[1] [1] Sun Xiaomin, Liu Dong, Tang Haibo, et al. Solid-state phase transformation and microstructure of laser direct manufactured TC17 titanium alloy compounds［J］. Rare Metal Materials and Engineering, 2013, 42(4): 724-729.

[2] [2] Zou Shikun, Gong Shuili, Guo Enming, et al. Laser peening of turbine engine integrally blade rotor［J］. Chinese J Lasers, 2011, 38(6): 0601009.

[3] [3] Gao Yukui. Influence of different surface modification treatments on surface integrity and fatigue performance of TC4 titanium alloy［J］. Acta Metallurgica Sinica, 2016, 52(8): 915-922.

[4] [4] Lu Ying, Zhao Jibin, Qiao Hongchao. Investigation of technology and strengthening mechanism research of TiAl alloy by laser shock processing［J］. Chinese J Lasers, 2014, 41(10): 1003013.

[5] [5] Pant B K, Pavan A H V, Prakash R V, et al. Effect of laser peening and shot peening on fatigue striations during FCGR study of Ti6Al4V［J］. International Journal of Fatigue, 2016, 93: 38-50.

[6] [6] Luo Xinmin, Zhang Jingwen, Zhao Guangzhi, et al. Effect of laser shock strengthening on fatigue behavior of 2A02 aluminium alloy［J］. Chinese J Lasers, 2009, 36(12): 3323-3328.

[7] [7] Zhang Qinglai, Wu Tiedan, Qian Yang, et al. Study on high cycle fatigue properties and high shock processing of AZ91D-T6 cast magnesium alloy［J］. Chinese J Lasers, 2014, 41(10): 1003008.

[8] [8] Nie Xiangfan, He Weifeng, Zang Shunlai, et al. Experimental study on improving high-cycle fatigue performance of TC11 titanium alloy by laser shock peening［J］. Chinese J Lasers, 2013, 40(8): 0803006.

[9] [9] Li Donglin, He Weifeng, You Xi, et al. Experimental research on improving fatigue strength of wounded TC4 titanium alloy by laser shock processing［J］. Chinese J Lasers, 2016, 43(7): 0702006.

[10] [10] Dai F Z, Zhou J Z, Lu J Z, et al. A technique to decrease surface roughness in overlapping laser shock peening［J］. Applied Surface Science, 2016, 370: 501-507.

[11] [11] Liu Y G, Li H M, Li M Q. Characterization of surface layer in TC17 alloy treated by air blast shot peening［J］. Materials and Design, 2015, 65: 120-126.

[12] [12] Wang L, Wang L, Nie Z H, et al. Evolution of residual stress, free volume, and hardness in the laser shock peened Ti-based metallic glass［J］. Materials and Design, 2016, 111: 473-481.

[13] [13] Salimianrizi A, Foroozmehr E, Badrossmay M, et al. Effects of laser shock peening on surface properties and residaul stress of Al6061-T6［J］. Optics and Lasers in Engineering, 2016, 77: 112-117.

[14] [14] Zhou J Z, Huang S, Sheng J, et al. Effect of repeated impacts on mechanical properties and fatigue morphologies of 6061-T6 aluminium subjected to laser peening［J］. Materials Science and Engineering: A, 2012, 539: 360-368.

[15] [15] Liu Xinling, Zhang Zheng, Tao Chunhu. Fatigue fractography quantitative analysis［M］. Beijing: National Defense Industry Press, 2010.

[16] [16] Li Zhen. Investigation of residual stress and fatigue performance of titanium alloy part with hole by laser shock processing［D］. Zhenjiang: Jiangsu University, 2016.

[17] [17] Haddad E, Topper K, Pook L P. Metal fatigue［M］. London: Oxford University Press, 1974: 30-195.

[18] [18] Lü Xuming. Fatigue behavior and LBB assessment of primary circuit piping materials in nuclear power plants［D］. Beijing: University of Science and Technology Beijing, 2015.

[19] [19] Zhang Xue. Fatigue short through thickness crack closure and growth in the residual stress field［J］. Journal of Mechanical Strength, 2000, 22(2): 137-139.

[20] [20] Zhang Dingquan, He Jiawen. X-ray diffraction analysis and effect of residual stress in materials［M］. Xi′an: Xi′an Jiaotong University Press, 1999.