium laser[J]. Urology, 2005, 65(3): 627-628.

[5] He Jie, Liu Xiumei, Lu Jian, et al.. Surface tension effects on the growth and collapse of cavitation bubbles near a rigid boundary[J]. Chinese J Lasers, 2009, 36(2): 342-346.

[6] Zong Siguang, Wang Jiangan. Experiment investigation of acoustics source generated by optical breakdown in viscid liquid[J]. Applied Laser, 2009, 29(1): 29-33.

[7] Li Beibei, Zhang Hongchao, Lu Jian, et al.. Experimental investigation of the effect of ambient pressure on laser-induced bubble dynamics[J]. Optics and Laser Technology, 2011, 43(8): 1499-1503.

[8] Liu Xumei, Liu Xinhua, Hou Youfu, et al.. Effect of temperature on the behaviour of a laser-induced cavitation bubble near a rigid boundary[J]. Lasers in Engineering, 2011, 21(3-4): 181-193.

[9] Li Shengyong, Liu Xiaoran, Wang Jiang′an, et al.. Influence of bubble content on spectrum properties of laser-induced cavitation bubble collapse sound waves in liquid[J]. High Power Laser and Particle Beams, 2012, 24(5): 1067-1070.

[10] Chen Xiao, Xu Rongqing, Shen Zhonghua, et al.. Experimental and theoretical study of the oscillation of a laser-induced bubble[J]. Chinese J Lasers, 2005, 32(3): 331-335.

[11] Zhao Rui, Xu Rongqing, Liang Zhongcheng, et al.. Influence of bubble content on laser-induced cavitation bubble oscillation in glycerol-water mixture[J]. Acta Physica Sinica, 2009, 58(12): 8400-8405.

[12] Liu Xumei, He Jie, Lu Jian, et al.. Nonlinear dynamics of laser-induced bubble near elastic boundaries [C]. SPIE, 2008, 6839: 68391J.

[13] S R Gonzalez-Avila, E Klaseboer, B C Khoo, et al.. Cavitation bubble dynamics in a liquid gap of variable height[J]. J Fluid Mechanics, 2011, 682: 241-260.

[14] Xu Rongqing, Zhao Rui, Shen Zhonghua, et al.. Experimental investigation of the oscillation of a laser-generated cavitation bubble near a solid boundary[J]. Acta Optica Sinica, 2006, 26(4): 571-575.

[15] Zong Siguang, Wang Jiang′an, Wang Huihua. Image measure of characters of cavitation bubble by optical breakdown[J]. Acta Optica Sinica, 2009, 29(8): 2197-2202.

[16] Liu Xiumei, He Jie, Lu Jian, et al.. Effect of surface tension on a liquid-jet produced by the collapse of a laser-induced bubble against a rigid boundary[J]. Optics and Laser Technology, 2009, 41(1): 21-24.

[17] G Kopitkovas, T Lippert, C David, et al.. Surface micromachining of UV transparent materials[J]. Thin Solid Films, 2004, 453-454: 31-35.

[18] I D Sergei, M E Karasev, L A Kulevskii, et al.. Dissolution in a supercritical liquid as a mechanism of laser ablation of sapphire[J]. Quantum Electronics, 2001, 31(7): 593-596.

[19] H Niino, Y Kawaguchi, T Sato, et al.. Surface Microstructuring by Laser-Induced Backside wet Etching[EB/OL]. http://spie.org/x34904.xml.

[20] Zhang Zhaoyang, Zhang Yongkang, Chen Fei, et al.. The Method and Apparatus of Photoelectrochemical 3D Processing by Laser-Induced Cavitation[P]. China Patent, 201010158801.2, 2010-10-13

[21] A Kruusing. Underwater and water-assisted laser processing: Part 1-General features, steam cleaning and shock processing[J]. Optics and Lasers in Engineering, 2004, 41(2): 307-327.

[22] A C Tam, H K Park, C P Grigoropoulos. Laser cleaning of surface contaminants[J]. Applied Surface Science, 1998, 127-129: 721-725.

[23] Y F Lu, W D Song, M H Hong, et al.. Laser surface cleaning and potential applications in disk drive industry[J]. Tribology International, 2000, 33(5-6): 329-335.

[24] Huang Zhigang, Guo Zhongning, Zhang Yongjun, et al.. The Method of Assembly Micro Components Using Laser Induced Cavition[P]. China, 201110173580.0, 2011-12-7.

[25] M -A Park, H -J Jang, F V Sirotkin, et al.. ErYAG laser pulse for small-dose splashback-free microjet transdermal drug delivery[J]. Opt Lett, 2012, 37(18): 3894-3896.

[26] E Yamashita, Y Oka, K Kaneko, et al.. Angioscope visualization in blood vessel using HoYAG laser-induced vapor bubble[C]. SPIE, 2005, 5686: 447-452.

[27] H Ramachandran, A K Dharmadhikari, K Bambardekar, et al.. Optical-tweezer-induced microbubbles as scavengers of carbon nanotubes[J]. Nanotechnology, 2010, 21(24): 245102.

[28] P A Quinto-Su, C Kuss, P R Preiser, et al.. Red blood cell rheology using single controlled laser-induced cavitation bubbles[J]. Labona Chip, 2011, 11(4): 672-678.

[29] Xu Bing, Song Renguo, Tang Puhong, et al.. Preparation of silver nanoparticles colloid by pulsed laser ablation[J]. Chinese J Lasers, 2007, 34(11): 1582-1588.

[30] K Ikova, B Vlckova, P Y Turpin, et al.. Ion-specific effects on laser ablation of silver in aqueous electrolyte solutions[J]. J Phys Chem C, 2008, 112(12): 4435-4443.

[31] P Wagener, J Jakobi, S Barcikowski. Organic nanoparticles generated by combination of laser-fragmentation and ultrasonication in liquid[J]. J Laser Micro/Nanoengineering, 2011, 6(1): 59-63.

[32] X Huang, P A Quinto-Su, S R Gonzalez-Avila, et al.. Controlled manipulation and in situ mechanical measurement of single Co nanowire with a laser-induced cavitation bubble[J]. Nano Letters, 2010, 10(10): 3846-3851.

[33] P A Quinto-Su, X H Huang, S R Gonzalez-Avila, et al.. Manipulation and microrheology of carbon nanotubes with laser-induced cavitation bubbles [J]. Phys Rev Lett, 2010, 104(1): 014501.