[1] [1] LU J Z, WU L J, SUN G F, et al. Microstructural response and grain refinement mechanism of commercially pure titanium subjected to multiple laser shock peening impacts［J］. Acta Materialia, 2017, 127: 252-266.

[2] [2] MONTROSS C S, WEI T, YE L, et al. Laser shock processing and its effects on microstructure and properties of metal alloys: A review［J］. International Journal of Fatigue, 2002, 24(10): 1021-1036.

[6] [6] SANCHEZ A G, YOU C, LEERING M, et al. Effects of laser shock peening on the mechanisms of fatigue short crack initiation and propagation of AA7075-T651［J］. International Journal of Fatigue, 2021, 143: 106025.

[7] [7] WANG Z D, SUN G F, LU Y, et al. Microstructural characterization and mechanical behavior of ultrasonic impact peened and laser shock peened AISI 316L stainless steel［J］. Surface and Coatings Technology, 2020, 385: 125403.

[8] [8] HACKEL L, RANKIN J, WALTER M, et al. Preventing stress corrosion cracking of spent nuclear fuel dry storage canisters［J］. Procedia Structural Integrity, 2019, 19: 346-361.

[9] [9] YELLA P, VENKATESWARLU P, BUDDU R K, et al. Laser shock peening studies on SS316LN plate with various sacrificial layers［J］. Applied Surface Science, 2018, 435: 271-280.

[13] [13] GAO Y, YANG W Y, HUANG Z Z, et al. Effects of residual stress and surface roughness on the fatigue life of nickel aluminium bronze alloy under laser shock peening［J］. Engineering Fracture Mechanics, 2021, 244: 107524.

[14] [14] CARALAPATTI V K, NARAYANSWAMY S. Effect of high repetition laser shock peening on biocompatibility and corrosion resistance of magnesium［J］. Optics & Laser Technology, 2017, 88: 75-84.

[18] [18] BRAISTED W, BROCKMAN R. Finite element simulation of laser shock peening［J］. International Journal of Fatigue, 1999, 21(7): 719-724.

[19] [19] FABBRO R, PEYRE P, BERTHE L, et al. Physics and applications of laser-shock processing［J］. Journal of Laser Applications, 1998, 10(6): 265-279.

[20] [20] WANG C, LI K F, HU X Y, et al. Numerical study on laser shock peening of TC4 titanium alloy based on the plate and blade model［J］. Optics & Laser Technology, 2021, 142: 107163.

[21] [21] BOVID S, KATTOURA M, CLAUER A, et al. Pressure amplification and modelization in laser shock peening of Ti-6Al-4V and AA7085 with adhesive-backed opaque overlays［J］. Journal of Materials Processing Technology, 2022, 299: 117381.

[22] [22] WANG C Y, LUO K Y, BU X Y, et al. Laser shock peening-induced surface gradient stress distribution and extension mechanism in corrosion fatigue life of AISI 420 stainless steel［J］. Corrosion Science, 2020, 177: 109027.

[23] [23] PANT B K, SUNDAR R, KUMAR H, et al. Studies towards development of laser peening technology for martensitic stainless steel and titanium alloys for steam turbine applications［J］. Materials Science and Engineering: A, 2013, 587: 352-358.

[24] [24] DING K, YE L. Simulation of multiple laser shock peening of a 35CD4 steel alloy［J］. Journal of Materials Processing Technology, 2006, 178(1/2/3): 162-169.

[25] [25] JOHNSON G R, COOK W H. Fracture characteristics of three metals subjected to various strains, strain rates, temperatures and pressures［J］. Engineering Fracture Mechanics, 1985, 21(1): 31-48.

[26] [26] KHODABAKHSHI F, FARSHIDIANFAR M H, GERLICH A P, et al. Microstructure, strain-rate sensitivity, work hardening, and fracture behavior of laser additive manufactured austenitic and martensitic stainless steel structures［J］. Materials Science and Engineering: A, 2019, 756: 545-561.

[27] [27] LAIN S J, KNOWLES K M, DOORBAR P J, et al. Microstructural characterisation of metallic shot peened and laser shock peened Ti-6Al-4V［J］. Acta Materialia, 2017, 123: 350-361.