[1] Gao A, Hang R Q, Bai L et al. Electrochemical surface engineering of titanium-based alloys for biomedical application[J]. Electrochimica Acta, 271, 699-718(2018).

[2] Guo A X Y, Cheng L J, Zhan S et al. Biomedical applications of the powder‐based 3D printed titanium alloys: a review[J]. Journal of Materials Science & Technology, 125, 252-264(2022).

[3] Huang Z Y, Liu H Q, Wang H M et al. Effect of stress ratio on VHCF behavior for a compressor blade titanium alloy[J]. International Journal of Fatigue, 93, 232-237(2016).

[4] Luo S Y, Zhu D H, Hua L et al. Numerical analysis of die wear characteristics in hot forging of titanium alloy turbine blade[J]. International Journal of Mechanical Sciences, 123, 260-270(2017).

[5] Ali M M, Colvenkar S, Omer N S et al. Prosthodontic management with a metal denture engraved with laser QR code[J]. Cureus, 15, e34483(2023).

[6] Leone C, Bassoli E, Genna S et al. Experimental investigation and optimisation of laser direct part marking of Inconel 718[J]. Optics and Lasers in Engineering, 111, 154-166(2018).

[7] Ahearne E. Engineering the surface for direct part marking (DPM)[J]. CIRP Journal of Manufacturing Science and Technology, 29, 1-10(2020).

[8] Endler I, Höhn M, Herrmann M et al. Aluminum-rich TiAlCN coatings by low pressure CVD[J]. Surface and Coatings Technology, 205, 1307-1312(2010).

[9] Ma J, Yan D Q, Hu J W et al. Reactive HVOF sprayed TiN-matrix composite coating and its corrosion and wear resistance properties[J]. Transactions of Nonferrous Metals Society of China, 23, 1011-1018(2013).

[10] Valente T, Galliano F P. Corrosion resistance properties of reactive plasma-sprayed titanium composite coatings[J]. Surface and Coatings Technology, 127, 86-92(2000).

[11] Zou J, Liu H J, Zhao Y H et al. Study on process parameters for preparing a high-strength Al-Mg-Sc-Zr alloy by laser melting deposition[J]. Laser & Optoelectronics Progress, 60, 0914003(2023).

[12] Mazurkiewicz A, Smolik J, Zbrowski A et al. Innovative technical solutions for evaporation of multilayer coatings by EB-PVD method[J]. Archives of Civil and Mechanical Engineering, 14, 250-254(2014).

[13] Wei R Z, Mao M H, Liang J G et al. Study of the effect of overlap rate on the failure form, microstructure and wear resistance of multilayer laser cladding on grey cast iron surfaces[J]. Tribology International, 194, 109568(2024).

[14] Du Y B, He G H, Zhou Z J et al. Microstructure and properties of 15-5PH coating by laser cladding on 20Cr13 surface[J]. Laser & Optoelectronics Progress, 60, 0914002(2023).

[15] Schüßler P, Damon J, Mühl F et al. Laser surface hardening: a simulative study of tempering mechanisms on hardness and residual stress[J]. Computational Materials Science, 221, 112079(2023).

[16] Hong J, Huang H, Zhang L et al. Laser polishing and simultaneous hardening of the electrical discharge machined Zr-based metallic glass surface[J]. Materials & Design, 237, 112599(2024).

[17] Lee M S, Lee J R, Baek H S et al. Surface hardening and plastic stability of Ti-6Al-4V alloy by cryo-quenching[J]. Materials Science and Engineering: A, 881, 145394(2023).

[18] Zhang H Q, Liu H, Liu Y et al. Research status and analysis of co-based composite coatings prepared by laser cladding[J]. Laser & Optoelectronics Progress, 60, 0900004(2023).

[19] Chen Z L, Wang Z G, Liu J Q et al. Enhancing the tribological properties of TA1 pure titanium by modulating the energy of pulsed laser nitriding[J]. Optics & Laser Technology, 169, 110118(2024).

[20] Gu Y F, Duan X Q, Xu Y W et al. Preparation of ultra-thick, crack-free, titanium nitride coatings using a full-domain power-modulated laser[J]. Journal of Manufacturing Processes, 113, 346-359(2024).

[21] Wang C, Huang H, Wu H X et al. Ultra-low wear of titanium alloy surface under lubricated conditions achieved by laser texturing and simultaneous nitriding[J]. Surface and Coatings Technology, 474, 130083(2023).

[22] Zong X, Wang H M, Tang H B et al. Microstructure evolution and mass transfer behavior during multi-pass laser surface nitriding process on titanium alloy[J]. Surface and Coatings Technology, 466, 129565(2023).

[23] Jangsombatsiri W, Porter J D. Laser direct-part marking of data matrix symbols on carbon steel substrates[J]. Journal of Manufacturing Science and Engineering, 129, 583-591(2007).

[24] Costa L, Lansford K, Rajput D et al. Unique corrosion and wear resistant identification tags via LISI™ laser marking[J]. Surface and Coatings Technology, 203, 1984-1990(2009).

[25] Kamat A M, Copley S M, Segall A E et al. Laser-sustained plasma (LSP) nitriding of titanium: a review[J]. Coatings, 9, 283(2019).

[26] Yu Y Q, Gong J N, Fang X Y et al. Comparison of surface integrity of GH4169 superalloy after high-energy, low-energy, and femtosecond laser shock peening[J]. Vacuum, 208, 111740(2023).

[27] Zhang L, Shao M H, Wang Z W et al. Comparison of tribological properties of nitrided Ti-N modified layer and deposited TiN coatings on TA2 pure titanium[J]. Tribology International, 174, 107712(2022).

[28] Ohtsu N, Saito W, Yamane M. Thickness of titanium nitride layers formed by focused low-power pulsed Nd∶ YAG laser irradiation in nitrogen atmospheres[J]. Surface and Coatings Technology, 244, 57-62(2014).

[29] Zong X, Wang H M, Li J et al. Microstructure characterization and evolution mechanism of titanium during laser surface nitriding[J]. Materials Characterization, 190, 112029(2022).

[30] Hutchings I M, Shipway P[M]. Tribology: friction and wear of engineering materials(2017).

[31] Budinski K G. Tribological properties of titanium alloys[J]. Wear, 151, 203-217(1991).

[32] Henriksen N G, Poulios K, Somers M A J et al. Impact of laser marking on microstructure and fatigue life of medical grade titanium[J]. Materials Science and Engineering: A, 873, 145020(2023).

[33] Colvenkar S, Sv R. Denture marking for forensic identification using laser-marked stainless steel quick response (QR) code[J]. Cureus, 14, e22431(2022).

[34] Awasthi A, Kumar D, Marla D. Understanding the role of oxide layers on color generation and surface characteristics in nanosecond laser color marking of stainless steel[J]. Optics & Laser Technology, 171, 110469(2024).