Lecture 1 - Principles of Quantum Mechanics
Lecture 2 - Principles of Quantum Mechanics - II
Lecture 3 - Schrodinger’s Wave Equation
Lecture 4 - Schrodinger’s Wave Equation - II
Lecture 5 - Formation of Energy Bands, The Kronig-Penney Model, K Space Diagram
Lecture 6 - Electrical Conduction in Solids-The Energy Band and the Bond Model, Drift Current, Electron Effective Mass
Lecture 7 - Density of States Function, Statistical Mechanics - I
Lecture 8 - DOS - II
Lecture 9 - Basic MOSFET Structure, symbol, and working as a Switch
Lecture 10 - MOSFET Operation- Depletion, Accumulation, and Inversion
Lecture 11 - MOSFET I/V Characteristics - Threshold voltage, I/V Characteristics, Transconductance
Lecture 12 - MOSFET I/V and Threshold Voltage - II
Lecture 13 - Second-Order Effects - I
Lecture 14 - Second Order Effects - II
Lecture 15 - Introduction to Cryogenics in Electronics
Lecture 16 - Cryogenic Coolant/Fluids used
Lecture 17 - Transition in Properties of materials with variation in Temperature
Lecture 18 - Transition in Properties of materials with variation in Temperature - II
Lecture 19 - Semiconductor devices at Room Temperature @ 300 K
Lecture 20 - Semiconductor devices at Low Temperature@ below 150 K and 77K
Lecture 21 - Change in Bandgap at Low Temperature - I
Lecture 22 - Change in Bandgap at Low Temperature - II
Lecture 23 - Change in Intrinsic Carrier concentration
Lecture 24 - Lowering in the level of Fermi Energy
Lecture 25 - Effect of Freeze-out on dopant atom concentration
Lecture 26 - Effect of Freeze-out on Dopant Atom Concentration - II and Complete Effect of Overall Phenomenon
Lecture 27 - Introduction to Modelling of Cryo-MOS Device
Lecture 28 - Device Performance Modelling at Cryogenic Temperatures
Lecture 29 - Semiconductor Device Equations at Low Temperature
Lecture 30 - Incomplete Ionization Models
Lecture 31 - Mobility Models: Scattering effect
Lecture 32 - Change in Threshold Voltage
Lecture 33 - Change in Threshold Voltage - II
Lecture 34 - Effect on Mobility
Lecture 35 - Effect on leakage and saturation current
Lecture 36 - Kink-observed at higher VDS due to Impact Ionization
Lecture 37 - Subthreshold Swing and Transconductance - I
Lecture 38 - Subthreshold Swing and Transconductance - II
Lecture 39 - Introduction to MOS Capacitance
Lecture 40 - Traps and Defects at Cryogenic Temperatures
Lecture 41 - C-V Characteristics: High-Frequency and Low-Frequency Capacitance
Lecture 42 - Characterization Techniques and Cryogenic MOS Capacitance Modeling
Lecture 43 - Noise Performance and Flicker Noise
Lecture 44 - Cryo-Analog to Digital Converter
Lecture 45 - Cryo-Low Noise Amplifiers
Lecture 46 - Multiplexers and Circulators
Lecture 47 - Cryo-Oscillators
Lecture 48 - Cryo-Power Management Circuits and Sensors and Sensors Interfaces
Lecture 49 - Introduction to Qubits
Lecture 50 - Properties of Qubits
Lecture 51 - Interfacing Quantum Processor with Classical Controllers
Lecture 52 - Quantum Entanglement and Quantum Communication
Lecture 53 - Single Qubit System
Lecture 54 - Extension to Two-Qubit systems and Multiplexing DC and I/O signal for 4 qubits
Lecture 55 - Multiplexing DC and I/O signal for 4 qubits
Lecture 56 - Multiplexing techniques based on FDMA, TDMA, SDMA
Lecture 57 - Introduction to Quantum Metrology and Quantum Sensing
Lecture 58 - SPADS and Challenges to Quantum Technology
Lecture 59 - Qubit readout front-end circuits for (a) Spin qubit (b)Transmon qubit
Lecture 60 - Sensing the Qubits- Microwave Technique
Lecture 61 - Characterization and Modelling of 22 nm FDSOI Cryogenic RF CMOS
Lecture 62 - Modelling of 22 nm FDSOI Cryogenic RF CMOS - Part II
Lecture 63 - Modelling of 22 nm FDSOI Cryogenic RF CMOS - Part III
Lecture 64 - Parasitic Capacitance in Nanosheet FETs
Lecture 65 - Performance Perspective of Gate All Around Double Nanosheet
Lecture 66 - Nanosheet: Part - I
Lecture 67 - Nanosheet: Part - II
Lecture 68 - Nanosheet: Part - III
