[1] 刘新灵, 刘德林, 陶春虎, 等. 航空发动机关键材料断口图谱［M］.北京：国防工业出版社, 2013:348.

[2] 陶春虎, 钟培道, 王仁智, 等.航空发动机转动部件的失效与预防［M］.北京：国防工业出版社, 2000:102-108.

[3] GUJBA A K, MEDRAJ M. Laser peening process and its impact on materials properties in comparison with shot peening and ultrasonic impact peening［J］. Materials, 2014, 7(12):7925-7974.

[4] 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)：1021-1036.

[5] LIM H, KIM P, JEONG H, et al. Enhancement of abrasion and corrosion resistance of duplex stainless steel by laser shock peening［J］. Journal of Materials Processing Technology, 2012, 212(6): 1347-1354.

[6] 李媛, 何卫锋, 聂祥樊, 等.激光冲击TC17钛合金疲劳裂纹扩展试验［J］.中国表面工程, 2017,30(3):40-47.

[7] 聂祥樊, 何卫锋, 王学德, 等. 激光冲击强化对TC17钛合金微观组织和力学性能的影响［J］.稀有金属材料与工程,2014,43(7):1691-1696.

[8] 侯果, 朱颖, 郭伟, 等.激光冲击强化对TC17微观组织和表面硬度的影响［J］.激光技术, 2017,41(1):68-73.

[9] CAO Z W, XU H Y, ZOU S K, et al. Investigation of surface integrity on TC17 titanium alloy treated by square-spot laser shock peening［J］. Chinese Journal of Aeronautics, 2012, 25(4): 650-656.

[10] YANG Y, ZHANG H, QIAO H C. Microstructure characteristics and formation mechanism of TC17 titanium alloy induced by laser shock processing［J］. Journal of Alloys and Compounds, 2017(722):509-516.

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

[12] WEI X L, LINGX. Numerical modeling of residual stress induced by laser shock processing［J］. Applied Surface Science, 2014(301):557-563.

[13] CAO Z W, CHE Z G, ZOUS K, et al. Numerical simulation of residual stress field induced by laser shock processing with square spot［J］. Journal of Shanghai University, 2011(15):553-556.

[14] HU Y X, GONG C M, YAO Z Q, et al.Investigation on the non-homogeneity of residual stress field induced by laser shock peening［J］. Surface & Coatings Technology,2009(203): 3503-3508.

[15] HU Y X, YAO Z Q, WANG F, et al.Study on residual stress of laser shock processing based on numerical simulation and orthogonal experimental design［J］. Surface Engineering, 2007(23):470-478.

[16] KIM J H, KIM Y J, LEE J W, et al.Study on effect of time parameters of laser shock peening on residual stresses using FE simulation［J］. Journal of Mechanical Science and Technology, 2014(28)：1803-1810.

[17] VASU A, HU Y, GRANDHI R V. Differences in plasticity due to curvature in laser peened components［J］. Surface & Coatings Technology, 2013(235):648-656.

[18] 游熙, 聂祥樊, 何卫锋, 等.纳秒脉冲激光冲击诱导冲击波作用下TC17钛合金高应变率本构模型参数辨识［J］.中国激光, 2016,43(8):0802003.

[19] FABBRO R, FOURNIER J, BALLARD P, et al. Physical study of laser‐produced plasma in confined geometry［J］. Journal of Applied Physics, 1990,68(2): 775-784.

[20] CORREA C, DE LARA L R, DAZ M, et al. Effect of advancing direction on fatigue life of 316L stainless steel specimens treated by double-sided laser shock peening［J］. International Journal of Fatigue, 2015(79): 1-9.

[21] PEYRE P, CHAIEB I, BRAHAM C. FEM calculation of residual stresses induced by laser shock processing in stainless steels［J］. Modelling and simulation in materials science and engineering, 2007,15(3): 205.

[22] ZHANG W, YAO Y L. Improvement of Laser Induced Residual Stress Distributions via Shock Waves［C］.Proc. ICALEO’00, Laser Materials Processing. 2000(89): E183-192.

[23] 卢国鑫.激光冲击对高温合金表面形貌、组织与性能的影响［D］.沈阳：中国科学院金属研究所, 2017:35-38.