晶体孪晶
材料科学
成核
再结晶(地质)
动态再结晶
微观结构
退火(玻璃)
冶金
热加工
热力学
地质学
古生物学
物理
作者
S.S.A. Shah,Manping Liu,Azim Khan,Farooq Ahmad,Arman Shah Abdullah,Xingquan Zhang,S.W. Xu,Zhen Peng
标识
DOI:10.1016/j.jma.2024.04.035
摘要
Twinning is widely recognized as an effective and cost-efficient method for controlling the microstructure and properties of wrought Magnesium (Mg) alloys. Specifically, twins play a crucial role in initiating dynamic recrystallization (DRX), while twin regions experience rapid recrystallization during static recrystallization (SRX). The activation of twinning can lead to changes in lattice orientation, significantly impacting the final texture in Mg alloys. The active roles of twinning are influenced by various factors during the activation process, and the mobility of twin boundaries (TB) can be amplified by stress effects, dislocation interactions, and thermal effects. Conversely, annealing treatments that involve proper segregation or precipitation on TBs serve to stabilize them, restraining their motion. Events such as segregation may also alter the twinning propensity in Magnesium-rare earth (Mg-RE) alloys. While {10–11} contraction twins (CT) and {10–11}-{10–12} double twins (DT) can promote dynamic recrystallization (DRX), they also pose a risk as potential sources of voids and cracks. Additionally, understanding the nucleation and growth mechanisms of twinning is crucial, and these aspects are briefly reviewed in this article. Considering the factors mentioned above, this article summarizes the recent research progress in this field, shedding light on advancements in recent eras.
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