Dependence of Microstructure Evolution and Mechanical Properties on Loading Direction for AZ31 Magnesium Alloy Sheet with Non-basal Texture During In-Plane Uniaxial Tension

doi:10.1007/s40195-021-01246-w

Abstract

Abstract:

In-plane uniaxial tension of AZ31 magnesium alloy sheet with non-basal texture has been conducted in order to demonstrate the effects of loading direction on the microstructure evolution and mechanical properties at ambient temperature. Loading axes are chosen to be along five directions distributed between rolling direction (RD) and transverse direction (TD), allowing various activities in involved slip and twinning modes to take place. As for twinning modes, electron backscattered diffraction observations confirm that the contribution of ${{\{ 10\overline{1}1\} }}$ compression twinning is minimal to the plastic deformation of all deformed samples. By comparison, ${{\{ 10\overline{1}2\} }}$ extension twinning (ET) not only serves as an important carrier on sustaining and accommodating plastic strain but also contributes to the emergence of TD-component texture with the progression of plastic strain. In terms of slip modes, analysis on Schmid factor demonstrates that the increasing tilted angle between loading direction and RD of sheet is unfavorable to the activation of basal <a> slip, whereas it contributes to the activation of prismatic <a> slip. These observations consequently explain the increasing tendency of 0.2% proof yield stress. Moreover, the activations of basal <a> slip and ${{\{ 10\overline{1}2\} }}$ ET collectively contribute to the concentration of two tilted basal poles toward normal direction. With increasing angle between loading direction and RD, the activations of basal <a> slip and ${{\{ 10\overline{1}2\} }}$ ET are gradually weakened. This leads to a weakening tendency about concentration of two tilted basal poles, a generally increasing tendency about Lankford value (r-value) and a generally decreasing tendency about strain-hardening exponent (n-value).

Key words: AZ31 magnesium alloy, Non-basal texture, Plastic deformation, Microstructure evolution

Li Hu, Mingao Li, Qiang Chen, Tao Zhou, Laixin Shi, Mingbo Yang. Dependence of Microstructure Evolution and Mechanical Properties on Loading Direction for AZ31 Magnesium Alloy Sheet with Non-basal Texture During In-Plane Uniaxial Tension[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(2): 223-234.

Figures/Tables 11

Fig. 1 a Optical micrograph of ECAR-CB-A AZ31 magnesium alloy sheet; b statistic analysis of grain size; c ${(}0002)$, $(10\overline{1}0)$ and $(10\overline{1}1)$ pole figures

Fig. 2 Schematic illustration of tension specimens with different tilted angles between loading direction and RD of sheet and the corresponding dimensions of tension specimen

Fig. 3 IPF maps, GB maps and KAM maps of 6%-deformed samples subjected to uniaxial tension along various loading directions: a1-c1 UT-0° sample; a2-c2 UT-30° sample; a3-c3 UT-45° sample; a4-c4 UT-60° sample; a5-c5 UT-90° sample

Fig. 4 IPF maps, GB maps and KAM maps of 12%-deformed samples subjected to uniaxial tension along various loading directions: a1-c1 UT-0° sample; a2-c2 UT-30° sample; a3-c3 UT-45° sample; a4-c4 UT-60° sample; a5-c5 UT-90° sample

Fig. 5 Misorientation angle distribution of deformed samples: a UT-0° sample; b UT-30° sample; c UT-45° sample; d UT-60° sample; e UT-90° sample and f statistical analysis about LABs

Fig. 6 Texture evolution of various samples subjected uniaxial tension along different loading directions: a UT-0° sample; b UT-30° sample, c UT-45° sample; d UT-60° sample, e UT-90° sample

Table 1 Measured results about separated angles between two points with maximum pole density in tilted basal poles at different deformation degrees and the corresponding difference (${\Delta }\theta$)

Samples	Separated angle		Difference
Samples	Deformation degree of 6%	Deformation degree of 12%	${\Delta }\theta$
UT-0°	71.3°	55.6°	15.7°
UT-30°	72.2°	61.4°	10.8°
UT-45°	71.8°	62.5°	9.3°
UT-60°	85.7°	80.8°	4.9°
UT-90°	80.6°	75.9°	4.7°

Fig. 7 a True stress-strain curves, b corresponding strain hardening curves, c curves of FE and ratio of YS to UTS and d curves of r-value and n-value

Table 2 Mechanical properties of various samples during uniaxial tension

Samples	YS (MPa)	UTS (MPa)	YS/UTS	FE (%)	r-value	n-value
UT-0°	72	271	0.27	21.6	0.41	0.45
UT-30°	95	316	0.30	23.9	0.37	0.48
UT-45°	112	282	0.40	19.6	0.69	0.43
UT-60°	123	266	0.46	17.3	0.92	0.32
UT-90°	150	288	0.52	12.4	1.23	0.20

Fig. 8 Analysis of SF on involved slip modes before uniaxial tension

Fig. 9 EBSD maps and (0002) pole figures of the selected ${{\{ 10\overline{1}2\} }}$ ETs in all deformed samples at deformation degree of 6%: a UT-0° sample; b UT-30° sample; c UT-45° sample; d UT-60° sample; e UT-90° sample

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