Tailoring the Texture and Mechanical Properties of Textured-AZ31 Mg Alloy Sheets by Twinning and Recrystallization

doi:10.1007/s40195-022-01441-3

Abstract

Abstract:

In this study, a method of corrugated width limit alignment processes (CWLA) was applied to pre-twin in hot-rolled Mg alloy sheets. The microstructure evolution and mechanical properties of the CWLA sheets were studied. The results demonstrated that the grain orientation was transformed from strong basal texture to RD-rotated texture after CWLA treatment and up to 22.2% of {10-12} tensile twin boundaries were produced in the microstructure. The 60 ± 5° < 10-10 > twin variant pairs were dominant in the twinned microstructure. Two kinds of dynamic recrystallization (DRX) mechanism, i.e., continuous DRX (CDRX) at low-temperature CWLA and the discontinuous DRX (DDRX) at high-temperature condition were observed. After post-annealing, the twin-induced static recrystallization (SRX) and abnormal grain growth were observed in the CWLA samples, and most twin boundaries were retained. After CAWL for 60 min at 300 °C and post annealing, an improvement on plasticity and strength were achieved with 55% increment for uniform elongation (UE) and 10% increment for ultimate tensile strength (UTS).

Key words: Magnesium alloy, Corrugated width limit alignment processes, Tension twinning, Dynamic recrystallization, Mechanical properties

Hui-Hu Lu, You Li, Li Lu, Wang-Gang Zhang, Wei Liang. Tailoring the Texture and Mechanical Properties of Textured-AZ31 Mg Alloy Sheets by Twinning and Recrystallization[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(12): 1983-1995.

Figures/Tables 15

Fig. 1 Schematic diagram of the process of CWLA

Fig. 2 Microstructure and texture of hot-rolled AZ31Mg sheets: a IPF, b twin boundaries distribution, c (0002) PF and d misorientation angle distribution map. Note: The color orientation triangle in the following IPF images is same as that in Fig. 2a

Fig. 3 Microstructure of hot-rolled sheets (a, b, c, and d) before and e, f, g and h after CWLA processing with different reheating conditions: a, e 200 °C?×?60 min, b, f 250 °C?×?60 min, c, g 300 °C?×?30 min, d, h 300 °C?×?60 min

Fig. 4 Texture of AZ31sheets before and after CWLA at various conditions

Fig. 5 a, c, and e Twin boundary and b, d, and f misorientation distribution of samples after CWLA at various conditions: a, b 200 °C?×?60 min, c, d 250 °C?×?60 min, and e, f 300 °C?×?60 min

Fig. 6 a Fraction of twin boundaries and b average grain size of samples before and after CWLA processing at various conditions

Fig. 7 Twining behavior in various basal grains a-c G1, d-f G2, g-i G3, and j-l G4 during the process of CWLA at 300 °C?×?60 mim (selected from Fig. 3h): a, d, g, j IPF maps, corresponding orientations represented in b, e, h, k (0002) PF and c, f, i, l IPF

Fig. 8 Microstructure showing the unDRXed and the DRXed regions in samples after CWLA treatment at 200 °C?×?60 min: a IPF image, and b band contrast map

Fig. 9 Microstructure showing the DRX behavior in samples after CWLA treatment at 300 °C?×?60 min: a optical metallography image, and b IPF image

Fig. 10 Microstructure and texture of CWLA samples after annealing for 30 min at 300 °C: a IPF, b twin boundaries in the microstructure, c PF, and d misorientation angle distribution map

Fig. 11 Coarse and fine grain distribution in the annealed samples

Fig. 12 SRX behavior of coarse grains with deformed microstructure: a IPF, b point-to-origin and point-to-point misorientations map along the black line AB and c {0002} PF

Fig. 13 SRX behavior of tension twinned region with 86.3°?±?5°?<?1-210?>?twin boundaries: a IPF, b point-to-origin and point-to-point misorientations map along the black line CD and c {0002} PF

Fig. 14 SRX behavior of twinned region with 60°?±?5°?<?10-10?>?twin variant boundaries: a IPF, b point-to-origin and point-to-point misorientations map along the black line EF and c {0002} PF

Fig. 15 Engineering stress-strain curves of various processed AZ31 sheets after CWLA processing

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