Microstructure and Texture Evolution of Mg-14Gd-0.5Zr Alloy during Rolling and Annealing under Different Temperatures

doi:10.1007/s40195-022-01447-x

Abstract

Abstract:

Mg alloys containing high rare earth (RE) elements are hard to be rolled due to their low ductility and high strength at low temperatures. Therefore, rolling at high temperatures is necessary for these alloys. In this work, a Mg-14Gd-0.5Zr (wt%) alloy was rolled one pass with 40% reduction at high temperatures over 450 °C. The effects of rolling temperature on the microstructure and dynamic recrystallization behavior were analyzed in detail by the electron backscattered diffraction (EBSD) method. The results revealed that the alloy shows good rollability at high temperature due to the activity of non-basal dislocations and twins. However, dynamic recrystallization is difficult to take place because of the easy activation of multi-slip system and thus more accumulated strain energy. However, Gd segregation was observed at the grain boundary and it is inferred that the segregation can partially enhance the dynamic recrystallization ratio. Statically recrystallized grains with large size took place after short-term inter-pass annealing treatment ranging from 450 °C to 500 °C, and formed basal texture. The result suggests that the formation of basal texture during short-term annealing treatment was attributed to the growth of dynamic recrystallized grains caused by weakened Gd segregation.

Key words: Magnesium alloys, Hot rolling, Annealing, Recrystallization, Mg-Gd-Zr

Chunxiao Li, Hong Yan, Rongshi Chen. Microstructure and Texture Evolution of Mg-14Gd-0.5Zr Alloy during Rolling and Annealing under Different Temperatures[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 61-76.

Figures/Tables 18

Fig. 1 Macrographs of GK140 alloys rolled at a 450 °C, b 475 °C, c 500 °C

Table 1 List of rolling temperature and annealing treatment of the samples

Rolling temperature ( °C)	Sample number	Annealing treatment	Sample number
450	R1	450 °C × 10 min	R1-450 °C
		475 °C × 10 min	R1-475 °C
		500 °C × 10 min	R1-500 °C
475	R2	450 °C × 10 min	R2-450 °C
		475 °C × 10 min	R2-475 °C
		500 °C × 10 min	R2-500 °C
500	R3	450 °C × 10 min	R3-450 °C
		475 °C × 10 min	R3-475 °C
		500 °C × 10 min	R3-500 °C

Fig. 2 Microstructures of GK140: a, b optical and SEM microstructure images of GK140 in the cast state; c, d optical and SEM microstructures of GK140 in the solution state; e EDS results of point A in b

Fig. 3 Invers pole figure maps and boundary maps of a, b R1, c, d R2, e, f R3

Fig. 4 a KAM map of R1; b microbands in R1; c, d KAM maps of R2 and R3 samples

Fig. 5 a KAM map of R1; b microbands in R1; c, d KAM maps of R2 and R3 samples

Fig. 6 Optical microstructures of a-c R1-450 °C, R2-450 °C and R3-450 °C; d-f R1-475 °C, R2-475 °C and R3-475 °C; g-i R1-500 °C, R2-500 °C and R3-500 °C

Fig. 7 a-c Inverse pole figure maps of R1-500 °C, R2-500 °C and R3-500 °C; d-f KAM maps of R1-500 °C, R2-500 °C and R3-500 °C. Figures inserted in a-c are boundary maps with dashed rectangles

Fig. 8 Backscattered electron images of a, d R1, b, e R2, c, f R3

Table 2 SF of extensive twin variant under the PSC condition and the strain accommodated by twinning

	Variant 1	Variant 2	Variant 3	Variant 4	Variant 5	Variant 6	Strain accommodated
R1	0.05	0.12	0.10	0.05	0.07	0.05	0.04
R2	0.23	0.28	0.04	0.26	0.29	0.01	0.01
R3	0.08	0.14	- 0.23	0.07	0.12	-0.25	0.02

Fig. 9 IPF figures of parent grain and twin and its corresponding (10-12) pole figures selected from a R1, b R2, c R3

Fig. 10 IGMA distributions of a R1, b R2, c R3

Fig. 11 (0001), (10-10) pole figures and IGMA distributions of G1, G2 and G3

Fig. 12 a High angle annular dark field image of grain boundaries in R2; b, c EDS maps corresponding to a; d high angle annular dark field image of grain boundaries in R3; e, f EDS maps corresponding to d

Table 3 Compositions of points marked in Fig. 12

Point	A	R2 B	C	D	R3 E	F
Mg (wt%)	84.43	82.85	84.32	87.49	83.97	87.00
Gd (wt%)	15.57	17.15	15.68	12.51	16.03	13.00

Fig. 13 Average KAM as a function of the X value

Fig. 14 a-c (0001) pole figures of R1, R2 and R3; d-f (0001) pole figures of R1-500 °C, R2-500 °C and R3-500 °C

Fig. 15 (0001) pole figure of deformed grains in a R1, d R2 and g R3; (0001) pole figure of dynamic recrystaillized grains in b R1, e R2 and h R3; the basal pole titled angle statistical distribution of deformed and recrystallized grains in c R1, f R2 and i R3

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