[1] Zhao H, Humbeeck J V, Sohier J et al. Electrochemical polishing of 316L stainless steel slotted tube coronary stents[J]. Journal of Materials Science: Materials in Medicine, 13, 911-916(2002).

[2] D’Andrea D. Additive manufacturing of AISI 316L stainless steel: a review[J]. Metals, 13, 1370(2023).

[3] Yang Q F, Gao S X, Chen P et al. Current research status of additive manufacturing of 316L stainless steel powder for nuclear power[J]. Journal of Netshape Forming Engineering, 15, 209-219(2023).

[4] Svetlizky D, Das M, Zheng B L et al. Directed energy deposition (DED) additive manufacturing: physical characteristics, defects, challenges and applications[J]. Materials Today, 49, 271-295(2021).

[5] Geng J F, Wu L, Guo P F et al. Study on high-frequency narrow pulse electrochemical post-processing behavior of Inconel 718 alloy by laser directed energy deposition[J]. Chinese Journal of Lasers, 51, 1002318(2024).

[6] Piscopo G, Iuliano L. Current research and industrial application of laser powder directed energy deposition[J]. The International Journal of Advanced Manufacturing Technology, 119, 6893-6917(2022).

[7] Liu W J, Zhang K, Wang H R et al. Research status and application progress of laser directed energy deposition technology[J]. Journal of Shenyang University of Technology, 46, 631-645(2024).

[8] Mazumder S, Pantawane M V, Patil S M et al. Thermokinetically driven microstructural evolution in laser-based directed energy-deposited CoCrMo biomedical alloy[J]. Advanced Engineering Materials, 24, 2200352(2022).

[9] Ma Y, Guan Y C. Research and application progress in laser additive manufacturing of heterogeneous metals (invited)[J]. Chinese Journal of Lasers, 51, 1002304(2024).

[10] Saini V K, Narayanan J A, Sinha N et al. Preliminary parametric investigations into macro-laser polishing of laser-directed energy deposition of SS 304L bulk structures[J]. Crystals, 13, 1604(2023).

[11] Zhu H T, Rennie A, Li R F et al. Two-steps electrochemical polishing of laser powder bed fusion 316L stainless steel[J]. Surfaces and Interfaces, 35, 102442(2022).

[12] Kendall T, Bartolo P, Gillen D et al. A review of physical experimental research in jet electrochemical machining[J]. The International Journal of Advanced Manufacturing Technology, 105, 651-667(2019).

[13] Speidel A, Bisterov I, Saxena K K et al. Electrochemical jet manufacturing technology: from fundamentals to application[J]. International Journal of Machine Tools and Manufacture, 180, 103931(2022).

[14] Wu G L, Shen J, Huang Y J et al. Experimental study of laser-assisted jet electrochemical polishing of GH3044 alloy[J]. Chinese Journal of Lasers, 51, 2002207(2024).

[15] Suo W H, Wang Y, Wen J C et al. Mechanism and numerical simulation of abrasive flow polishing for impeller parts[J]. Surface Technology, 52, 287-298(2023).

[16] Mu J R, Sun T T, Leung C L A et al. Application of electrochemical polishing in surface treatment of additively manufactured structures: a review[J]. Progress in Materials Science, 136, 101109(2023).

[17] Kumar P, Dixit P, Chaudhary B et al. Surface finishing of an additively manufactured part using electrochemical jet machining[J]. Materials Today Communications, 35, 105581(2023).

[18] Yang Z Z, Wu G L, Shen J et al. Surface morphological characteristics and mechanisms of laser-assisted electrochemical polishing on Inconel 718 alloy[J]. Optics & Laser Technology, 181, 111591(2025).

[19] Guo P F, Wu L, Lin X et al. Anodic dissolution behavior of the complex microstructure of laser directed energy deposited alloy 718 during electrolyte jet machining in NaCl-ethylene glycol electrolyte[J]. Additive Manufacturing, 73, 103685(2023).

[20] Han W, Fang F Z. Eco-friendly NaCl-based electrolyte for electropolishing 316L stainless steel[J]. Journal of Manufacturing Processes, 58, 1257-1269(2020).

[21] Xu Z X, Zhao Y H, Xie W F et al. Research on defect control and crystal directional growth of DD6 single crystal superalloy prepared using laser directed energy deposition[J]. Chinese Journal of Lasers, 51, 2002305(2024).

[22] Li J Q. Electrochemical anodic dissolution behavior of laser solid formed Ti-6Al-4V alloy[D](2019).

[23] Guo P F. Microstructure and electrochemical anodic behavior of Inconel 718 fabricated by laser solid forming[D](2019).

[24] Trisnanto S R, Wang X L, Brochu M et al. Effects of crystallographic orientation on the corrosion behavior of stainless steel 316L manufactured by laser powder bed fusion[J]. Corrosion Science, 196, 110009(2022).

[25] Guo P F, Lin X, Li J Q et al. Electrochemical behavior of Inconel 718 fabricated by laser solid forming on different sections[J]. Corrosion Science, 132, 79-89(2018).

[26] Yin Y Y, Zhang J H, Ma Y C et al. Electrochemical dissolution behavior of nickel-based Hastelloy X superalloy at low current densities[J]. IEEE Access, 8, 62714-62724(2020).

[27] Liu G, Su Y G, Pi X Y et al. Achieving high strength 316L stainless steel by laser directed energy deposition-ultrasonic rolling hybrid process[J]. Materials Science and Engineering: A, 903, 146665(2024).

[28] Saboori A, Aversa A, Bosio F et al. An investigation on the effect of powder recycling on the microstructure and mechanical properties of AISI 316L produced by directed energy deposition[J]. Materials Science and Engineering: A, 766, 138360(2019).

[29] Li W, Soshi M. Modeling analysis of the effect of laser transverse speed on grain morphology during directed energy deposition process[J]. The International Journal of Advanced Manufacturing Technology, 103, 3279-3291(2019).

[30] Chechik L, Boone N A, Stanger L R et al. Variation of texture anisotropy and hardness with build parameters and wall height in directed-energy-deposited 316L steel[J]. Additive Manufacturing, 38, 101806(2021).

[31] Landolt D. Fundamental aspects of electropolishing[J]. Electrochimica Acta, 32, 1-11(1987).