Lectures related to Contacts: Semiconductor Devices II

Contact Resistance: Theory and Measurements

Explores contact resistance in semiconductor devices, including Moore's Law, FET characteristics, quantum limits, and measurement techniques.

Semiconductor Devices II: Contact Resistance Modeling

Explores contact resistance modeling in semiconductor devices, focusing on gate voltage calculation and defect analysis.

Understanding Ohmic Contacts: Schottky and Avalanche Effects

Covers the principles of ohmic contacts and their significance in semiconductor devices.

Introduction to 2D Materials

Introduces 2D materials, FETs, optoelectronics, post-CMOS concepts, and the historical impact of Moore's Law on semiconductor devices.

Diode Schottky: Electrical Characteristics and Modeling

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

Semiconductor Devices II: Defects Engineering

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

MOSFET Structure and Operation: Qualitative Analysis

Describes the qualitative behavior of MOSFET transistors, focusing on their structure and operational principles.

MOSFET Operation: Understanding NMOS Behavior

Explains the operation of NMOS structures and their behavior in various regimes, including sub-threshold, linear, and saturation.

Building Tomorrow’s Electronics: From Atoms to Devices

Delves into the evolution of transistors, the impact of quantum effects on nano-devices, and the functionality of memristors.

Contact Resistance in Semiconductor Devices

Explores contact resistance in semiconductor devices and methods to measure and extract it.

Metal-Semiconductor Junction: Physics Overview

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

Metal-Semiconductor Junctions: Thermodynamic Equilibrium

Discusses metal-semiconductor junctions, their historical context, thermodynamic equilibrium, and the principles governing their operation in semiconductor technology.

MOSFET Basics: NMOS and PMOS Characteristics

Provides an overview of MOSFET operation, focusing on NMOS and PMOS characteristics, including current equations and channel modulation effects.

Contact Resistance: Strategies and Measurements

Explores contact resistance, quantum resistance, measurement techniques, reduction strategies, and experimental reviews in 2D materials.

Controlling Threshold Voltage in Semiconductor Devices

Covers the control of threshold voltage in semiconductor devices through oxide thickness and substrate doping adjustments.

Low-power Analog IC Design

Covers the design of low-power analog CMOS integrated circuits and the challenges of technology scaling in semiconductor industry.

Density of States in Semiconductor Devices

Explores density of states in semiconductor devices, covering electron gas, energy bands, Fermi-Dirac distribution, and band structures.

Integrated Circuits: Evolution and Fabrication

Explores the evolution of integrated circuits, from transistors to CMOS technology, highlighting key historical milestones.

Organic Electronic Devices: Field-Effect Transistors

Explores organic field-effect transistors, covering their fabrication, working principles, and real device examples.

JFET Amplifier Design: Key Concepts and Applications

Covers the design and application of JFET amplifiers, focusing on biasing, gain characteristics, and practical examples involving photodiodes.