[1] Casati R, Lemke J, Vedani M. Microstructure and fracture behavior of 316L austenitic stainless steel produced by selective laser melting[J]. Journal of Materials Science & Technology, 32, 738-744(2016).

[2] DebRoy T, Wei H L, Zuback J S et al. Additive manufacturing of metallic components: process, structure and properties[J]. Progress in Materials Science, 92, 112-224(2018).

[3] Yap C Y, Chua C K, Dong Z L et al. Review of selective laser melting: materials and applications[J]. Applied Physics Reviews, 2, 041101(2015).

[4] Cherry J A, Davies H M, Mehmood S et al. Investigation into the effect of process parameters on microstructural and physical properties of 316L stainless steel parts by selective laser melting[J]. The International Journal of Advanced Manufacturing Technology, 76, 869-879(2015).

[5] Sander J, Hufenbach J, Giebeler L et al. Microstructure, mechanical behavior, and wear properties of FeCrMoVC steel prepared by selective laser melting and casting[J]. Scripta Materialia, 126, 41-44(2017).

[6] Sun Y, Moroz A, Alrbaey K. Sliding wear characteristics and corrosion behaviour of selective laser melted 316L stainless steel[J]. Journal of Materials Engineering and Performance, 23, 518-526(2014).

[7] Kumar S, Kruth J P. Wear performance of SLS/SLM materials[J]. Advanced Engineering Materials, 10, 750-753(2008).

[8] Meng G B, Gu D D, Li C et al. Forming process and properties of TiC/Ti bulk-form nanocomposites prepared by selective laser melting[J]. Chinese Journal of Lasers, 38, 0603024(2011).

[9] Lin H, Yang Y Q, Zhang G Q et al. Tribological performance of medical CoCrMo alloy fabricated by selective laser melting[J]. Acta Optica Sinica, 36, 1114003(2016).

[10] Zhou Y, Duan L C, Wu X L et al. Effect of powder particle size on wear and corrosion resistance of S136 mould steels fabricated by selective laser melting[J]. Laser & Optoelectronics Progress, 55, 101403(2018).

[11] Liu C Y, Cai Z X, Dai Y H et al. Experimental comparison of the flow rate and cooling performance of internal cooling channels fabricated via selective laser melting and conventional drilling process[J]. The International Journal of Advanced Manufacturing Technology, 96, 2757-2767(2018).

[12] Liu C Y, Yan D, Tan J W et al. Development and experimental validation of a hybrid selective laser melting and CNC milling system[J]. Additive Manufacturing, 36, 101550(2020).

[13] Flynn J M, Shokrani A, Newman S T et al. Hybrid additive and subtractive machine tools-research and industrial developments[J]. International Journal of Machine Tools and Manufacture, 101, 79-101(2016).

[14] Cortina M, Arrizubieta J I, Ruiz J E et al. Latest developments in industrial hybrid machine tools that combine additive and subtractive operations[J]. Materials, 11, 2583(2018).

[15] Sun Z J, Tan X P, Tor S B et al. Selective laser melting of stainless steel 316L with low porosity and high build rates[J]. Materials & Design, 104, 197-204(2016).

[16] Simchi A, Pohl H. Effects of laser sintering processing parameters on the microstructure and densification of iron powder[J]. Materials Science and Engineering: A, 359, 119-128(2003).

[17] Cao S, Chen Z E, Lim C V S et al. Defect, microstructure, and mechanical property of Ti-6Al-4V alloy fabricated by high-power selective laser melting[J]. JOM, 69, 2684-2692(2017).

[18] Rombouts M, Kruth J P, Froyen L et al. Fundamentals of selective laser melting of alloyed steel powders[J]. CIRP Annals, 55, 187-192(2006).

[19] Yin J, Hao L, Yang L L et al. Investigation of interaction between vapor plume and spatter during selective laser melting additive manufacturing[J]. Chinese Journal of Lasers, 49, 1402202(2022).

[20] Snow Z, Scime L, Ziabari A et al. Observation of spatter-induced stochastic lack-of-fusion in laser powder bed fusion using in situ process monitoring[J]. Additive Manufacturing, 61, 103298(2023).

[21] Yang Y Y, Gong Y D, Qu S S et al. Additive/subtractive hybrid manufacturing of 316L stainless steel powder: Densification, microhardness and residual stress[J]. Journal of Mechanical Science and Technology, 33, 5797-5807(2019).

[22] Tang C M, Zhao J B, Wang Z G et al. Experimental investigation on the effect of process parameters in additive/subtractive hybrid manufacturing 316L stainless steel[J]. The International Journal of Advanced Manufacturing Technology, 121, 2461-2481(2022).

[23] Sames W J, List F A, Pannala S et al. The metallurgy and processing science of metal additive manufacturing[J]. International Materials Reviews, 61, 315-360(2016).

[24] Huang Y B, Yang S L, Gu J X et al. Microstructure and wear properties of selective laser melting 316L[J]. Materials Chemistry and Physics, 254, 123487(2020).

[25] Wang D, Huang J H, Tan C L et al. Review on effects of cyclic thermal input on microstructure and property of materials in laser additive manufacturing[J]. Acta Metallurgica Sinica, 58, 1221-1235(2022).

[26] Armstrong-Hélouvry B, Dupont P, De Wit C C. A survey of models, analysis tools and compensation methods for the control of machines with friction[J]. Automatica, 30, 1083-1138(1994).

[27] Song J F, Song Y N, Wang W W et al. Prediction and control on the surface roughness of metal powder using selective laser melting[J]. Chinese Journal of Lasers, 49, 0202008(2022).

[28] Mu W H, Chen X H, Zhang Y et al. Surface morphology analysis and roughness prediction of 316L stainless steel by selective laser melting[J]. Laser & Optoelectronics Progress, 59, 0714011(2022).

[29] Wen S, Dong A P, Lu Y L et al. Finite element simulation of the temperature field and residual stress in GH536 superalloy treated by selective laser melting[J]. Acta Metallurgica Sinica, 54, 393-403(2018).

[30] Zhang Y J, Song B, Zhao X et al. Selective laser melting and subtractive hybrid manufacture AISI420 stainless steel: evolution on surface roughness and residual stress[J]. Journal of Mechanical Engineering, 54, 170-178(2018).

[31] Li H, Ramezani M, Li M et al. Effect of process parameters on tribological performance of 316L stainless steel parts fabricated by selective laser melting[J]. Manufacturing Letters, 16, 36-39(2018).

[32] Zhu Y, Zou J, Chen X et al. Tribology of selective laser melting processed parts: stainless steel 316L under lubricated conditions[J]. Wear, 350/351, 46-55(2016).

[33] Lanzutti A, Marin E, Tamura K et al. High temperature study of the evolution of the tribolayer in additively manufactured AISI 316L steel[J]. Additive Manufacturing, 34, 101258(2020).

[34] Li H, Ramezani M, Li M et al. Tribological performance of selective laser melted 316L stainless steel[J]. Tribology International, 128, 121-129(2018).