材料科学
合金
变形(气象学)
微观结构
宏观尺度
冶金
复合材料
激光器
宏
光学
物理
量子力学
计算机科学
程序设计语言
作者
Cheng Chang,Guangrui Yao,Sophie C. Cox,Xiaofeng Zhang,Liyuan Sheng,Min Liu,Weili Cheng,Yang Lu,Xingchen Yan
标识
DOI:10.1016/j.jma.2024.12.018
摘要
• Densification of SLM Mg-RE alloy was affected by laser input from conduction to keyhole mode. • 2 VPSC proves that deformation of SLM Mg-RE alloy was governed by the basal < a > and prismatic < a > slips. • Precipitation hardening is the primary mechanism driving the mechanical improvement of SLM Mg-RE alloy. To clarify the densification behavior, deformation response and strengthening mechanisms of selective laser melted (SLM) Mg-RE alloys, this study systematically investigates a representative WE43 alloy via advanced material characterization techniques. A suitable laser output mode fell into the transition mode, allowing for the fabrication of nearly full-density samples (porosity = 0.85 ± 0.021%) with favorable mechanical properties (yield strength=351 MPa, ultimate tensile strength = 417 MPa, the elongation at break = 6.5% and microhardness = 137.9 ± 6.15 HV 0.1 ) using optimal processing parameters ( P = 80 W, v = 250 mm/s and d = 50 µm). Viscoplastic self-consistent analysis and transmission electron microscopy observations reveal that the plastic deformation response of the SLM Mg-RE alloys is primarily driven by basal < a > and prismatic < a > slips. Starting from a random texture before deformation (maximum multiple of ultimate density, Max. MUD = 3.95), plastic stretching led the grains to align with the Z-axis, finally resulting in a {0001}< 10 1 ¯ 0 > texture orientation after fracture (Max. MUD = 8.755). Main phases of the SLM state are mainly composed of α-Mg, Mg 24 Y 5 and β’-Mg 41 Nd 5 , with an average grain size of only 4.27 µm (about a quarter of that in the extruded state), resulting in a favorable strength-toughness ratio. Except for the nano-β’ phase and semi-coherent Mg 24 Y 5 phase (mismatch = 16.12%) around the grain boundaries, a small amount of nano-ZrO 2 and Y 2 O 3 particles also play a role in dispersion strengthening. The high mechanical properties of the SLM state are chiefly attributed to precipitation hardening (44.41%), solid solution strengthening (34.06%) and grain boundary strengthening (21.53%), with precipitation hardening being predominantly driven by dislocation strengthening (67.77%). High-performance SLM Mg-RE alloy components were manufactured and showcased at TCT Asia 2024, receiving favorable attention. This work underscores the significant application potential of SLM Mg-RE alloys and establishes a strong foundation for advancing their use in the biomedical fields.
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