Semiconductor Devices and Circuits
Offered By: NPTEL via YouTube
Course Description
Overview
PRE-REQUISITES: A background in electrical engineering helps to some extent, but this is not required
INTENDED AUDIENCE: Graduate and Senior Undergraduate Students pursuing studies in Electrical/Electronic Engineering, Electronic Materials, Physics
INDUSTRIES APPLICABLE TO : Companies working in semiconductors and integrated circuits: Intel, AMD, Samsung, Texas Instruments, Analog Devices etc.
COURSE OUTLINE : This course is intended to equip any students interested in electronic materials and devices with the fundamentals of semiconductor devices. The materials covered in the course begins with fundamentals and accelerates to advanced topics in semiconductor physics. The course connects circuit performance to material and device behavior.
At the end of the course, the students would learn to:
1.) Learn the important concepts related to semiconductor technology.
2.) Perform the analysis and design of semiconductor devices (electrostatics and current-voltage characteristics) from fundamental principles.
3.) Learn how to extract device parameters by suitable experiments.
4.) Engineer and innovate on device design and even construct new devices intended for special applications in circuits. There is special emphasize placed on this aspect.
5.) Learn the fundamentals of circuit design and observe how device properties and device design impact circuit behaviour (eg. dc and ac response, noise)
6.) Extend the concepts and analysis to advanced topics such as: devices based on disordered semiconductors (eg. organic semiconductors, amorphous metal oxides), flexible and printed electronics, etc.
Syllabus
lec 01 Quantum Mechanics: Concept of Wave Particle, Schrodinders Equation.
lec 02 Quantum Mechanics: Particle in a Box.
lec 03 Quantum Mechanics: Particle in a Box - Continued, Harmonic Oscillator.
mod02lec04.
mod02lec05.
mod02lec06.
mod02lec07.
mod02lec08.
lec09-Density of States.
lec10-Density of States - Continued, Fermi Function.
lec11-Fermi Function - Carrier Concentration.
lec12-Doping.
lec13-Doping - Continued.
lec14-Recombination and Generation.
lec15-Recombination and Generation - Continued.
lec16-Recombination and Generation - Continued, Charge Transport.
lec17-Charge Transport - Continued.
lec18-Continuity Equation.
mod05lec19.
mod05lec20.
mod05lec21.
mod05lec22.
mod05lec23.
mod06lec24.
mod06lec25.
mod06lec26.
mod06lec27.
mod06lec28.
mod07lec29.
mod07lec30.
mod07lec31.
mod08lec32.
mod08lec33.
mod08lec34.
mod08lec35.
mod09lec36.
mod09lec37.
mod09lec38.
mod09lec39.
mod09lec40.
mod10lec41.
mod10lec42.
mod10lec43.
mod10lec44.
mod10lec45.
mod11lec46.
mod11lec47.
mod11lec48.
mod11lec49.
mod11lec50.
mod12lec51.
mod12lec52.
mod12lec53.
mod12lec54.
mod12lec55.
Taught by
Semiconductor Devices and Circuits
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