[1] [1] J. H. Baek, Y. P. Kim, W. S. Kim et al.. Fracture toughness and fatigue crack growth properties of the base metal and weld metal of a type 304 stainless steel pipeline for LNG transmission［J］. Int. J. Pressure Vessels Piping, 2001, 78(5): 351～357

[2] [2] K. Mukai, K. Hoshino, T. Fujioka. Tensile and fatigue properties of austenitic stainless steels at LNG temperature［J］. Tetsu-to-Hagane, 1979, 65(12): 1756～1765

[3] [3] Lei Yucheng, Feng Lianghou, Zhao Xiaojun. Cavitation erosion behavior of an austenitic stainless steel［J］. J. Jiangsu University (Natural Science Edition), 2006, 27(3): 241～244

[4] [4] G. Bregliozzi, A. Di Schino, S. I. U. Ahmed et al.. Cavitation wear behaviour of austenitic stainless steels with different grain sizes［J］. Wear, 2005, 258(1-4): 503～510

[5] [5] Xu Guifang, Qin Minming, Lei Yucheng et al.. Cavitation erosion resistance of Fe-Cr-Ni-Co overlaying and remelting layer［J］. Chinese J. Material Research, 2011, 25(1): 61～66

[6] [6] L. Zhang, K. Y. Luo, J. Z. Lu et al.. Effects of laser shock processing with different shocked paths on mechanical properties of laser welded ANSI 304 stainless steel joint［J］. Mater. Sci. Engng. A, 2011, 528(13-14): 4652～4657

[7] [7] Ren Xudong, Ruan Liang, Huangfu Yongzhuo et al.. Experimental research of laser shock processing 6061-T651 aluminum alloy during elevated temperature［J］. Chinese J. Lasers, 2012, 39(3): 0303010

[8] [8] L. Zhang, J. Z. Lu, Y. K. Zhang et al.. Effects of different shocked paths on fatigue property of 7050-T7451 aluminum alloy during two-sided laser shock processing［J］. Mater. Des., 2011, 32(2): 480～486

[9] [9] Zhong Junwei, Lu Jinzhong, Luo Kaiyu et al.. Tribological behaviors of laser shock processing AISI 8620 steel［J］. Chinese J. Lasers, 2012, 39(1): 0103001

[10] [10] Ge Maozhong, Zhang Yongkang, Xiang Jianyun. Research on laser shock strengthening and stress corrosion cracking resistance of AZ31B magnesium alloy［J］. Chinese J. Lasers, 2010, 37(11): 2925～2930

[11] [11] Ren Xudong, Zhang Tian, Zhang Yongkang et al.. Improving fatigue properties of 00Cr12 alloy by laser shock processing［J］. Chinese J. Lasers, 2010, 37(8): 2111～2115

[12] [12] Z. Xiaojun, L. A. J. Procopiak, N. C. Souza et al.. Phase transformation during cavitation erosion of a Co stainless steel［J］. Mater. Sci. Engng. A, 2003, 358(1-2): 199～204

[13] [13] Y. G. Zhang, S. Z. Luo, W. Ke. Cavitation erosion-corrosion behaviour of CrMnB stainless steel overlay and 0Cr13Ni5Mo stainless steel in 0.5 M NaCl and 0.5 M HCl solutions［J］. Tribol. Int., 2008, 41(12): 1181～1189

[14] [14] X. Y. Li, Y. G. Yan, L. Ma et al.. Cavitation erosion and corrosion behavior of copper-manganese-aluminum alloy weldment［J］. Mater. Sci. Engng. A, 2004, 382(1-2): 82～89

[15] [15] C. T. Kwok, H. C. Man, F. T. Cheng. Cavitation erosion and damage mechanisms of alloys with duplex structures［J］. Mater. Sci. Engng. A, 1998, 242(1-2): 108～120

[16] [16] A. Krella, A. Czyzniewski. Influence of the substrate hardness on the cavitation erosion resistance of TiN coating［J］. Wear, 2007, 263(1-6): 395～401

[17] [17] Lei Yucheng, Qin Minming, Xu Guifang et al.. Cavitation erosion behavior of Cr-Ni-Co austenite deposited metal［J］. Transactions of the China Welding Institution, 2011, 32(6): 21～24

[18] [18] Lei Yucheng, Li Tao, Qin Minming et al.. Cavitation erosion resistance of Co alloy coating on 304 stainless steel by TIG cladding［J］. Trans. China Weld. Inst., 2011, 32(7): 9～12

[19] [19] Luo Xinming, Ma Hui, Zhang Jingwen et al.. Surface nano-crystallization of austenitic stainless steel induced by laser shocking［J］. Chinese J. Lasers, 2011, 38(6): 0603028