In situ atomic-scale observation of twinning-dominated deformation in nanoscale body-centred cubic tungsten.

@article{Wang2015InSA,
  title={In situ atomic-scale observation of twinning-dominated deformation in nanoscale body-centred cubic tungsten.},
  author={Jiangwei Wang and Zhi Zeng and Christopher R. Weinberger and Ze Zhang and Ting Zhu and Scott X. Mao},
  journal={Nature materials},
  year={2015},
  volume={14 6},
  pages={
          594-600
        }
}
Twinning is a fundamental deformation mode that competes against dislocation slip in crystalline solids. In metallic nanostructures, plastic deformation requires higher stresses than those needed in their bulk counterparts, resulting in the 'smaller is stronger' phenomenon. Such high stresses are thought to favour twinning over dislocation slip. Deformation twinning has been well documented in face-centred cubic (FCC) nanoscale crystals. However, it remains unexplored in body-centred cubic (BCC… 
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References

SHOWING 1-10 OF 58 REFERENCES
Strong crystal size effect on deformation twinning
TLDR
A ‘stimulated slip’ model is developed to explain the strong size dependence of deformation twinning in crystals, and the sample size in transition is relatively large and easily accessible in experiments, making the understanding of size dependence relevant for applications.
Atomic-scale dynamic process of deformation-induced stacking fault tetrahedra in gold nanocrystals.
TLDR
A new kind of stacking fault tetrahedra formed via the interaction and cross-slip of partial dislocations in gold nanocrystals is reported, uncovering a unique deformation mechanism via dislocation interaction inside the confined volume of nanocry crystals and have important implications regarding the size effect on the mechanical behaviour of small-volume materials.
Existence of two twinning-mediated plastic deformation modes in Au nanowhiskers
Deformation twinning in nanocrystalline materials
Near-ideal theoretical strength in gold nanowires containing angstrom scale twins
TLDR
It is shown that Au nanowires containing angstrom-scaled twins exhibit tensile strengths up to 3.12 GPa, near the ideal limit, with a remarkable ductile-to-brittle transition with decreasing twin size, opposite to the behaviour of metallic nanowire with lower-density twins reported thus far.
Surface-controlled dislocation multiplication in metal micropillars
TLDR
This work predicts multiplication of dislocations in body-centered-cubic (BCC) pillars through a series of molecular dynamics and dislocation dynamics simulations, and suggests a need for a different explanation of the size dependence of yield stress in FCC and BCC pillars.
A new regime for mechanical annealing and strong sample-size strengthening in body centred cubic molybdenum.
TLDR
It is shown that significant mechanical annealing does occur in BCC, and a new regime of size effects in BCC metals is discovered, revealing deep connection in the dislocation dynamics of the two systems.
Deformation twinning during nanoindentation of nanocrystalline Ta
The deformation mechanism of body-centered cubic (bcc) nanocrystalline tantalum with grain sizes of 10–30 nm is investigated by nanoindentation, scanning electron microscopy and high-resolution
Superplastic deformation of defect-free Au nanowires via coherent twin propagation.
TLDR
It is reported that defect-free Au nanowires show superplasticity on tensile deformation, induced by coherent twin propagation, completely reorientating the crystal from <110> to <100>.
The effect of pre-existing defects on the strength and deformation behavior of α-Fe nanopillars
...
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2
3
4
5
...