Lectures related to Transport Properties in Semiconductors: Charge Dynamics and Conductivity

Drift Currents and Conductivity: Poisson's Equation in Semiconductors

Covers drift currents, conductivity, and the effects of scattering in semiconductors.

Diffusion Currents in Semiconductors: Principles and Equations

Covers diffusion currents in semiconductors, detailing their principles, equations, and interactions with drift currents.

Understanding Semiconductor Behavior: Charge and Conductivity

Covers semiconductor behavior, focusing on energy levels, charge distributions, and conductivity in N-P-N structures and metal-semiconductor interfaces.

Intrinsic Semiconductors: Thermal Generation and Carrier Concentration

Covers intrinsic semiconductors, focusing on thermal generation and carrier concentration calculations.

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Drude Model: Moving Charges

Explores the Drude model, charge scattering, conductivity, and temperature effects on materials.

Generation and Recombination in Semiconductors

Covers the generation and recombination processes in semiconductors out of equilibrium, detailing their implications on semiconductor behavior.

Charge Modeling in MOS Junctions: N-Substrate Analysis

Covers charge modeling and electric field variations in MOS junctions on n-substrates.

Electrical and Magnetic Properties of Materials

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

Hot Plate Experiment: Semiconductor Behavior Analysis

Covers the hot plate experiment and the behavior of silicon semiconductors under temperature gradients.

Semiconductor Junctions: Electric Fields and Currents

Covers semiconductor junctions, focusing on electric fields, current flow, and diode characteristics.

Doping in Semiconductors: Energy Band Models

Covers the impact of doping on semiconductor properties and energy levels.

Semiconductors: Band Structure and Carrier Concentration

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

Diode Schottky and PN Heterojunctions: Band Structure Analysis

Covers the construction of band diagrams for Schottky diodes and PN heterojunctions in semiconductor physics.

Doping in Semiconductors: Carrier Concentration and Ionization Energy

Discusses doping in semiconductors, focusing on carrier concentration, ionization energy, and the effects of temperature on electrical properties.

Semiconductor Components: N+/N Junction Analysis

Covers the analysis of N+/N junctions in semiconductor components, focusing on diffusion and drift currents and their equilibrium.

Semiconductors and Charge Carriers

Introduces semiconductor physics, covering materials, charge density, energy levels, doping, transport, and conductivity.

Charge Formation and Delocalization: Solitons, Polarons, and Interfaces

Explores charge carriers in organic semiconductors, including solitons, polarons, and band transport regimes.

Semiconductor Physics: Band Formation and Experiments

Covers semiconductor band formation and presents experiments demonstrating charge carrier behavior and wave-particle duality in electrons.

Magnetostatics: Magnetic Field and Force

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