NOC:Fundamentals of Semiconductor Devices


Lecture 1 - Introduction to semiconductors


Lecture 2 - Introduction to energy bands


Lecture 3 - Fundamentals of band structure


Lecture 4 - Band structure (Continued...) and Fermi-Dirac distribution


Lecture 5 - Density of states


Lecture 6 - Doping and intrinsic carrier concentration


Lecture 7 - Equilibrium carrier concentration


Lecture 8 - Temperature-dependence of carrier concentration


Lecture 9 - High doping effects and incomplete ionization


Lecture 10 - Carrier scattering and mobility


Lecture 11 - Low-field and high-field transport, introduction to diffusion


Lecture 12 - Drift-diffusion and trap statistics


Lecture 13 - Current continuity equation


Lecture 14 - Continuity equation (Continued...) and introduction to p-n junction


Lecture 15 - p-n junction under equilibrium


Lecture 16 - p-n junction under equilibrium (Continued...)


Lecture 17 - p-n junction under bias


Lecture 18 - p-n junction under bias (Continued...)


Lecture 19 - p-n junction: generation-recombination currents


Lecture 20 - Application of p-n junctions


Lecture 21 - Breakdown of junction and C-V profiling


Lecture 22 - Introduction to Schottky junction


Lecture 23 - Schottky junction under equilibrium


Lecture 24 - Schottky junction under bias


Lecture 25 - Introduction to transistors: BJT


Lecture 26 - Basics of BJT


Lecture 27 - Working of BJT


Lecture 28 - Working of BJT (Continued...)


Lecture 29 - Delays in BJT


Lecture 30 - MOS: Introduction


Lecture 31 - MOS: Capacitance-voltage


Lecture 32 - Ideal MOS system: derivation of threshold voltage


Lecture 33 - MOS C-V in more details


Lecture 34 - MOSFET - An introduction


Lecture 35 - Gradual Channel Approximation: Derivation of I-V characteristics


Lecture 36 - Substrate bias effect and subthreshold conduction in MOSFET


Lecture 37 - Short Channel Effects in MOSFET


Lecture 38 - Introduction to compound semiconductors


Lecture 39 - Basics of heterojunctions


Lecture 40 - Band diagram of heterojunctions


Lecture 41 - Heterojunctions (Continued....)


Lecture 42 - Heterojunction transistors


Lecture 43 - III-nitrides


Lecture 44 - Solar cell basics


Lecture 45 - Solar cell (Continued...)


Lecture 46 - Solar cell: Shockley Quiesser Limit


Lecture 47 - Basics of photodetectors


Lecture 48 - Photodetectors: figures of merit and types of devices


Lecture 49 - Junction photodetectors


Lecture 50 - Basics of recombination


Lecture 51 - Basics of LED


Lecture 52 - LED: light extraction and design issues


Lecture 53 - Visible LED: photometry and colorimetry


Lecture 54 - Transistors for power electronics


Lecture 55 - Transistors for power electronics (Continued...) and for RF electronics


Lecture 56 - Transistors for RF (Continued...) and transistors for Memory


Lecture 57 - Basics of microelectronic fabrication


Lecture 58 - Microelectronic fabrication (Continued...)


Lecture 59 - Summary