Abstract
In situ hard X-ray diffraction experiments were carried out to investigate the dislocation slip activity of Mg-1 wt.% Zn-based alloys containing Nd or Ca during tensile loading. Diffraction patterns collected during tensile loading at 3 temperatures were analyzed using a convolutional multiple whole profile fitting procedure. High activation of nonbasal <a> and pyramidal <c+a> dislocations was found in the Nd- and Ca-containing alloys. The microstructure evolution after 10% deformation was examined by complementary EBSD measurements. The microstructure evolution was related to the differences in the initial texture and active deformation modes, according to the alloying and temperature. In-grain misorientation axes analysis obtained from the EBSD measurements confirms that the addition of Nd or Ca contributes to the higher activity of prismatic <a> slip. The high activity of prismatic <a> slip leads to a broadening of the basal poles perpendicular to the loading direction and a strengthening of the <101‾0> pole along the loading direction. The overall dislocation density evolution at elevated temperatures is controlled by dynamic recovery and dynamic recrystallization. These thermally activated mechanisms are retarded in the Nd- or Ca-containing alloys.
Highlights
The effect of alloying and processing on texture weakening during the rolling of magnesium (Mg) sheets has been discussed to a large extent [1,2,3,4,5]
It is assumed that the influence of Zr as an alloying element beyond its grain refining effect can be neglected for the purpose of this study [1], and ZK10 can be considered as a reference for the ZN10 and ZX10 alloys
As a result of the solution effect, the critical resolved shear stress (CRSS) for prismatic slip decreases with alloying such elements [43], which agrees well with the results presented in this work
Summary
The effect of alloying and processing on texture weakening during the rolling of magnesium (Mg) sheets has been discussed to a large extent [1,2,3,4,5]. It has been revealed that the resulting weakened textures help to improve the formability of Mg alloy sheets and to extend the performance of this class of materials for potential applications [1,7,8,9,10]. The mechanisms leading to such texture weakening, as discussed in the literature, have been mostly related to microstructure changes as a result of recrystallization. Shear band nucleation (SBN) of grains and the retardation of recrystallization due to solute drag or boundary pinning at Mg-RE precipitates have been emphasized [2,11,12,13,14,15]
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