[1] Jianhua Sun, 孙建华, Jinlong Liu, 刘金龙, 王庆良, Qingliang Wang. Research status of biomedical porous metal materials fabricated by selective laser melting. Materials Reports, 25, 95-98(2011).

[2] 张国庆, Guoqing Zhang, Jin Li, 李晋, 李俊鑫, Junxin Li. Influence of heat treatment on the performance of selective laser melting manufacturing CoCrMo alloy. Infrared and Laser Engineering, 47, 0104004(2018).

[3] 杨永强, Yongqiang Yang, Changhui Song, 宋长辉, Di Wang, 王迪. Selective laser melting and its applications on personalized medical parts. Journal of Mechanical Engineering, 50, 140-151(2014).

[4] Hui Yan, 严惠, Xiao Wang, 王霄, Huixin Liang, 梁绘昕. Influence of scanning order on residual stress and deformation in laser direct manufacturing of TC4. Infrared and Laser Engineering, 48, 0242002(2019).

[5] 薛军, Jun Xue, Jiantao Feng, 冯建涛, Changzheng Ma, 马长征. Influence of laser shock peening on microstructure and oxidation resistance of laser additive manufactured TC4 titanium alloy. Chinese Optics, 11, 198-205(2018).

[6] 张敏, Min Zhang, 刘畅, Chang Liu, 任博, Bo Ren. Microstructure and mechanical properties of porous Ni alloy fabricated by laser 3D printing. Chinese Optics, 9, 335-341(2016).

[7] 吴伟辉, Weihui Wu, 杨永强, Yongqiang Yang, Guisheng Mao, 毛桂生. Free manufacturing of heterogeneous materials part by selective laser melting. Optics and Precision Engineering, 27, 517-526(2019).

[8] A Barbas, A-S Bonnet, P Lipinski. Development and mechanical characterization of porous titanium bone substitutes. Journal of the Mechanical Behavior of Biomedical Materials, 9, 34-44(2012).

[9] Zifu Li, Chunyu Zhang, Liujun Qi. Selective laser melting bone-compatible pure titanium porous structure. Applied Mechanics & Materials, 423-426, 833-836(2013).

[10] C Simoneau, V Brailovski, P Terriault. Design, manufacture and tensile properties of stochastic porous metallic structures. Mechanics of Materials, 94, 26-37(2016).

[11] 杜道中, Daozhong Du, Tingting Liu, 刘婷婷, Wenhe Liao, 廖文和. Design of monitoring system of melt pool light intensity in selective laser melting. Infrared and Laser Engineering, 46, 1206002(2017).

[12] 柏龙, Long Bo, 熊飞, Fei Xiong, 陈晓红, Xiaohong Chen. Multi-objective structural optimization design of Ti6Al4V lattice structure formed by SLM. Journal of Mechanical Engineering, 54, 156-165(2018).

[13] Weihui Wu, 吴伟辉, 杨永强, Yongqiang Yang, 肖冬明, Dongming Xiao. Pore forming results of controllable ultra-light structured parts by selective laser melting. Optics and Precision Engineering, 25, 1547-1556(2017).

[15] Čapek Jaroslav, Machová Markéta, Fousová Michaela. Highly porous, low elastic modulus 316L stainless steel scaffold prepared by selective laser melting. Materials Science & Engineering C, Materials for Biological Applications, 69, 631-639(2016).

[16] 张国庆, Guoqing Zhang, Yongqiang Yang, 杨永强, Changhui Song, 宋长辉. Study on design and properties of porous CoCrMo alloy structure manufactured by selective laser melting. Chinese Journal of Lasers, 42, 1103003(2015).

[17] 孙全平, Quanping Sun, 梁元凯, Yuankai Liang, Chunmei Feng, 冯春梅. Optimization of selective laser melting forming technology for 316 stainless steel. Hot Working Technology, 45, 65-68(2016).

[18] Ghouse Shaaz, Babu Sarat, Nai Kenneth. The influence of laser parameters, scanning strategies and material on the fatigue strength of a stochastic porous structure. Additive Manufacturing, 22, 290-301(2018).

[19] Ramirez-Cedillo Erick, A Sandoval-Robles Jesús, Ruiz-Huerta Leopoldo. Process planning guidelines in selective laser melting for the manufacturing of stainless steel parts. Procedia Manufacturing, 26, 973-982(2018).

[20] Lna J. Gibson, Michael F Ashby. Cellular Solids: Structure Properties[M]. Cambridge: Cambridge University Press, 1997: 161179.

[21] Karageorgiou Vassilis, Kaplan David. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials, 26, 5474-5491(2005).

[24] Bo Wang, 王勃, 樊瑜波, Yubo Fan, Mengshi Chen, 陈孟诗. Testing of anisotropic modulus and fluid characteristic of chinese femur and tibia. Journal of Biomedical Engineering, 23, 75-78(2016).