Semiconductor Physics: Signal Amplification and Doping

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Quantum Structures: Band Gaps and Heterostructures

Covers the formation and properties of quantum wells and heterostructures in semiconductor materials.

Semiconductor Behavior

Covers the behavior of semiconductors, including intrinsic and extrinsic properties, doping, charge carriers, band bending, and p-n junction formation.

Semiconductor Junctions: Electric Fields and Currents

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

Semiconductor Detectors: Principles and Applications

Explores semiconductor detectors for radiation detection, covering principles, applications, doping, p-n junctions, and detection mechanisms.

Infrared Photodetectors: MSM and Photoconductors Overview

Covers infrared photodetectors, focusing on MSM detectors and photoconductors, their structures, advantages, disadvantages, and operational principles.

Semiconductor Physics: Donors and Acceptors

Covers the role of donors and acceptors in semiconductor physics and the control of conductivities.

Diode Schottky: Electrical Characteristics and Modeling

Covers the Schottky diode's structure, electrical characteristics, and modeling under various biasing conditions.

Diode Equations

Covers diode equations in semiconductor devices, including dark IV curve and photocurrent.

Semiconductor Materials: Charges and Energy Levels

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

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.