Zhou, et al.
               Progress of Biodegradable Zinc Alloys and Composites for   Modeling of Grain Structure Evolution during Welding of an
               Biomedical Applications:  Biomechanical  and  Biocorrosion   Aluminum Alloy. Acta Mater, 126:413–25.
               Perspectives. Bioact Mater, 6:836–79.           85.  de Rosa C, Park C, Thomas EL, et al., 2000, Microdomain
           73.  Lee H, Lim CH, Low MJ, et al., 2017, Lasers in Additive   Patterns from Directional Eutectic Solidification and Epitaxy.
               Manufacturing: A Review. Int J Precision Eng Manuf Green   Nature, 405:433–7.
               Technol, 4:307–22.                              86.  Zheng  W,  He Y, Yang  J, et al.,  2019,  Influence  of
               https://doi.org/10.1007/s40684-017-0037-7           Crystallographic  Orientation  of  Epitaxial  Solidification  on
           74.  Chen YZ, Wen P, Voshage M, et al., 2019, Laser Additive   the  Initial  Instability  during  the  Solidification  of  Welding
               Manufacturing of Zn Metal Parts for Biodegradable Implants:   Pool. J Manuf Proc, 38:298–307.
               Effect of Gas Flow on Evaporation and Formation Quality.   87.  Sullivan  EM,  2021,  Influence  of  Reaction  Synthesis
               J Laser Appl, 31:1003.                              Feedstocks  on  Solidification  Defect  Formation  and
               https://doi.org/10.2351/1.5096118                   Microstructure-Property  Relationships in Electron  Beam
           75.  Lu FG, Li XB, Li ZG, et al., 2015, Formation and influence   Freeform Fabrication of Aluminum Metal Matrix Composites.
               mechanism of keyhole-induced porosity in deep-penetration   Illinois: Colorado School of Mines.
               laser  welding based on 3D transient modeling.  Int J Heat   88.  Zhu YY, Tang HB, Li Z, et al., 2019, Solidification Behavior
               Mass Transfer, 90:1143–52.                          and Grain Morphology of Laser  Additive  Manufacturing
               https://doi.org/10.1016/j.ijheatmasstransfer.2015.07.041  Titanium Alloys. J Alloys Compd, 777:712–6.
           76.  Young ZA, Guo Q, Parab ND, et al., 2020, Types of Spatter   89.  Wang X, Zhang C, Cui X, et al., 2021, Novel Gradient
               and their  Features and Formation  Mechanisms in Laser   Alloy  Steel  with  Quasi-Continuous  Ratios  Fabricated  by
               Powder Bed Fusion Additive Manufacturing Process. Addit   SLM: Material Microstructure and Wear Mechanism. Mater
               Manuf, 36:101438.                                   Charact, 174:111020.
               https://doi.org/10.1016/j.addma.2020.101438     90.  Rappaz M, David SA, Vitek JM, et al., 1989, Development
           77.  Wen  P,  Qin  Y,  Chen  Y, et al., 2019, Laser  Additive   of Microstructures  in Fe15Ni15Cr Single  Crystal  Electron
               Manufacturing of Zn Porous Scaffolds: Shielding Gas Flow,   Beam Welds. Metall Trans A, 20:1125–38.
               Surface  Quality  and  Densification.  J  Mater Sci Technol,   91.  Soler R, Evirgen A, Yao M, et al., 2018, Microstructural and
               35:368–76.                                          Mechanical Characterization of an Equiatomic YGdTbDyHo
           78.  Jauer L, Jülich B, Voshage M, et al., 2015, Selective Laser   High Entropy Alloy with Hexagonal Close-Packed Structure.
               Melting of Magnesium Alloys.                        Acta Mater, 156:86–96.
           79.  Yang Y, Yang M, He C, et al., 2021, Rare Earth Improves   92.  Paidar V, Capek J, Ostapovets A, 2018, Secondary Twinning
               Strength and Creep Resistance of Additively Manufactured   in Zinc. Philos Mag Lett, 98:437–45.
               Zn Implants. Compos B Eng, 216:108882.              https://doi.org/10.1080/09500839.2019.1566799
               https://doi.org/10.1016/j.compositesb.2021.108882  93.  Li Y, Shi J, Jahr H, et al., 2021, Improving the Mechanical
           80.  Elmer  JW,  Allen  S M, Eagar  TW,  1989,  Microstructural   Properties of  Additively Manufactured Micro-Architected
               Development during Solidification of Stainless Steel Alloys.   Biodegradable  Metals.  JOM J Miner Metals Mater Soc,
               Metall Trans A, 20:2117–31.                         73:1–11.
           81.  Shuai C, Xue L, Gao C, et al., 2018, Selective  Laser   94.  Liu S,  Yang  W, Shi X, et al.,  2019,  Influence  of  Laser
               Melting of Zn-Ag Alloys for Bone Repair: Microstructure,   Process  Parameters  on  the  Densification,  Microstructure,
               Mechanical  Properties and Degradation Behaviour.  Virtual   and Mechanical Properties of a Selective Laser Melted AZ61
               Phys Prototyp, 13:146–54.                           Magnesium Alloy. J Alloys Compd, 808:151160.
           82.  Qin Y, Wen P, Xia D, et al., 2020, Effect of Grain Structure on   95.  Auer S, Frenkel D, 2001, Suppression of Crystal Nucleation
               the Mechanical Properties and In Vitro Corrosion Behavior of   in Polydisperse Colloids due to Increase of the Surface Free
               Additively Manufactured Pure Zn. Addit Manuf, 33:101134.  Energy. Nature, 413:711–3.
               https://doi.org/10.1016/j.addma.2020.101134     96.  Wei K, Gao M, Zemin W, et al., 2014, Effect of Energy Input
           83.  Gandin R, 1993, Probabilistic modelling  of microstructure   on Formability, Microstructure and Mechanical Properties of
               formation  in  solidification  processes.  Acta  Metall  Mater,   Selective Laser Melted AZ91D Magnesium Alloy. Mater Sci Eng
               41:345–60.                                          A Struct Mater Properties Misrostruct Process, 611:212–22.
           84.  Wei HL, Elmer JW, de Broy  T, 2017,  Three-Dimensional   97.  Azizand MJ, 1982, Model for Solute Redistribution during

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