Evolution of Microstructure and Mechanical Properties of AZ31 Sheets with Different Initial Microstructures During the Corrugated Wide Limit Alignment Process

doi:10.1007/s40195-025-01844-y

Abstract

Abstract:

Presetting tensile twins (TTs) can enhance the mechanical properties of magnesium (Mg) alloys. Two as-received (AR) sheets, as-received state-A (AR-A) with fiber texture and nonuniform grains and as-received state-B with basal texture and uniform equiaxial grains are selected to induce TTs via a novel method called corrugated wide limit alignment (CWLA), and the corresponding CWLA-processed sheets are denoted as CWLA-processed state-A (C-A) and CWLA-processed state-B (C-B). The results demonstrate that a larger initial average grain size correlates with a higher fraction of TTs induced in Mg sheets, thereby refining the grains and forming a new rolling direction (RD) tilted texture during CWLA. The ultimate tensile strength increases by 32% from AR-A to C-A, primarily due to refinement strengthening and twinning-induced strain hardening. The recrystallization mechanism of C-A is dominated by twinning-induced dynamic recrystallization (DRX), where DRX grains prefer to inherit the orientation of TTs, resulting in an enhanced RD-tilted texture and the formation of multi-modal texture. The recrystallization mechanism of C-B is mainly discontinuous DRX and continuous DRX, and the DRX grains prefer to inherit the orientation of matrix grains, ultimately forming a basal texture. In summary, the tensile mechanical behavior of pre-twinned Mg sheets significantly depends on the grain size and texture of the AR sheets, so they present similar changing trends during tensile deformation.

Key words: Mg sheet, Texture, Grain size, Corrugated wide limit alignment (CWLA), Tensile twin (TT), Dynamic recrystallization (DRX)

Hongyang Zhang, Huihui Nie, Zhijian Li, Hongsheng Chen, Wei Liang, Liuwei Zheng. Evolution of Microstructure and Mechanical Properties of AZ31 Sheets with Different Initial Microstructures During the Corrugated Wide Limit Alignment Process[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(6): 1012-1028.

Figures/Tables 13

Fig. 1 Schematic diagram of CWLA process and grain orientation diagram: a and b bending process, c and d straightening process, e and f grain orientation diagram

Fig. 2 Microstructure diagram of AR-A and AR-B: a and b IPFs, c and d distribution of the varied grains, e and f {0001} PFs. a, c, and e AR-A; b, d, and f AR-B. The OM diagram labeled in Fig. 2a is the metallographic diagram for calculating the average grain size

Fig. 3 Microstructure diagram after CWLA: a and b IPFs, c and d TBs distribution in band contrast images, e and f {0001} PFs. a, c, and e C-A; b, d, and f C-B

Fig. 4 Microstructure diagram after CWLA: a and b KAM maps, c and d Distribution of the varied grains, e and f Misorientation angle distribution maps. a, c, and e C-A; b, d, and f C-B

Fig. 5 Stress-strain curves of four types of Mg sheets: a engineering stress-strain curve, b true stress-strain curve

Table 1 Mechanical properties of each specimen during uniaxial tensile test

Samples	YS (MPa)	UTS (MPa)	EL (%)
AR-A	48	198	17.2
AR-B	120	194	18.1
C-A	58	262	18.4
C-B	182	261	19.1

Fig. 6 SF maps for various slip systems of AR-A and C-A

Fig. 7 SF maps for various slip systems of AR-B and C-B

Fig. 8 DRX behavior of the black ellipse area in Fig. 4d: a IPF, b KAM map, c {0001} PF, d point-to-origin misorientations map along line 1 and line 2

Fig. 9 DRX behavior of the black ellipse area in Fig. 4c: a IPF, b distribution of the varied grains, c part of DDRX grains, d {0001} PF

Fig. 10 Texture evolution diagram of AR-A and AR-B after CWLA process

Fig. 11 Principle diagram of recrystallization of AR-A and AR-B in the CWLA

Fig. 12 Mechanical performance diagram after CWLA: a work hardening rate diagram, b experimental Vickers hardness data diagram

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