Course Summary
This course covers the fundamental principles of semiconductor physics and its applications in electronic devices. Students will learn about the band theory of solids, charge carriers, and p-n junctions.Key Learning Points
- Understand the fundamental principles of semiconductor physics
- Learn about the band theory of solids and charge carriers
- Explore the applications of semiconductor physics in electronic devices
Related Topics for further study
Learning Outcomes
- Understand the principles of semiconductor physics and band theory of solids
- Analyze the behavior of charge carriers in semiconductors
- Apply semiconductor physics to the design and operation of electronic devices
Prerequisites or good to have knowledge before taking this course
- Basic knowledge of physics and calculus
- Familiarity with electronic circuits
Course Difficulty Level
IntermediateCourse Format
- Online
- Self-paced
Similar Courses
- Introduction to Quantum Mechanics
- Solid State Chemistry
Related Education Paths
Notable People in This Field
- Dr. Michio Kaku
- Elon Musk
Related Books
Description
This course can also be taken for academic credit as ECEA 5630, part of CU Boulder’s Master of Science in Electrical Engineering degree.
Outline
- Quantum Theory Of Semiconductors
- Semiconductor Devices Specialization Introduction
- Course Introduction
- Crystal Structures
- Defects in Crystals
- Crystal Growth
- Formation of Energy Bands
- Energy Band Structure
- Semiconductor
- Module Topics
- Materials and Physical Constants
- Homework #1
- Carrier Statistics
- Density of States
- Carrier Statistics
- Intrinsic Semiconductors
- Extrinsic Semiconductors 1
- Extrinsic Semiconductors 2
- Module Topics
- Materials and Physical Constants
- Homework 2
- Currents in Semiconductor
- Currents in Semiconductor
- Drift Current
- Diffusion Current
- Hall Effect
- Module Topics
- Materials and Physical Constants
- Homework #3
- Carrier Dynamics
- Radiative Transitions
- Radiative Transition Rate
- Non-Radiative Transitions 1
- Non-Radiative Transitions 2
- Continuity Equation
- Quasi-Fermi Level
- Heterogeneous Materials
- Module Topics
- Materials and Physical Constants
- Homework #4
Summary of User Reviews
Discover the fascinating world of semiconductor physics through this engaging course on Coursera. Users rave about the detailed explanations and practical applications provided by the instructor. Many have found this course to be an excellent starting point for a career in the field.Key Aspect Users Liked About This Course
The detailed explanations and practical applications provided by the instructorPros from User Reviews
- Excellent starting point for a career in the field
- Engaging and informative lectures
- Well-organized course materials
- Instructor is knowledgeable and responsive
- Good balance between theory and practical applications
Cons from User Reviews
- Some users found the course to be too technical
- Not enough emphasis on certain topics
- Could benefit from more interactive elements
- Some users experienced technical difficulties with the platform
- Limited opportunities for peer interaction
Wounjhang Park
4.4 Raiting
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