[1] [1] K Otsuka, C M Wayman. Shape Memory Materials[M]. Cambridge: Cambridge University Press, 1998. 49-64.

[2] [2] S Shabalovskaya, J Anderegg, J Van Humbeeck. Critical overview of Nitinol surfaces and their modifications for medical applications[J]. Acta Biomater, 2008, 4(3): 447-467.

[3] [3] J Lindemann, C Buque, F Appel. Effect of shot peening on fatigue performance of a lamellar titanium aluminide alloy[J]. Acta Mater, 2006, 54(4): 1155-1164.

[4] [4] H Y Miao, D Demers, S Larose, et al.. Experimental study of shot peening and stress peen forming[J]. J Mater Process Technol, 2010, 210(15): 2089-2102.

[5] [5] C S Montross, T Wei, L Ye, et al.. Laser shock processing and its effects on microstructure and properties of metal alloys: a review[J]. Inter J Fatigue, 2002, 24(10): 1021-1036.

[6] [6] P Peyer, R Fabbro. Laser shock processing: a review of the physics and applications[J]. Optical and Quantum Electronics, 1995, 27(12): 1213-1229.

[7] [7] Li Wei, Li Yinghong, He Weifeng, et al.. Development and application of laser shock processing[J]. Laser & Optoelectronics Progress, 2008, 45(12):15-19.

[8] [8] W W Zhang, Y L Yao. Micro scale laser shock processing of metallic components[J]. Journal of Manufacturing Science and Engineering, 2002, 124(2): 369-378.

[9] [9] Y N Wang, H Q Chen, J W Kysar, et al.. Response of thin films and substrate to micro-scale laser shock peening[J]. Journal of Manufacturing Science and Engineering, 2007, 129(3): 485-496.

[10] [10] Liu Xiaodong, Shang Deguang, Liu Hui, et al.. Study on fatigue property for electroplated copper thin film by pulsed laser shock peening[J]. Journal of Mechanical Strength, 2012, 34(5): 751-756.

[11] [11] Chang Ye, Suslov Suslo, Xueling Fei, et al.. Bimodal nanocrystallization of NiTi shape memory alloy by laser shock peening and post-deformation annealing[J]. Acta Materialia, 2011, 59(19): 7219-7227.

[12] [12] C Eberl, R J Thompson, D S Gianola, et al.. Free Digital Image Correlation and Tracking Functions[OL]. http://www/mathworks.com/matlabcentral/fileexchange/12413.

[13] [13] Lu Jinzhong, Luo Kaiyu, Feng Aixin, et al.. Micro-structural enhancement mechanism of LY2 Aluminum alloy by means of a single laser shock processing[J]. Chinese J Lasers, 2010, 37(10): 2662-2666.

[14] [14] Zhang Lingfeng, Xiong Yi, Zhang Yi, et al.. Microstructure of high manganese steel by laser shock processing[J]. Chinese J Lasers, 2011, 38(6): 0603025.

[15] [15] T C Chu, W F Ranson, M A Sutton, et al.. Applications of digital-image-correlation techniques to experimental mechanics[J]. Exp Mech, 1985, 25(3): 232-244.

[16] [16] M A Sutton, M Q Cheng, W H Peters, et al.. Application of an optimized digital correlation method to planar deformation analysis[J]. Image Vis Comput, 1986, 4(3): 143-150.

[17] [17] H W Schreier. Investigation of Two and Three-Dimensional Image Correlation Techniques with Applications in Experimental Mechanics[M]. Columbia: University of South Carolina, 2003.

[18] [18] Bing Pan, Kemao Qian, Huimin Xie, et al.. Two-dimensional digital image correlation for in-plane displacement and strain measurement: a review[J]. Meas Sci Technol, 2009, 20(6): 062001.

[19] [19] L Berthe, R Fabbro, P Peyre, et al.. Shock waves from a water-confined laser-generated plasma[J]. J Appl Phys, 1997, 82: 2826-2832.

[20] [20] J C F Millett, N K Bourne. The shock-induced mechanical response of the shape memory alloy, NiTi [J]. Materials Science and Engineering: A, 2004, 378(1-2): 138-142.

[21] [21] Yiliang Liao, Chang Ye, Dong Lin, et al.. Deformation induced martensite in NiTi and its shape memory effects generated by low temperature laser shock peening[J]. Journal of Applied Physics, 2012, 112(3): 033515.

[22] [22] Y C Chen, D C Lagoudas. Impact induced phase transformation in shape memory alloys[J]. Journal of the Mechanics and Physics of Solids , 2000, 48: 275-300.

[23] [23] D C Lagoudas, K Ravi-Chandar, K Sarh, et al.. Dynamic loading of polycrystalline shape memory alloy rods[J]. Mechanics of Materials , 2003, 35: 689-716.