Atomic-resolution investigations on dislocation-assisted evolution of {101¯3} twin boundaries in a magnesium alloy

•{101¯3} TBs and STGBs near the {101¯3} twin orientation can evolve into each other by reactions with basal 〈a60〉 dislocations.•Incident basal 〈a60〉 dislocations would prefer to react with GBDs at the STGBs, producing steps and {101¯3} TDs.•Resultant STGB steps can further emit {101¯3} TDs to facili...

Full description

Saved in:
Bibliographic Details
Published in:International journal of plasticity 2024-10, Vol.181, p.104108, Article 104108
Main Authors: Su, Huhu, Zu, Qun, Yang, Zhiqing, Ye, Hengqiang
Format: Article
Language:English
Subjects:
Deformation
Dislocations
Mg alloy
Plasticity
Twinning
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•{101¯3} TBs and STGBs near the {101¯3} twin orientation can evolve into each other by reactions with basal 〈a60〉 dislocations.•Incident basal 〈a60〉 dislocations would prefer to react with GBDs at the STGBs, producing steps and {101¯3} TDs.•Resultant STGB steps can further emit {101¯3} TDs to facilitate STGB migration.•The STGB can transform into a {101¯3} TB by a GB sliding of b = 〈303¯2¯〉 theoretically. {101¯3}〈303‾2‾〉 twinning is usually activated at the later stage of plastic deformation of Mg alloys, which is closely relevant to their fracture behavior. Reactions between slip dislocations and twin boundaries (TBs) are suggested to facilitate TB migration, retarding the premature TB cracking. Here, dislocation-assisted evolution of {101¯3} TBs in a Mg alloy subjected to cyclic deformation were studied and modeled, according to transmission electron microscopy observations, theoretical analyses of interfacial defects, and molecular dynamics simulations. Atomic-resolution experimental observations showed that symmetric tilt grain boundaries (STGBs) near the {101¯3} twin orientation with steps were generated in the deformed Mg alloy. Theoretical analyses and atomistic simulations indicated that transformation of {101¯3} TBs into the STGBs could occur by reactions with incident basal 〈a60〉 dislocations in pairs from the twin and matrix respectively under the normal stress. STGB steps would be produced by reactions of individual basal 〈a60〉 dislocations with GB dislocations at the STGB. Importantly, resultant steps could further emit {101¯3} twinning dislocations to facilitate the STGB migration. Moreover, STGBs near the {101¯3} twin orientation could evolve back into {101¯3} TBs either by reactions with an array of basal 〈a60〉 dislocations, or by a GB sliding of b = 〈303‾2‾〉 theoretically. Our results may provide insights into the mechanisms of {101¯3} TB evolution in Mg alloys, which plays important roles in their plastic deformation and plasticity. [Display omitted]
ISSN:0749-6419
DOI:10.1016/j.ijplas.2024.104108