Zhou, et al.
               Process Failure Analysis of Thin-Wall Structures Made by   36.  Chen  Y,  Wen  P,  Voshage  M, et al., 2019, Laser  Additive
               Laser Powder Bed Fusion Additive Manufacturing. J Mater   Manufacturing of Zn Metal Parts for Biodegradable Implants:
               Sci Technol, 98:233–43.                             Effect of Gas Flow on Evaporation and Formation Quality.
           25.  Espana  FA,  Balla  VK,  Bose  S, et al., 2010, Design and   J Laser Appl, 31:022304.
               Fabrication  of CoCrMo Alloy  Based  Novel  Structures  for   37.  Meng B, Fu MW, Fu CM, et al., 2015, Multivariable Analysis
               Load Bearing Implants Using Laser Engineered Net Shaping.   of Micro Shearing  Process Customized  for Progressive
               Mater Sci Eng C Mater Biol Appl, 30:50–7.           Forming of Micro-Parts. Int J Mech Sci, 93:191–203.
               https://doi.org/10.1016/j.msec.2009.08.006          https://doi.org/10.1016/j.ijmecsci.2015.01.017
           26.  Vignesh  M,  Kumar  GR,  Sathishkumar  M, et al., 2021,   38.  Bhatt NH, Pati AR, Kumar A, et al., 2017, High Mass Flux
               Development of Biomedical Implants through  Additive   Spray  Cooling  with  Additives  of  Low  Specific  Heat  and
               Manufacturing: A Review. J Mater Eng Perform, 30:4735–44.  Surface  Tension:  A  Novel Process to Enhance  the Heat
               https://doi.org/10.1007/s11665-021-05578-7          Removal Rate. Appl Therm Eng, 120:537–48.
           27.  Kok  Y, Tan  XP, Wang  P,  et  al.,  2018,  Anisotropy  and   39.  Beals J, She Y, Jagdale V, et al., 2020, Structured Powder
               Heterogeneity of Microstructure and Mechanical Properties   Particles  for Feedstock Improvement for Laser Based
               in Metal Additive Manufacturing: A Critical Review. Mater   Additive Manufacturing. Philadelphia, PA: MyScienceWork.
               Des, 139:565–86.                                40.  Gu DD,  Meiners  W,  Wissenbach K,  et al., 2013, Laser
               https://doi.org/10.1016/j.matdes.2017.11.021        Additive Manufacturing of Metallic Components: Materials,
           28.  Singh S, Ramakrishna  S, Singh R, 2017, Material  Issues   Processes and Mechanisms. Int Mater Rev, 57:133–64.
               in Additive  Manufacturing: A  Review.  J  Manuf Processes,   41.  Sing SL, An J, Yeong WY, et al., 2016, Laser and Electron-
               25:185–200.                                         Beam  Powder-Bed  Additive  Manufacturing  of  Metallic
               https://doi.org/10.1016/j.jmapro.2016.11.006        Implants: A  Review  on Processes, Materials  and  Designs.
           29.  Hase T,  Ohtagaki T,  Yamaguchi  M,  et  al.,  2016,  Effect  of   J Orthop Res, 34:369–85.
               Aluminum or Zinc Solute  Addition on Enhancing Impact   42.  Brika SE, Letenneur M, Dion CA, et al., 2020, Influence of
               Fracture Toughness in Mg-Ca Alloys. Acta Mater, 104:283–94.  Particle  Morphology and  Size  Distribution  on the  Powder
           30.  Strano G, Hao L, Everson RM, et al., 2013, A New Approach to   Flowability and Laser Powder Bed Fusion Manufacturability
               the Design and Optimisation of Support Structures in Additive   of Ti-6Al-4V Alloy. Addit Manuf, 31:100929.
               Manufacturing. Int J Adv Manuf Technol, 66:1247–54.     https://doi.org/10.1016/j.addma.2019.100929
               https://doi.org/10.1007/s00170-012-4403-x       43.  Leitz, K.,  -H., et al., 2018, Fundamental  Analysis of the
           31.  Montani M, Demir AG, Mostaed E, et al., 2017, Processability   Influence  of  Powder  Characteristics  in  Selective  Laser
               of Pure Zn and Pure Fe by SLM for Biodegradable Metallic   Melting of molybdenum based on a multi-physical simulation
               Implant Manufacturing. Rapid Prototyp J, 23:514–23.  model. Int J Refract Met Hard Mater, 72:1–8.
               https://doi.org/10.1108/rpj-08-2015-0100        44.  Halada  K, Minagawa  K, Chiba K, et  al.,  2009,  Solidified
           32.  Shuai  C,  Cheng Y, Yang Y, et al., 2019, Laser  Additive   Microstructure of Zn-Al Alloy Powders Produced by Various
               Manufacturing of Zn-2Al Part for Bone Repair: Formability,   Atomization Methods. J Jpn Soc Powder Powder Metallurgy,
               Microstructure and Properties. J Alloys Compd, 798:606–15.  40:1160–5.
           33.  Yang Y, Yuan F, Gao C, et al., 2018, A Combined Strategy to   45.  Tong L, Reddy RG, 2005, Synthesis of  Titanium  Carbide
               Enhance the Properties of Zn by Laser Rapid Solidification   Nano-Powders by Thermal Plasma. Scr Mater, 52:1253–8.
               and Laser Alloying. J Mech Behav Biomed Mater, 82:51–60.  46.  Ruvalcaba  BE,  Arrieta  E, Escarcegaa  AH, et al.,
           34.  Wen  P,  Jauer  L,  Voshage  M, et al.,  2018,  Densification   Manufacturing  Process and Parameters  Development  for
               Behavior of Pure Zn Metal Parts Produced by Selective Laser   Water-atomized  Zinc Powder  for Selective  Laser Melting
               Melting for Manufacturing Biodegradable Implants. J Mater   Fabrication. United States: The University of Texas at Austin.
               Process Technol, 258:128–37.                    47.  Sungkhaphaitoon P, Plookphol T, Wisutmethangoon S, 2012,
               https://doi.org/10.1016/j.jmatprotec.2018.03.007    Design and Development  of a Centrifugal  Atomizer  for
           35.  Qin Y, Wen P, Guo H, et al., 2019, Additive Manufacturing   Producing Zinc Metal Powder. Int J Appl Phys Math, 2:77.
               of Biodegradable Metals: Current Research Status and Future   48.  Wen  P,  Voshage  M,  Jauer  L, et al., 2018, Laser Additive
               Perspectives. Acta Biomat, 98:3–22.                 Manufacturing of Zn Metal Parts for Biodegradable
               https://doi.org/10.1016/j.actbio.2019.04.046        Applications: Processing, Formation Quality and Mechanical

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