[1] Quan S J, Song K X, Zhang B B et al. Effect of heat treatment process on microstructure of Ti80 alloy[J]. Transactions of Materials and Heat Treatment, 39, 44-52(2018).

[2] Zhao Y Q. The new main titanium alloys used for shipbuilding developed in China and their applications[J]. Materials China, 33, 398-404(2014).

[3] Singh V, Singh S R, Chattopadhyay K et al. Surface nanostructuring of Ti-6Al-4V alloy through ultrasonic shot peening[J]. International Journal of Surface Science and Engineering, 11, 23-35(2017).

[4] Ren Z J, Lai F Q, Qu S G et al. Effect of ultrasonic surface rolling on surface layer properties and fretting wear properties of titanium alloy Ti5Al4Mo6V2Nb1Fe[J]. Surface and Coatings Technology, 389, 125612(2020).

[5] Zhang Y S, Wei Q M, Niu H Z et al. Formation of nanocrystalline structure in tantalum by sliding friction treatment[J]. International Journal of Refractory Metals and Hard Materials, 45, 71-75(2014).

[6] Alikhani C S, Miresmaeili R, Aliofkhazraei M. Improvement in tribological behavior of commercial pure titanium (CP-Ti) by surface mechanical attrition treatment (SMAT)[J]. Tribology International, 119, 744-752(2018).

[7] Tong Z P, Ren X D, Ren Y P et al. Effect of laser shock peening on microstructure and hot corrosion of TC11 alloy[J]. Surface and Coatings Technology, 335, 32-40(2018).

[8] Wang J, Li M, Wang J X et al. Effects of laser shock processing on fatigue life of 304 stainless steel[J]. Chinese Journal of Lasers, 46, 0102003(2019).

[9] Ning C Y, Huang Y H, Zhang G Y et al. Wear resistance and electrochemical properties of 6061 aluminum alloys treated by laser shock peening[J]. Laser & Optoelectronics Progress, 55, 061403(2018).

[10] Chattopadhyay A, Muvvala G, Sarkar S et al. Effect of laser shock peening on microstructural, mechanical and corrosion properties of laser beam welded commercially pure titanium[J]. Optics & Laser Technology, 133, 106527(2021).

[11] Jia W J, Hong Q, Zhao H Z et al. Effect of laser shock peening on the mechanical properties of a near-α titanium alloy[J]. Materials Science and Engineering: A, 606, 354-359(2014).

[12] Lan L, Xin R Y, Jin X Y et al. Effects of laser shock peening on microstructure and properties of Ti-6Al-4V titanium alloy fabricated via selective laser melting[J]. Materials, 13, 3261(2020).

[13] Li J K, Wang S R, Wang G Q et al. Effect of laser shock peening on surface modification and tribological properties of Ti6Al4V titanium alloy bone Plates[J]. Chinese Journal of Laser, 49, 0202010(2022).

[14] Duan H F, Luo K Y, Lu J Z. Friction and wear properties of H62 brass subjected to laser shock peening[J]. Acta Optica Sinica, 38, 1014002(2018).

[15] Jiang Q H, Li S, Zhou C et al. Effects of laser shock peening on the ultra-high cycle fatigue performance of additively manufactured Ti6Al4V alloy[J]. Optics & Laser Technology, 144, 107391(2021).

[16] Wu L J, Luo K Y, Liu Y et al. Effects of laser shock peening on the micro-hardness, tensile properties, and fracture morphologies of CP-Ti alloy at different temperatures[J]. Applied Surface Science, 431, 122-134(2018).

[17] Qiao H C, Zhao J B, Zhang G X et al. Effects of laser shock peening on microstructure and residual stress evolution in Ti-45Al-2Cr-2Nb-0.2B alloy[J]. Surface and Coatings Technology, 276, 145-151(2015).

[18] Huang S, Zhu Y, Guo W et al. Impact toughness and microstructural response of Ti-17 titanium alloy subjected to laser shock peening[J]. Surface and Coatings Technology, 327, 32-41(2017).

[19] Yang X F, Zhang H J, Cui H T et al. Effect of laser shock peening on fretting fatigue life of TC11 titanium alloy[J]. Materials, 13, 4711(2020).

[20] Yang T, Zhou W F, Yang J D et al. Effect of laser shot peening on high temperature property of Ti-6Al-4V titanium alloy[J]. Laser Technology, 41, 526-530(2017).

[21] Su B X, Luo L S, Wang B B et al. Annealed microstructure dependent corrosion behavior of Ti-6Al-3Nb-2Zr-1Mo alloy[J]. Journal of Materials Science & Technology, 62, 234-248(2021).

[22] Pan X L, Xu D W, Tian Z et al. Effect of dynamic recrystallization on texture orientation and grain refinement of Ti6Al4V titanium alloy subjected to laser shock peening[J]. Journal of Alloys and Compounds, 850, 156672(2021).

[23] Kheradmandfard M, Kashani-Bozorg S F, Kang K H et al. Simultaneous grain refinement and nanoscale spinodal decomposition of β phase in Ti-Nb-Ta-Zr alloy induced by ultrasonic mechanical impacts[J]. Journal of Alloys and Compounds, 738, 540-549(2018).

[24] Sundar R, Sudha C, Rai A K et al. Effect of laser shock peening on the microstructure, tensile and heat transport properties of alloy D9[J]. Lasers in Manufacturing and Materials Processing, 7, 259-277(2020).

[25] Fabbro R, Fournier J, Ballard P et al. Physical study of laser-produced plasma in confined geometry[J]. Journal of Applied Physics, 68, 775-784(1990).

[26] Johnson J N, Rohde R W. Dynamic deformation twinning in shock-loaded iron[J]. Journal of Applied Physics, 42, 4171-4182(1971).

[27] Zhou L C, Li Y H, He W F et al. Deforming TC6 titanium alloys at ultrahigh strain rates during multiple laser shock peening[J]. Materials Science and Engineering: A, 578, 181-186(2013).

[28] Huang P[D]. In situ TEM investigation of size and temperature effect on deformation mechanisms in titanium alloys, 11-20(2019).

[29] Zan Y X, Jia W J, Zhao H Z et al. Microstructure evolution of Ti834 alloy subjected to laser shock processing in strengthening layer[J]. Rare Metal Materials and Engineering, 49, 343-348(2020).

[30] Liu Y G, Li M Q, Liu H J. Surface nanocrystallization and gradient structure developed in the bulk TC4 alloy processed by shot peening[J]. Journal of Alloys and Compounds, 685, 186-193(2016).

[31] Jiao Q Y, Han P P, Lu Y et al. Effect of laser shock peening on residual stress and mechanical properties of TA15 titanium alloy[J]. Journal of Plasticity Engineering, 28, 146-152(2021).

[32] Liu Y P, Shi Z J, Zhao Y Z et al. Cut-off value of detail fatigue rated strength of TC4 titanium alloy with compound strengthening treatment by laser shock peening and shot peening[J]. Chinese Journal of Lasers, 47, 0502006(2020).

[33] Wu Y L, Xiong Y, Liu W et al. Effect of supersonic fine particle bombardment on microstructure and fatigue properties of Ti-6.5Al-3.5Mo-1.5Zr-0.3Si titanium alloy at different temperatures[J]. Surface and Coatings Technology, 421, 127473(2021).

[34] Ren X D, Zhang Y K, Yongzhuo H F et al. Effect of laser shock processing on the fatigue crack initiation and propagation of 7050-T7451 aluminum alloy[J]. Materials Science and Engineering: A, 528, 2899-2903(2011).

[35] Ye C, Telang A, Gill A S et al. Gradient nanostructure and residual stresses induced by ultrasonic nano-crystal surface modification in 304 austenitic stainless steel for high strength and high ductility[J]. Materials Science and Engineering: A, 613, 274-288(2014).

[36] Liu H, Yang J J, Zhao X Y et al. Microstructure, mechanical properties and corrosion behaviors of biomedical Ti-Zr-Mo-xMn alloys for dental application[J]. Corrosion Science, 161, 108195(2019).

[37] Trdan U, Grum J. Evaluation of corrosion resistance of AA6082-T651 aluminium alloy after laser shock peening by means of cyclic polarisation and ElS methods[J]. Corrosion Science, 59, 324-333(2012).

[38] Meng K[D]. Study on corrosion behavior of TA31 alloy in hydrochloric acid solution, 20-30(2019).

[39] Deng Z H, Liu Q B, Xu P et al. Corrosion resistance and mechanism of metallic surface processed by square-spot laser shock peening[J]. Journal of Materials Engineering, 46, 140-147(2018).

[40] Li X C, Zhang Y K. Effect of laser shock times on electrochemical performance of AZ31 magnesium alloy[J]. Laser Technology, 39, 466-470(2015).

[41] Yang Y, Zhou W F, Tong Z P et al. Electrochemical corrosion behavior of 5083 aluminum alloy subjected to laser shock peening[J]. Journal of Materials Engineering and Performance, 28, 6081-6091(2019).