Development of high-performance Mg–Zn–Ca–Mn alloy via an extrusion process at relatively low temperature

In general, Mg alloys are difficult to process at low temperature (below 200 °C), due to the limited slip systems. High-temperature deformation easily results in the grain growth, which seriously restricts the improvement of mechanical properties. In this study, we report a subsequent low-temperatur...

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Bibliographic Details
Published in:Journal of alloys and compounds 2020-06, Vol.825, p.153942, Article 153942
Main Authors: Tong, L.B., Chu, J.H., Sun, W.T., Jiang, Z.H., Zou, D.N., Wang, K.S., Kamado, S., Zheng, M.Y.
Format: Article
Language:English
Subjects:
Alloys
Calcium
Deformation effects
Ductility
Dynamic recrystallization
Equal channel angular extrusion
Equal channel angular pressing
Formability
Grain boundaries
Grain growth
Grain refinement
High temperature
Low temperature
Low-temperature extrusion
Magnesium base alloys
Mechanical properties
Mg alloy
Non-basal slip
Slip
Stacking faults
System effectiveness
Texture
Yield strength
Yield stress
Zinc
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Summary:In general, Mg alloys are difficult to process at low temperature (below 200 °C), due to the limited slip systems. High-temperature deformation easily results in the grain growth, which seriously restricts the improvement of mechanical properties. In this study, we report a subsequent low-temperature extrusion technology for ultra-fine grained (UFG) Mg–Zn–Ca–Mn alloys processed through equal channel angular pressing (ECAP), and successfully fabricate the extruded alloy with high yield strength (∼332.8 MPa) and superior ductility (∼17.9%) through grain refinement and texture modification. The initially fine-grained structure in the as-ECAPed alloy is beneficial to improving its low-temperature deformability, because the compatibility stress at grain boundaries can effectively promote the activation of the non-basal slip systems. Although the strength is dramatically increased, the alloy extruded at 100 °C exhibits the poor ductility, which can be ascribed to the dislocation accumulation behavior. With increasing extrusion temperature, the yield strength is remarkably increased at very small expense of ductility, because of the grain refinement, stacking faults, recovery of basal texture and fine secondary phase particles. The dislocations formed during the extrusion can be rapidly annihilated through a dynamic recrystallization process, which contributes to the improved ductility. [Display omitted] •Low-temperature extrusion leads to high strength and excellent ductility.•Ultra-fine grained structure improves low-temperature deformability.•Dislocation annihilation effectively hinders the premature fracture.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2020.153942