New models for dislocation structure and motion are presented for nanocrystals, nucleation at grain boundaries, shocked crystals, interphase interfaces, quasicrystals, complex structures with non-planar dislocation cores, and colloidal crystals. A review of experimentally established main features of the magnetoplastic effect with their physical interpretation explains many diverse results of this type. The model has many potential applications for forming processes influenced by magnetic fields.
- Dislocation model for the magnetoplastic effect- New mechanism for dislocation nucleation and motion in nanocrystals- New models for the dislocation structure of interfaces between crystals with differing crystallographic structure- A unified view of dislocations in quasicrystals, with a new model for dislocation motion- A general model of dislocation behavior in crystals with non-planar dislocation cores - Dislocation properties at high velocities- Dislocations in colloidal crystals
New models for dislocation structure and motion are presented for nanocrystals, nucleation at grain boundaries, shocked crystals, interphase interfaces, quasicrystals, complex structures with non-planar dislocation cores, and colloidal crystals. A review of experimentally established main features of the magnetoplastic effect with their physical interpretation explains many diverse results of this type. The model has many potential applications for forming processes influenced by magnetic fields.
- Dislocation model for the magnetoplastic effect- New mechanism for dislocation nucleation and motion in nanocrystals- New models for the dislocation structure of interfaces between crystals with differing crystallographic structure- A unified view of dislocations in quasicrystals, with a new model for dislocation motion- A general model of dislocation behavior in crystals with non-planar dislocation cores - Dislocation properties at high velocities- Dislocations in colloidal crystals
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Dislocations in FCC Metallic Nanocystalline Materials
2. M.A. Tschopp, D.E. Spearot, and D.L. McDowell, Influence of
Grain Boundary Structure on Dislocation Nucleation in FCC
Metals
3. M.J. Demkowicz, J. Wang, and R.G. Hoagland, Interfaces between
Dissimilar Crystalline Solids
4. H.M. Zbib, and T.A. Khraishi, Size Effects and Dislocation-Wave
Interaction in Dislocation Dynamics
5. J. Bonneville, D. Caillard, and P. Guyot, Dislocations and
Plasticity of Icosahedral Quasicrystals
6. V.I. Alshits, E.V. Darinskaya, M.V. Koldaeva, and E.A. Petrzhik,
Magnetoplastic Effect in Nonmagnetic Crystals
7. V. Vitek, and V. Paidar, Non-planar Dislocation Cores: A
Ubiquitous Phenomenon Affecting Mechanical Properties of
Crystalline Materials
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