[1] [1] Kong Dejun, Zhou Chaozheng, Wu Yongzhong. Mechanism on residual stress of 304 stainless steel by laser shock processing[J]. Infrared and Laser Engineering, 2010, 39(4): 736-740. (in Chinese)

[2] [2] Zhang X Q, Li H, Yu X L, et al. Investigation on effect of laser shock processing on fatigue crack initiation and its growth in aluminum alloy plate[J]. Materials and Design, 2015, 65: 425-431.

[3] [3] Hu Yongxiang, Yao Zhenqiang, Hu Jun. Numerical simulation of residual stress field for laser shock processing[J]. Chinese J Lasers, 2006, 33(6): 846-851. (in Chinese)

[4] [4] Kim J H, Kim Y J, Kim J S. Effects of simulation parameters on residual stresses for laser shock peening finite element analysis[J]. Journal of Mechanical Science and Technology, 2013, 27(7): 2025-2034.

[5] [5] Warren A W, Guo B Y, Chen S C. Massive parallel laser shock peening: Simulation, analysis, and validation[J]. International Journal of Fatigue, 2008, 30(1): 188-197.

[6] [6] Luo K Y, Lin T, Dai F Z, et al. Effects of overlapping rate on the uniformities of surface profile of LY2 Al alloy during massive laser shock peening impacts[J]. Surface & Coatings Technology, 2015, 266: 49-56.

[7] [7] Zhang X Q, Chen L S, Li S Z, et al. Investigation of the fatigue life of pre-and post-drilling hole in dog-bone specimen subjected to laser shot peening[J]. Material and Design, 2015, 88: 106-114.

[8] [8] Li Jing, Li Jun, He Weifeng, et al. Microstructure and mechanical properties of TC17 titanium alloy by laser shock peening with different impacts[J]. Infrared and Laser Engineering, 2014, 43(9): 2889-2895. (in Chinese)

[9] [9] Zhang Xingquan, Zuo Lisheng, Yu Xiaoliu, et al. Numerical simulation on attenuation of stress wave in copper target irradiated by intense laser[J]. Infrared and Laser Engineering, 2014, 43(9): 681-686. (in Chinese)

[10] [10] Johnson G R, Cook W H. A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures[C]//7th International Symposium on Ballistics, 1983, 21: 541-547.

[11] [11] Peyre P, Sollier A, Chaieb I, et al. FEM simulation of residual stresses induced by laser peening[J]. The European Physical Journal Applied Physics, 2003, 23(2): 83-88.

[12] [12] Fabbro R, Fournier J, Ballard P, et al. Physical study of laser-produced plasma in confined geometry[J]. J Appl Phys, 1990, 68(2): 775-784.

[13] [13] Hong X, Wang S B, Guo D H, et al. Confining medium and absorptive overlay: Their effects on a laser-induced shock wave[J]. Optics and Lasers in Engineering, 1998, 29(6): 447-455.

[14] [14] Cao Ziwen, Zou Shikun, Che Zhigang. Bending deformation and surface characteristics of 2024 aluminum alloy processed by laser-induced shock wave[J]. Laser & Optoelectronics Progress, 2015, 52(12): 121405. (in Chinese)

[15] [15] Dai Mei, Jin Guangyong, Wang Chao, et al. 100MW high peak power and high beam quality Nd:YAG laser[J]. Infrared and Laser Engineering, 2012, 41(3): 612-616. (in Chinese)

[16] [16] Neila Hfaiedh, Patrice Peyre, Song H B, et al. Finite element analysis of laser shock peening of 2050-T8 aluminum alloy[J]. International Journal of Fatigue, 2015, 70: 480-489.

[17] [17] Wang Min. Principle & Technology of Anti-fatigue Manufacture [M]. Nanjing: Jiangsu Science and Technology Press, 1999: 458-476. (in Chinese)