Thermally Activated Dislocation Motion

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Description

This lecture covers the thermally activated dislocation motion, including the Z-A model and MTS model. It explains the role of activation energy in overcoming barriers, the evolving microstructure under shock loads, and the rate dependency of plastic response. The lecture also discusses physically based constitutive models, lattice rotations, and twinning in materials at high strain rates.

Official source

Ontological neighbourhood

Chemical engineering

Materials science: Deformation of materials

Related lectures (32)

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In course

DEMO: excepteur dolore Lorem reprehenderit

Ontological neighbourhood

Chemical engineering

Materials science: Deformation of materials

Related lectures (32)

Empirical Constitutive Relations

Explores empirical constitutive relations, dislocation movement, and thermally activated motion in material science.

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Geometrically Necessary Dislocations in Materials

Explains geometrically necessary dislocations in materials and their role in reducing work hardening.

Lamination: Deformation, Ductility, and Dislocations

Explores lamination, ductility, plastic deformation, and dislocations in materials, emphasizing the effects of strain rate and temperature.

Plastic Deformation: Introduction to the Dislocation Model

Covers plastic deformation, dislocation model, stages, shear stress, distortion, dislocation loops, strain hardening, and crystal growth.