Physics of Manufacturing: Laser Processing and Material Shaping

Related lectures (30)

Covers shock waves, brittle material response, phase transformation, and Hugoniot relationships in materials under stress.

Explores stress, strain, elasticity, plasticity, and material behavior, emphasizing the importance of dislocations and microstructure.

Explores relaxation in traction, permanent deformation, hardening, and strain rate calculation.

Covers axial loading, stress, strain, and their implications in deformable bodies.

Covers the fundamentals of structural mechanics, including axial loading, stress, strain, and generalized uniaxial loading.

Covers yield strength, hardness, defects, dislocations, plasticity mechanisms, and hardening in materials science for mechanical engineering.

Explores dislocations, grain boundaries, and hardening mechanisms in metals through thermal treatments and recrystallization.

Explores the modes of hardening metal alloys and their industrial implications, emphasizing the effects of dislocations and grain size.

Covers the fundamentals of metallurgy, including world reserves of metals, shaping processes, heat treatments, and steel properties.

Explores mechanical properties, plastic deformation, dislocations, strengthening mechanisms, and high temperature plasticity in alloys.

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