Journal
ACTA MATERIALIA
Volume 77, Issue -, Pages 28-42Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.actamat.2014.05.030
Keywords
Twinning/detwinning; Twin-twin interactions/boundaries; Secondary twinning; Mg
Funding
- Office of Basic Energy Sciences under US DOE [FWP 06SCPE401, W-7405-ENG-36]
- US Department of Energy, Office of Basic Energy Sciences [DE-SC0002144]
Ask authors/readers for more resources
When twin variants interact, TTBs form and consequently affect twinning and detwinning processes. In this paper, we study twin-twin interactions by combining experimental observations and theoretical analysis. Mg single crystals are cyclically loaded in [0001] and [10 (1) over bar0] directions, respectively. Experimental characterization reveals the character of the twin-twin-boundary and three kinds of twin-twin-structures: a quilted-looking twin structure consisting of twins arrested at other twin-boundaries, an apparent crossing twin structure which links twins impinging independently on each side of twin-lamella and a double twin-structure that results from secondary twins being nucleated at twin-twin-interfaces. According to their crystallography, twin-twin-interactions are classified into Type I for two twin-variants sharing the same (11 (2) over bar0) zone axis and Type II for two twins with different zone axes. For Type I twin-twin interactions, one twin does not transmit across the twin boundary and into the other twin. For Type II twin-twin interactions, one twin can transmit into the other only under some special loading conditions. In most cases twin transmission does not occur but, instead, twin-twin boundaries form that contain boundary dislocations. For Type I twin-twin interactions, the twin-twin boundary is a low angle tilt boundary with the habit plane being either the basal or the prismatic plane. For Type II twin-twin interactions, the twin-twin boundary is a high index crystallographic plane according to geometry analysis. twin-twin boundary dislocations can be inferred by reactions of twinning dislocations associated with the two twin variants. An apparent crossing twin structure is thus a consequence of twin-twin boundary formation. Under reversed loading, detwinning is hindered because of the energetically unfavorable dissociation of boundary dislocations. Most interestingly, secondary twinning is activated at Type II twin-twin boundaries under reversed loading. Published by Elsevier Ltd. on behalf of Acta Materialia Inc.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available