Quantum Dot Lab Learning Module: An Introduction

By James K Fodor1; Jing Guo1

1. University of Florida

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Online Presentations

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Abstract

THIS MATERIAL CORRESPONDS TO AN OLDER VERSION OF QUANTUM DOT LAB THAN CURRENTLY AVAILABLE ON nanoHUB.org. More current documentation is available through links on the tool page. This learning module introduces nanoHUB users to the Quantum Dot Lab simulator. A brief introduction to Quantum Dot Lab is presented, followed by voiced presentations featuring the simulator in action. Upon completion of this module, users should be able to use this simulator to gain valuable insight into the electronic and physical properties of cutting edge devices.

This series is a set of materials formerly known as a "Learning Module." It has been converted into an Online Presentation.  Please feel free to pause the presentation at anytime so you can try the different exercises with the simulation tool.

Topics:

  • Introduction
  • Example 1: Box Quantum Dot
  • Example 2: Quantum Dot Shapes
  • Example 3: Device Material

Cite this work

Researchers should cite this work as follows:

  • James K Fodor, Jing Guo (2007), "Quantum Dot Lab Learning Module: An Introduction," https://nanohub.org/resources/2846.

    BibTex | EndNote

Tags

  1. ANTSY
  2. AQME
  3. Learning Module
  4. nanoelectronics
  5. quantum
  6. Quantum Dot Lab
  7. quantum dots
  8. tight-binding
  9. wavefunction
Quantum Dot Lab Learning Module: An Introduction
  • Introduction to QDot Lab 1. Introduction to QDot Lab 0
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  • Descriptoin of the QDot Lab Simulator 2. Descriptoin of the QDot Lab Si… 27.694361027694363
    00:00/00:00
  • Descriptoin of the QDot Lab Examples 3. Descriptoin of the QDot Lab Ex… 67.667667667667672
    00:00/00:00
  • Quantum Dot Lab Problem 1 4. Quantum Dot Lab Problem 1 95.862529195862535
    00:00/00:00
  • 1a) Eigenenergy vs. State 5. 1a) Eigenenergy vs. State 125.658992325659
    00:00/00:00
  • 1a) Eigenenergy vs. State 6. 1a) Eigenenergy vs. State 142.67600934267603
    00:00/00:00
  • 1a) Eigenenergy vs. State 7. 1a) Eigenenergy vs. State 166.56656656656656
    00:00/00:00
  • 1b) 3D Wave Function 8. 1b) 3D Wave Function 194.76142809476144
    00:00/00:00
  • Quantum Dot Lab Problem 2 9. Quantum Dot Lab Problem 2 227.09376042709377
    00:00/00:00
  • 2a) Eigenenergy vs. State 10. 2a) Eigenenergy vs. State 263.697030363697
    00:00/00:00
  • 2a) Eigenenergy vs. State 11. 2a) Eigenenergy vs. State 318.31831831831835
    00:00/00:00
  • 2a) Eigenenergy vs. State 12. 2a) Eigenenergy vs. State 350.65065065065068
    00:00/00:00
  • 2a) Eigenenergy vs. State 13. 2a) Eigenenergy vs. State 360.16016016016016
    00:00/00:00
  • 2a) Eigenenergy vs. State 14. 2a) Eigenenergy vs. State 362.16216216216219
    00:00/00:00
  • 2a) Eigenenergy vs. State 15. 2a) Eigenenergy vs. State 364.19753086419752
    00:00/00:00
  • 2a) Eigenenergy vs. State 16. 2a) Eigenenergy vs. State 366.53319986653321
    00:00/00:00
  • 2b) 3D Wave Function 17. 2b) 3D Wave Function 428.62862862862863
    00:00/00:00
  • Quantum Dot Lab Problem 3 18. Quantum Dot Lab Problem 3 511.91191191191194
    00:00/00:00
  • 3a) Eigenenergy vs. State 19. 3a) Eigenenergy vs. State 550.61728395061732
    00:00/00:00
  • 3a) Eigenenergy vs. State 20. 3a) Eigenenergy vs. State 584.51785118451789
    00:00/00:00
  • 3a) Eigenenergy vs. State 21. 3a) Eigenenergy vs. State 613.48014681348013
    00:00/00:00
  • 3a) Eigenenergy vs. State 22. 3a) Eigenenergy vs. State 623.22322322322327
    00:00/00:00
  • 3a) Eigenenergy vs. State 23. 3a) Eigenenergy vs. State 626.12612612612611
    00:00/00:00
  • 3b) 3D Wave Function 24. 3b) 3D Wave Function 670.2369035702369
    00:00/00:00
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