Lectures related to Ionic Materials Conductivity

Semiconductor Devices II: Defects Engineering

Covers the analysis of measurements and defects engineering in semiconductor devices, including density of states and defect probing.

Effective Masses in Semiconductor Physics

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

Electrical Conductivity of Metals: Semiconductor Properties

Explores electrical conductivity of metals, semiconductor properties, and energy bands.

Intrinsic Semiconductors: Thermal Generation and Carrier Concentration

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

Free Electrons and Holes (Electronics)

Explores the manipulation of charge carriers in semiconductors to generate electric fields.

Excitons in Disordered Systems

Explores excitons in disordered systems, focusing on exciton dissociation and charge carrier trapping.

Band Structure: 3D to OD

Explores band structure in various dimensions, quantum confinement effects, density of states, and Fermi quantities in 3D objects.

Semiconductor Components: Band Diagram Interpretation

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

Drift Currents and Conductivity: Poisson's Equation in Semiconductors

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

Semiconductors: Band Structure and Carrier Concentration

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

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.

Charge Formation and Delocalization: Solitons, Polarons, and Interfaces

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

Electronic Band Structure: Kronig-Penney Potential

Explores electronic band structure, material properties, and density of states in periodic potentials, including energy levels and wavefunctions.

Semiconductor Detectors: Principles and Applications

Explores semiconductor detectors for radiation detection, covering history, principles, charge carriers, doping, p-n junctions, and detection chain.

Semiconductor Devices II: Contact Resistance Modeling

Explores contact resistance modeling in semiconductor devices, focusing on gate voltage calculation and defect analysis.

Semiconductors: Basic Properties

Explores the basic properties of semiconductors, including conductivity, impurities, band gaps, and crystal structures.

Density of States in Semiconductor Devices

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

Phonon Band Structure

Explores Phonon Band Structure, Density of States, and Modes in crystal lattices, including the Schrodinger equation and phonon dispersion.

Alloys and Band Structure

Covers the properties of alloys, band structure, and density of states in materials like GaAs and Si.

Semiconductor Materials and Nanostructures

Covers the history of semiconductor materials, band structure, charge carriers, doping, electronic transport, optical properties, and applications.