Grain Size Dependence of Twin Nucleation in Magnesium Alloys

Twinning plays a prominent role in the plastic deformation of low-symmetry crystals such as magnesium alloys. However, the capture of twin nucleation has been challenging since the process is rapid and difficult to predict, making it impossible to observe directly. Because of this, the fundamental mechanism of twinning and the simulation techniques incorporating twinning have been hindered for decades. In this study, a quantitative analysis integrating an in-situ three-point bending experiment and crystal plasticity modeling was conducted on the twin nucleation in AZ31 magnesium alloys with different grain sizes. The threshold for triggering twin nucleation has been quantified. The prediction ability of three widely used criteria for twin nucleation, i.e., GND density, von Mises stress, and stored energy density, is evaluated. The results suggest that only the stored energy density is able to capture the twin nucleation location accurately in all the considered grain sizes. The critical value exhibits an exponential reduction with the increase in grain size. Based on the quantitative analysis, the mechanism of the grain size effect on twin nucleation is proposed.

Keywords: twin nucleation, crystal plasticity, size effect, stored energy density, magnesium alloy

Suggested Citation: Suggested Citation

Xin, Hai and Zhan, Mei and Lei, Yudong and Zhao, Pandi and Wang, Yuyang and Zheng, Zebang, Grain Size Dependence of Twin Nucleation in Magnesium Alloys. Available at SSRN: https://ssrn.com/abstract=4726458 or http://dx.doi.org/10.2139/ssrn.4726458