Research on the Microstructural Evolution of Injection Molded AZ91 and Ultralight LAZ561Ca Magnesium Alloys during Solidification and Heat Treatment: Multiscale Characterizations and Multiphase Field Modeling

Te Cheng Su; Si Yuan Hu; Ming Hung Wu; I An Chen; Lee Han Wu; Hao Chuan Huang; Kai Yu Liang

doi:10.4028/p-Ik6gNx

Paper Titles

Application of Bi-Modal Milling Process to Fabricate Harmonic Structure Materials
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Effect of Annealing Process on Microstructures and Mechanical Properties of Cold-Rolled Martensitic Steels for Automotive Structural Parts
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Formulation and Characterization of Stainless Steel-Based Feedstocks for Fused Deposition Modeling: Effects of Binder Composition on Rheology, Printability, Physical, and Mechanical Properties
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Laser Surface Hardening of AISI 431 Martensitic Stainless Steel by Using Different Laser Sources
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Effect of Intercritical Annealing Temperature to Mechanical Performance of Hot-Rolled Medium Manganese Steel
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Research on the Microstructural Evolution of Injection Molded AZ91 and Ultralight LAZ561Ca Magnesium Alloys during Solidification and Heat Treatment: Multiscale Characterizations and Multiphase Field Modeling
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Thermomechanical Rolling of Air-Cooled Thick Nb-Ti-V-Ni High Strength Structural Plate
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Thermodynamics of Bimetallic Joints between Titanium and Tantalum Produced by Laser Powder Bed Fusion
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Fabrication and Bonding Properties of Joints Formed by Transient Liquid Phase Diffusion Bonding Using Electroplated Films
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HomeMaterials Science ForumMaterials Science Forum Vol. 1174Research on the Microstructural Evolution of...

Research on the Microstructural Evolution of Injection Molded AZ91 and Ultralight LAZ561Ca Magnesium Alloys during Solidification and Heat Treatment: Multiscale Characterizations and Multiphase Field Modeling

Abstract:

AZ91 magnesium injection molding is suitable for manufacturing complex-shaped electronic product frames or thin plates. However, the strengthening effect of the Mg₁₇Al₁₂ precipitate in AZ91 is limited, and it tends to dissolve during heat treatment, leading to a lack of particles that can pin grain boundaries and prevent grain growth. To address these challenges, the LAZ561Ca alloy has been developed, offering a reduced density (83% of AZ91), AlLi nanoprecipitates with strong strengthening capabilities, and thermally stable Ca-bearing intermetallics that effectively pin grain boundaries, maintaining a fine-grained structure (~8 μm) even after heat treatment. Experimental results demonstrate that AZ91 undergoes abnormal grain growth after solution treatment at 400°C due to a significant reduction in Zener pinning forces. In contrast, the LAZ561Ca alloy, with stable Al₂Ca precipitates, resists such growth during two-stage heat treatment at 370°C – 400°C. Through the coupling between Thermo-Calc and MICRESS software, multiphase field modeling reasonably reproduced the microstructure evolution during injection molding and heat treatment processes, highlighting its value in establishing digital physical metallurgy models. This study reveals the microstructural mechanisms of magnesium alloys, confirming the critical role of Ca-bearing precipitates in grain growth suppression. It provides a foundation for further optimization of alloy compositions and heat treatment conditions, paving the way for advanced magnesium alloys with enhanced performance in injection molding applications.

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Periodical:

Materials Science Forum (Volume 1174)

Pages:

89-94

DOI:

https://doi.org/10.4028/p-Ik6gNx

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Online since:

January 2026

Authors:

Te Cheng Su*, Si Yuan Hu, Ming Hung Wu, I An Chen, Lee Han Wu, Hao Chuan Huang, Kai Yu Liang

Keywords:

CALPHAD, Electron Microscopy, Heat Treatment, Magnesium Injection Molding, Multiphase Field Method

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