Effect of Deformation Temperatures on Microstructure of AQ80 Magnesium Alloy under Repeated Upsetting-Extrusion

doi:10.1007/s40195-023-01562-3

Abstract

Abstract:

A new repeated upsetting-extrusion (RUE) process was proposed to improve the microstructure and the mechanical properties of Mg alloys. The effects of deformation temperature on the microstructure and microhardness of RUEed AQ80 Mg alloy were studied. The results showed that Mg alloy is subjected to sufficient corner shear deformation, upsetting deformation, and extrusion deformation, resulting in a large and uniformly distributed effective strain after RUE deformation. The microstructure is refined to an average grain size of 2.1 μm by the continuous dynamic recrystallization (CDRX) mechanism at 250 °C. As the temperature increases to 300 °C, the discontinuous dynamic recrystallization (DDRX) mechanism is activated and the average grain size is refined to 1.6 µm by the combined effect of CDRX and DDRX. In comparison to their parent grains, the orientations of the CDRXed grains show a clearly preferred orientation, but those of the DDRXed grains are completely different. At 350 °C, {10-12} extension twins appear in the microstructure, and the twinning-induced recrystallization (TDRX) mechanism plays an important role in grain refinement. With the two strengthening mechanisms of fine-grained strengthening and dislocation strengthening, the microhardness of the 250 °C sample is greatly improved, with an increase of about 35.1% compared to the initial sample.

Key words: AQ80 Mg alloy, Repeated upsetting-extrusion, Microstructure, Microhardness

Yutian Fan, Liwei Lu, Hongliang Zhao, Zhiqiang Wu, Yong Xue, Wen Wang. Effect of Deformation Temperatures on Microstructure of AQ80 Magnesium Alloy under Repeated Upsetting-Extrusion[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(10): 1649-1664.

Figures/Tables 14

Fig. 1 Schematic diagram of the repeated upsetting-extrusion die

Fig. 2 Effective strain distribution in the longitudinal section of the deformed billet: a 1/2 pass; b 1 pass; c distribution of effective strain in different directions

Table 1 Values of εmax, εmin, εave and Ci after RUE of 1/2 and 1 pass

	ε_max	ε_min	ε_ave	C_i
1/2 pass	1.68	0.67	1.07	0.94
1 pass	2.93	2.12	2.52	0.32

Fig. 3 Flow velocity distribution in the longitudinal section of the deformed billet: a, b 1/2 pass; c, d 1 pass

Fig. 4 Microstructural characteristics of the initial alloy: a grain boundaries map; b grain size distribution; c misorientation angle distribution

Fig. 5 Inverse pole figure maps a-c; twinning boundary and DRXed grains distribution maps d-f; distribution histogram of misorientation angle with axis distributions for the angles of 30 ± 5° and 86 ± 5° g-i and grain size distribution chart j-l. EBSD of RUEed alloy after different temperatures: a, d, g, j 250 ℃; b, e, h, k 300 ℃; c, f, i, l 350 ℃

Fig. 6 Details of {10-12} twinning behavior of coarse grains a, b G1 and c, d G2 are selected in Fig. 5c: a, c inverse pole figure maps; b, d KAM maps; e corresponding (0001) pole figure, f inverse pole figure

Fig. 7 Details of DRX behavior and corresponding effects on the grain orientation in the typical regions R1 selected in Fig. 5a: a inverse pole figure map; b misorientation angle developed along the black arrow AB indicated in a; c (0001) pole figures, d inverse pole figures along the ED

Fig. 8 Details of DRX behavior and corresponding effects on the grain orientation in the typical regions R2 selected in Fig. 5b: a inverse pole figure map; b (0001) pole figures; c misorientation angle developed along the black arrow CD, d Schmid factor distribution map

Fig. 9 Schematic illustration of grain refinement and corresponding mechanisms during RUE process: a initial state, b CDRX, c CDRX and DDRX, d CDRX and TDRX

Fig. 10 TEM images of the 250 ℃ sample: a dislocation, b dislocation wall, c dislocation cells, d dislocation array and sub-grain boundaries

Fig. 11 Two-beam bright-field TEM micrographs of 250 ℃ sample: a high density dislocation, b g = 01-11, c g = 01-10, d g = 0002

Fig. 12 Microhardness chart of the AQ80 alloy after different deformation temperatures

Fig. 13 KAM maps: a 250 ℃, b 300 ℃, c 350 ℃, d the corresponding KAM relative frequency and average KAM value

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