Lectures related to Surface states

Surface Properties: Understanding Semiconductors and Nanomaterials

Covers the significance of surface properties in semiconductors and nanomaterials, including surface energy, reconstruction, and the effects of surface states on electronic behavior.

Surface Absorption and Catalysis

Explores surface absorption, catalysis, and the importance of specific surfaces in chemical reactions and hydrogen economy.

Metal-Semiconductor Junction: Physics Overview

Provides an overview of metal-semiconductor junction physics, including work function, Schottky barrier, Ohmic contacts, and heterojunctions.

Alloys and Band Structure

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

Surface States and Charge Transport

Explores surface states, charge transport in semiconductors, and factors affecting mobility, emphasizing the importance of understanding and improving carrier mobility.

Advanced Optics: Photonic Crystals

Explores 2D photonic crystals, reciprocal lattices, Brillouin zones, and band diagrams in advanced optics.

Novel Materials Discovery in Silico

Explores computational discovery of novel materials, focusing on quantum spin Hall insulators and topological phases in transition metal dichalcogenides.

Doped Semiconductors

Covers heterostructuring, gate voltage tuning, doping mechanisms, and impurity band formation in semiconductors.

Topological Waves for Robust Signal Processing Applications

Explores topological waves for robust signal processing applications, focusing on resistance to perturbations and the design paradigm of topological systems.

Semiconductor Materials: Charges and Energy Levels

Covers the fundamentals of semiconductor materials, including crystal structure, energy levels, electrons, holes, charge density, and doping.

Solid State Physics II: Band Structures and Fermi Surfaces

Summarizes key concepts in Solid State Physics II, including band structures, Fermi surfaces, tight-binding approximation, and insulators vs. metals.

Carrier Concentration: Extrinsic Semiconductors Overview

Covers the influence of doping on carrier concentrations in extrinsic semiconductors and the resulting shifts in the Fermi energy level.

Band Structure: Energy Levels and Fermi Sphere

Explains energy levels, Fermi sphere, and periodic potentials in different dimensions.

Semiconductor Detectors

Explores the principles and operation of semiconductor detectors for radiation detection.

Doping in Semiconductors: Energy Band Models

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

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Formation of Bands in Semiconductors: Understanding Silicon and Gallium Arsenide

Covers the formation of bands in semiconductors, focusing on silicon and gallium arsenide, and their electronic properties and crystalline structures.

Semiconductor Devices II: Defects Engineering

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

Dispersion Relationships: Band Structures and Density of States

Discusses dispersion relationships, band structures, and density of states in real crystals and semiconductors.

Chemical Bonding in Solids

Explores chemical bonding in solids, band structure, and surface scattering techniques for lattice parameter measurements and crystal orientation analysis.