Lectures related to Semi-classical Electron Motion in Solids

Explores density of states in semiconductor devices, covering electron gas, energy bands, Fermi-Dirac distribution, and band structures.

Covers the semi-classical approximation in periodic potentials and the quantum Hall effect.

Covers effective masses in semiconductors, focusing on energy bands and their implications for materials like silicon and gallium arsenide.

Explores Maxwell's equations, induction in moving conductors, electromotive force, and electrical fields.

Covers the interpretation of band diagrams in semiconductor components, focusing on pn junction diodes and their behavior under applied voltage.

Covers the equilibrium properties of semiconductors, focusing on charge dynamics and the influence of temperature on electron-hole generation.

Covers magnetic fields, Ampère's law, and magnetic dipoles with examples and illustrations.

Explores the Boltzmann transport equation, Berry phase, and the spin Hall effect in quantum mechanics.

Explores electronic transitions in photochemistry and band theory in solids.

Covers the Bloch theorem and Kronig-Penney model, essential for understanding semiconductor band theory and electronic states in periodic potentials.

Explains band structure, density of states, Fermi distribution, and carrier densities.

Covers charge transport in semiconductors, low dimensional systems, quantum conductance, and the quantum Hall effect.

Explores charged particles in a magnetic field, focusing on Landau levels and gauge transformations.

Explores analog quantum simulation using optical lattices to control kinetic energy and create complex band structures.

Explores magnetic fields, currents, Biot-Savart law, Ampère's law, and magnetic dipoles.

Explores the components and risks of MRI scanners, emphasizing safety and functionality.

Explores electrical and magnetic properties of materials, including semiconductors, dielectric behavior, and optical phenomena.

Covers the impact of temperature on Fermi levels in doped semiconductors, analyzing behavior at 300 K, 600 K, and 77 K.

Covers the principles of optical absorption in gases and semiconductors, detailing energy interactions and measurement techniques.