[1] Kolli R P, Devaraj A. A review of metastable beta titanium alloys[J]. Metals, 8, 506(2018).

[2] Cotton J D, Briggs R D, Boyer R R et al. State of the art in beta titanium alloys for airframe applications[J]. JOM, 67, 1281-1303(2015).

[3] Balazic M, Kopac J, Jackson M J et al. Review: titanium and titanium alloy applications in medicine[J]. International Journal of Nano and Biomaterials, 1, 3-34(2007).

[4] Wang X M, Liu W T[M]. Structural design and application of aircraft titanium alloy, 32(2010).

[5] Yang J K, Bao X Y, Zhang J Y et al. A review on design methods and deformation mechanisms at room temperature of metastable β-titanium alloys[J]. Materials Reports, 35, 19170-19180(2021).

[6] Kuroda D, Niinomi M, Morinaga M et al. Design and mechanical properties of new β type titanium alloys for implant materials[J]. Materials Science and Engineering: A, 243, 244-249(1998).

[7] Olakanmi E O. Selective laser sintering/melting (SLS/SLM) of pure Al, Al-Mg, and Al-Si Powders: effect of processing conditions and powder properties[J]. Journal of Materials Processing Technology, 213, 1387-1405(2013).

[8] Zhang X Y, Zhao Y Q, Bai C G[M]. Titanium alloy and its application, 73(2005).

[9] Shao J. Application and development of titanium alloys[J]. Rare Metals and Cemented Carbides, 35, 61-65(2007).

[10] Liu Q M, Zhang Z H, Liu S F et al. Application and development of titanium alloy in aerospace and military hardware[J]. Journal of Iron and Steel Research, 27, 1-4(2015).

[11] An G J. Application and prospect of metal additive manufacturing technology in aerospace[J]. Modern Machinery, 39-43(2019).

[12] Gong S L, Suo H B, Li H X. Development and application of metal additive manufacturing technology in aviation field[J]. Aeronautical Manufacturing Technology, 56, 66-71(2013).

[13] Hu J Y, Liu P, Sun S Y et al. Relation between heat treatment processes and microstructural characteristics of 7075 Al alloy fabricated by SLM[J]. Vacuum, 177, 109404(2020).

[14] Gu D D, Meiners W, Wissenbach K et al. Laser additive manufacturing of metallic components: materials, processes and mechanisms[J]. International Materials Reviews, 57, 133-164(2012).

[15] Zheng B, Zhou Y, Smugeresky J E et al. Thermal behavior and microstructural evolution during laser deposition with laser-engineered net shaping: part I. numerical calculations[J]. Metallurgical and Materials Transactions A, 39, 2228-2236(2008).

[16] Joseph J, Jarvis T, Wu X H et al. Comparative study of the microstructures and mechanical properties of direct laser fabricated and arc-melted AlxCoCrFeNi high entropy alloys[J]. Materials Science and Engineering: A, 633, 184-193(2015).

[17] Zhang W, Chabok A, Kooi B J et al. Additive manufactured high entropy alloys: a review of the microstructure and properties[J]. Materials & Design, 220, 110875(2022).

[18] Montero Sistiaga M, Nardone S, Hautfenne C et al. Effect of heat treatment of 316L stainless steel produced by selective laser melting (SLM)[EB/OL]. http:∥utw10945.utweb.utexas.edu/sites/default/files/2016/041-Sistiaga.pdf

[19] Zhao Y H, He C, Zhao J B et al. Process of Sc/Zr-modified Al-Mg alloy prepared by additive/equivalent composite manufacturing[J]. Acta Optica Sinica, 43, 0716002(2023).

[20] Sun C J, Zhao J B, Zhao Y H et al. Effects of laser melting deposition process parameters on ultrasonic testing accuracy of TA15 titanium alloy[J]. Acta Optica Sinica, 39, 1014002(2019).

[21] Zhao Y H, He C, Zou J et al. Effect of external field on microstructure and properties of Al-Mg-Sc-Zr alloy prepared by laser melting deposition[J]. Acta Optica Sinica, 43, 0214002(2023).

[22] Yao D Z, Liu X H, Wang J et al. Numerical insights on the spreading of practical 316 L stainless steel powder in SLM additive manufacturing[J]. Powder Technology, 390, 197-208(2021).

[23] Agius D, Kourousis K I, Wallbrink C et al. Cyclic plasticity and microstructure of as-built SLM Ti-6Al-4V: the effect of build orientation[J]. Materials Science and Engineering: A, 701, 85-100(2017).

[24] Khorasani A M, Gibson I, Ghaderi A et al. Investigation on the effect of heat treatment and process parameters on the tensile behaviour of SLM Ti-6Al-4V parts[J]. The International Journal of Advanced Manufacturing Technology, 101, 3183-3197(2019).

[25] Cao S, Chu R K, Zhou X G et al. Role of martensite decomposition in tensile properties of selective laser melted Ti-6Al-4V[J]. Journal of Alloys and Compounds, 744, 357-363(2018).

[26] Jiang J J, Ren Z H, Ma Z B et al. Mechanical properties and microstructural evolution of TA15 Ti alloy processed by selective laser melting before and after annealing[J]. Materials Science and Engineering: A, 772, 138742(2020).

[27] Schwab H, Bönisch M, Giebeler L et al. Processing of Ti-5553 with improved mechanical properties via an in situ heat treatment combining selective laser melting and substrate plate heating[J]. Materials & Design, 130, 83-89(2017).

[28] Wang J C, Liu Y J, Qin P et al. Selective laser melting of Ti-35Nb composite from elemental powder mixture: microstructure, mechanical behavior and corrosion behavior[J]. Materials Science and Engineering: A, 760, 214-224(2019).

[29] Wan M P. Study on deformation and microstructure evolution of Ti-1300 alloy at room temperature[D], 105(2015).

[30] Yang P[M]. Electron backscattering diffraction technology and its application, 84-88(2007).

[31] Liu L F, Ding Q Q, Zhong Y et al. Dislocation network in additive manufactured steel breaks strength-ductility trade-off[J]. Materials Today, 21, 354-361(2018).

[32] Gorsse S, Hutchinson C, Gouné M et al. Additive manufacturing of metals: a brief review of the characteristic microstructures and properties of steels, Ti-6Al-4V and high-entropy alloys[J]. Science and Technology of Advanced Materials, 18, 584-610(2017).

[33] Yamanaka K, Kuroda A, Ito M et al. Quantifying the dislocation structures of additively manufactured Ti-6Al-4V alloys using X-ray diffraction line profile analysis[J]. Additive Manufacturing, 37, 101678(2021).

[34] Lin D Y, Xu L Y, Jing H Y et al. Effects of annealing on the structure and mechanical properties of FeCoCrNi high-entropy alloy fabricated via selective laser melting[J]. Additive Manufacturing, 32, 101058(2020).

[35] Deng H, Qiu W B, Chen L Q et al. Microstructure and mechanical property of Ti-5Al-5Mo-5V-3Cr-1Zr alloy fabricated by selective laser melting with a preheated substrate[J]. Advanced Engineering Materials, 23, 2100265(2021).

[36] Qi L C, Qiao X L, Huang L J et al. Effect of cold rolling deformation on the microstructure and properties of Ti-10V-2Fe-3Al alloy[J]. Materials Characterization, 155, 109789(2019).

[37] Ma X K, Li F G, Cao J et al. Strain rate effects on tensile deformation behaviors of Ti-10V-2Fe-3Al alloy undergoing stress-induced martensitic transformation[J]. Materials Science and Engineering: A, 710, 1-9(2018).

[38] Chen Z, Zhong D L, Sun Q et al. Effect of α phase fraction on the dynamic mechanical behavior of a dual-phase metastable β titanium alloy Ti-10V-2Fe-3Al[J]. Materials Science and Engineering: A, 816, 141322(2021).