Evaluation of Non-Basal Slip Activity in Rolled Mg–Li Alloys

AbstractUniaxial μ-compression tests have been performed on single crystal Mg with a <11-20> compression direction, an orientation unfavorable for basal slip. Results show that the early stages of deformation proceed via both twinning and dislocation plasticity. Twinning leads to a reorientation of the crystal favorable for basal slip, typically with the <2-1-1-3> aligned with the compression direction. At a critical strain a large strain burst occurs, and is associated with both rapid propagation of the twin and the activation of basal slip within the twin. Such a mechanistic picture of the deformation behavior is revealed through SEM, EBSD and TEM characterization of the deformation structures.

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Influence of basal slip activity in twin lamellae on mechanical behavior of Mg alloys

Materials Letters ◽

10.1016/j.matlet.2016.04.113 ◽

2016 ◽

Vol 176 ◽

pp. 147-150 ◽

Cited By ~ 12

Author(s):

Bo Song ◽

Renlong Xin ◽

Ning Guo ◽

Zhiqian Chen ◽

Xiaofang Yang ◽

...

Keyword(s):

Mechanical Behavior ◽

Basal Slip ◽

Mg Alloys ◽

Slip Activity

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Evaluation of non-basal slip activity in rolled Mg-Li alloys

Journal of Japan Institute of Light Metals ◽

10.2464/jilm.70.117 ◽

2020 ◽

Vol 70 (4) ◽

pp. 117-121

Author(s):

Haruka Miyano ◽

Keisuke Takemoto ◽

Masayuki Tsushida ◽

Hiromoto Kitahara ◽

Shinji Ando

Keyword(s):

Basal Slip ◽

Slip Activity

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Dislocation Substructures Produced During Tensile, Creep, and Fatigue Deformation of Ti3Al at 700°C

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100078882 ◽

1977 ◽

Vol 35 ◽

pp. 272-273

Author(s):

S. M. L. Sastry

Keyword(s):

Intermetallic Compound ◽

Strain Rate ◽

Tensile Creep ◽

Slip Systems ◽

Slip Vector ◽

Superlattice Structure ◽

Slip Activity ◽

Dislocation Arrangement ◽

Ordered Intermetallic ◽

Tangled Dislocation

Ti3Al is an ordered intermetallic compound having the DO19-type superlattice structure. The compound exhibits very limited ductility in tension below 700°C because of a pronounced planarity of slip and the absence of a sufficient number of independent slip systems. Significant differences in slip behavior in the compound as a result of differences in strain rate and mode of deformation are reported here.Figure 1 is a comparison of dislocation substructures in polycrystalline Ti3Al specimens deformed in tension, creep, and fatigue. Slip activity on both the basal and prism planes is observed for each mode of deformation. The dominant slip vector in unidirectional deformation is the a-type (b) = <1120>) (Fig. la). The dislocations are straight, occur for the most part in a screw orientation, and are arranged in planar bands. In contrast, the dislocation distribution in specimens crept at 700°C (Fig. lb) is characterized by a much reduced planarity of slip, a tangled dislocation arrangement instead of planar bands, and an increased incidence of nonbasal slip vectors.

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Dislocations in alumina deformed by prismatic slip

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100110179 ◽

1978 ◽

Vol 36 (1) ◽

pp. 606-607

Author(s):

J. Cadoz ◽

J. Castaing ◽

J. Philibert

Keyword(s):

Electron Microscopy ◽

Transmission Electron Microscopy ◽

Basal Slip ◽

Prismatic Slip ◽

Compression Tests ◽

Thin Sections ◽

Burgers Vector ◽

Maximum Deformation ◽

Transmission Electron ◽

Mechanical Thinning

Plastic deformation of alumina has been much studied; basal slip occurs and dislocation structures have been investigated by transmission electron microscopy (T.E.M.) (1). Non basal slip has been observed (2); the prismatic glide system <1010> {1210} has been obtained by compression tests between 1400°C and 1800°C (3). Dislocations with <0110> burgers vector were identified using a 100 kV microscope(4).We describe the dislocation structures after prismatic slip, using high voltage T.E.M. which gives much information.Compression tests were performed at constant strainrate (∿10-4s-1); the maximum deformation reached was 0.03. Thin sections were cut from specimens deformed at 1450°C, either parallel to the glide plane or perpendicular to the glide direction. After mechanical thinning, foils were produced by ion bombardment. Details on experimental techniques can be obtained through reference (3).

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