Effect of Hydrostatic Pressure on LPSO Kinking and Microstructure Evolution of Mg-11Gd-4Y-2Zn-0.5Zr Alloy

doi:10.1007/s40195-020-01120-1

Abstract

Abstract:

Two different kinds of hot compressions, namely normal-compression and can-compression, were performed on the Mg-11Gd-4Y-2Zn-0.5Zr alloy, featured with long period stacking ordered (LPSO) phase. The kinking behavior of LPSO phase and microstructure evolution was investigated to clarify the effect of levels of imposed hydrostatic pressure. The results suggest that the LPSO phases including both the intragranular 14H-LPSO phase and intergranular 18R-LPSO phase suffer severe kinking behavior under higher hydrostatic pressure induced by can-compression, which is firstly characterized with more kinking times and smaller relative kinking width. The main reason for such enhanced LPSO kinking during can-compression may be mainly ascribed to the higher dislocation density under a higher level of hydrostatic pressure. Meanwhile, a competitive relationship between the kink behaviors of intergranular 18R-LPSO phase and intragranular 14H-LPSO phase was observed. That is, the intergranular 18R-LPSO phase only kinks obviously on the condition that the surrounded intragranular 14H-LPSO phase scarcely kinks. In contrast to the distinctive kinking of LPSO phase, the dynamic recrystallization (DRX) mechanism shows less dependence on the hydrostatic pressure. Resultantly, similar DRX fractions and crystallographic texture were attained for two compression processes owing to the similar operation of deformation mode.

Key words: Magnesium alloy, Hydrostatic pressure, Long period stacking ordered (LPSO) phase, Kinking, Dynamic recrystallization

Ce Zheng, Shuai-Feng Chen, Rui-Xue Wang, Shi-Hong Zhang, Ming Cheng. Effect of Hydrostatic Pressure on LPSO Kinking and Microstructure Evolution of Mg-11Gd-4Y-2Zn-0.5Zr Alloy[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(2): 248-264.

Figures/Tables 16

Fig. 1 Distribution of effective plastic strain for a normal-compression, b can-compression at final state; evolution of c effective plastic strain, d stress triaxiality for the selected center element

Fig. 2 EBSD results of as-homogenized GWZK114 alloy a orientation imaging microscopy (OIM); b statistical distribution of grain size; c (0001) pole figure (PF); d backscattered electron (BSE) image; TEM results of e intragranular needle-like phase; f intergranular bulk phase; g-i EDS results of points A, B, and C in Fig. 2d. The CD and RD indicate the compression and radial directions, respectively

Fig. 3 True stress-true strain curves of a normal-compression, b can-compression under different temperatures

Fig. 4 OM microstructure of as-compressed GWZK 114 alloy under two hydrostatic pressures for different deformation conditions. The DRX area fractions are also presented and calculated as fDRX = SDRX/(SAll - SInter) with SDRX and SInter being the areas of DRX grains and intergranular phases, respectively

Fig. 5 SEM images of the kink behavior of LPSO phases under different conditions; 14H and 18R-LPSO phases were marked by red and yellow lines, respectively, and the curved ones represent the kinking of LPSO phase

Fig. 6 Kinking behavior of LPSO phases in normal and can-compressed samples: a kink angle; b kink times; c relative width ratio of kink band (d/L). d schematic of width, kink times and angle for kink band. For a certain deformation case in Fig. 6a-c, at least ten measures are taken for these statistics

Fig. 7 Inverse pole figure of GWZK 114 alloy under normal-compression of a 350 °C, c 450 °C; can-compression of b 350 °C, d 450 °C

Fig. 8 Kernel average misorientation (KAM) maps of samples under normal-compression of a 350 °C, d 450 °C; can-compression of b 350 °C, e 450 °C; distribution of local misorientation of KAM under c 350 °C, f 450 °C

Table 1 Average local misorientation and calculated dislocation density under different conditions

Contents	Normal-compression		Can-compression
Contents	350 °C	450 °C	350 °C	450 °C
θ_local (°)	1.19	0.69	1.41	0.79
ρ_GND (/m², × 10¹⁴)	0.96	0.33	1.36	0.43

Fig. 9 (0001) pole figures of GWZK 114 alloy under normal-compression of a 350 °C, c 450 °C; can-compression of b 350 °C, d 450 °C

Fig. 10 DRX behavior of grain G1 in Fig. 7c: a orientation imaging microscopy (OIM); b line profile of misorientation angle along the lines A-B in a; c Schmid factors of basal 〈a〉, prismatic 〈a〉 and pyramidal 〈c + a〉 slip systems for grain G1 under normal-compression condition. (Basal 〈a〉: $\left\{ {0001} \right\}\left\langle {11\bar{2}0} \right\rangle$; prismatic 〈a〉: $\left\{ {10\bar{1}0} \right\}\left\langle {11\bar{2}0} \right\rangle$; pyramidal 〈c + a〉: $\left\{ {11\bar{2}2} \right\}\left\langle {11\bar{2}3} \right\rangle$)

Fig. 11 DRX behavior of grain G3 in Fig. 7d: a orientation imaging microscopy (OIM); b line profile of misorientation angle along the lines E-F in a; c the Schmid factors of basal 〈a〉, prismatic 〈a〉 and pyramidal 〈c + a〉 slip systems for grain G3 under can-compression condition

Fig. 12 DRX behavior of grain G2 in Fig. 7c: a orientation imaging microscopy (OIM); b band contract figure; c line profile of misorientation angle along the lines C-D in a; d the Schmid factors of basal 〈a〉, prismatic 〈a〉 and pyramidal 〈c + a〉 slip systems for grain G2 under normal-compression condition

Fig. 13 DRX behavior of grain G4 in Fig. 7d: a orientation imaging microscopy (OIM); b band contract figure c line profile of misorientation angle along the lines G-H in a, d Schmid factors of basal 〈a〉, prismatic 〈a〉 and pyramidal 〈c + a〉 slip systems for grain G4 under can-compression condition

Fig. 14 Schematic of kink band formation under different loading conditions: a compression with a small inclined α angle of CD from 14H-LPSO phase’s basal planes; b compression with a high inclined α angle of CD from 14H-LPSO phase’s basal planes

Fig. 15 Effective Schmid factor distribution of GWZK 114 alloy on (0001) PFs under

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