Microstructure, texture and mechanical properties in an as-cast AZ61 Mg alloy during multi-directional impact forging and subsequent heat treatment

Microstructure, texture and mechanical properties in an as-cast AZ61 Mg alloy during multi-directional impact forging and subsequent heat treatment

Multi-directional impact forging (MDIF) and subsequent heat treatment were applied to an as-cast AZ61 Mg alloy and the microstructure, texture evolution and mechanical properties were systematically investigated. The microstructural evolution during MDIF was classified into twinning-active and dynam...

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Bibliographic Details
Published in:Materials & design Vol. 87; pp. 891 - 900
Main Authors: Jiang, M.G., Yan, H., Chen, R.S.
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-12-2015
Subjects:
Dynamic recrystallization
Forging
Grain boundaries
Grains
Heat treatment
Magnesium alloy
Magnesium base alloys
Mechanical properties
Microstructure
Surface layer
Texture
Twinning
Mechanical properties
Forging
Twinning
Dynamic recrystallization
Texture
Magnesium alloy
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Summary:Multi-directional impact forging (MDIF) and subsequent heat treatment were applied to an as-cast AZ61 Mg alloy and the microstructure, texture evolution and mechanical properties were systematically investigated. The microstructural evolution during MDIF was classified into twinning-active and dynamic recrystallization (DRX)-predominant stages. During the early forging passes, a complicated twinning behavior was observed, including {10–12} primary, {10–12}–{10–12} secondary and {10–12}–{10–12}–{10–12} ternary twins with various twin variants, and even detwinning behavior. With further continuous forging, {10–12} twins disappeared leading to the formation of coarse DRXed grains, and fine DRXed grains began to nucleate at serrated grain boundaries of the coarse DRXed grains due to discontinuous DRX mechanism and progressively consumed the coarse DRXed grains, eventually resulting in a bimodal microstructure. Meanwhile, as-cast random texture turned into a special non-basal texture. After subsequent heat treatment at 400°C for 2h, the coarse eutectic network completely disappeared with fine β-Mg17Al12 particles uniformly locating at grain boundaries and the non-basal texture stayed stable, thereby resulting in a good balance of strength (ultimate tensile strength of 259MPa) and ductility (20.6%). [Display omitted] •A complicated twinning behavior during MDIF was characterized in detail.•Special non-basal texture was obtained after MDIF due to twinning and DRX.•Subsequent heat treatment effectively optimized grain size and β-Mg17Al12 phase.•MDIF and subsequent heat treatment showed a good balance of strength-ductility.
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ISSN:0264-1275
1873-4197
DOI:10.1016/j.matdes.2015.08.052