By completing the [/resources/qdot Quantum Dot Lab], you will be able to:
a) understand the 3D confinement of carriers in a quantum dot,
b) describe effects of geometry of a quantum dot on the energy states of carriers,
c) study light absorption of a quantum dot
The specific objectives of the Quantum Dot Lab are:
== Recommended Reading ==
If you have not had experience with quantum mechanics, listed below are the suggested reading materials:
1. D. K. Ferry, Quantum Mechanics: An Introduction for Device Physicists and Electrical Engineers, Second Edition (Institute of Physics Publishing, 2001).
2. P. Harrison, Quantum Wells, Wires and Dots: Theoretical and Computational Physics of Semiconductor Nanostructures (John Wiley & Sons, 2010).
3. Quantum dot, wikipedia - http://en.wikipedia.org/wiki/Quantum_dot.
== Demo ==
* [/resources/10779 First time user guide for quantum dot lab]
* [/resources/4194 Introduction to quantum dot lab]
* [/resources/6845 Quantum dot lab tool demonstration]
== Theoretical Description ==
* [/resources/189 Quantum dots]
* [/resources/8598 Introduction to Quantum Dots and Modeling Needs/Requirements]
* [/resources/8599 Nanoelectronic Modeling Lecture 29: Introduction to the NEMO3D Tool]
== Tool Verification ==
== Worked Examples ==
* [/resources/4196/download/2008.03.06-klimeck.pdf Introduction to quantum dot lab slide 19-30]
== Exercises and Homework Assignments ==
* [/resources/4203 Exercise]
== Solutions to Exercises ==
* Solutions to exercises are provided to Instructors ONLY!
== Take a Test ==
* [/resources/9968 Test for Quantum Dot Lab tool]
== Solve the Challenge ==
* [/resources/9970 Quantum dot - Design a laser]