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Tools

• 9.8 Ranking Klimeck: Quantum Dot Lab

  Quantum Dot Lab

  Type	Tools
  Contributor(s)	Gerhard Klimeck, Matteo Mannino, Michael McLennan, Wei Qiao, David Ebert, Xufeng Wang
  Date	12 Nov. 2005
  Avg. Rating	5.0 out of 5 stars  (11)
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  Compute the eigenstates of a particle in a box of various shapes including domes and pyramids.

• 9.7 Ranking Vasileska: Schred

  Schred

  Type	Tools
  Contributor(s)	Dragica Vasileska, Shaikh S. Ahmed, Matteo Mannino, Akira Matsudaira, Gerhard Klimeck, Mark Lundstrom
  Date	09 Feb. 2006
  Avg. Rating	5.0 out of 5 stars  (4)
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  Calculates the envelope wavefunctions and the corresponding bound-state energies in a typical MOS (Metal-Oxide-Semiconductor) or SOS (Semiconductor-Oxide- Semiconductor) structure and a typical SOI structure

• 8.6 Ranking Wagner: QWalk: Quantum Monte Carlo

  QWalk: Quantum Monte Carlo

  Type	Tools
  Contributor(s)	Lucas Wagner, Jeffrey C Grossman, Jeffrey B. Neaton
  Date	15 Jun. 2007
  Avg. Rating	5.0 out of 5 stars  (2)
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  Quantum Monte Carlo methods solve the Schrodinger equation for many electrons to high accuracy--exactly in some cases. In most implementations, it also has favorable scaling with system size, approximately the same as mean-field theories like density functional theory, although with a larger ...

• 7.3 Ranking Tejerina: UV/Vis Spectra simulator

  UV/Vis Spectra simulator

  Type	Tools
  Contributor(s)	Baudilio Tejerina
  Date	15 Apr. 2008
  Avg. Rating	0.0 out of 5 stars  (0)
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  Molecular electronic spectra

• 7.0 Ranking Gavrilenko: Quantum Bound State

  Quantum Bound State

  Type	Tools
  Contributor(s)	Alexander Gavrilenko, Heng Li
  Date	17 May. 2007
  Avg. Rating	0.0 out of 5 stars  (0)
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  Particle in a box - The particle in a box (or the infinite potential well) is a simple idealized system that is completely solved within quantum mechanics. The infinite potential well is a finite sized region in space (the box) with an infinite potential at its boundaries (the walls). A particle ...

• 7.0 Ranking Hahm: Electrostatic simulation for SOI ...

  Electrostatic simulation for SOI Trigate

  Type	Tools
  Contributor(s)	Hyung-Seok Hahm, Andres Godoy
  Date	04 Mar. 2008
  Avg. Rating	0.0 out of 5 stars  (0)
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  Generate classical and quantum electrostatic simulation results in a SOI Trigate geometry

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Online Presentations

• 8.9 Ranking Wagner: The basics of quantum Monte Carlo

  The basics of quantum Monte Carlo

  Type	Online Presentations
  Contributor(s)	Lucas Wagner, Jeffrey C Grossman, Jeffrey B. Neaton
  Date	18 Jun. 2007
  Avg. Rating	4.5 out of 5 stars  (3)
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  Quantum Monte Carlo is a highly accurate method to approximately solve the Schrodinger equation. I explain quantum Monte Carlo in a way that should be accessible to someone who is somewhat familiar with quantum mechanics. The discussion is mostly conceptual.Lucas Wagner is a postdoctoral ...

Learning Modules

• 10.0 Ranking Fodor: Introduction to Quantum Dot Lab

  Introduction to Quantum Dot Lab

  Type	Learning Modules
  Contributor(s)	James K Fodor, Jing Guo
  Date	02 Jul. 2007
  Avg. Rating	0.0 out of 5 stars  (0)
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  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 ...

• 6.3 Ranking Vasileska: Modeling Single and Dual-Gate ...

  Modeling Single and Dual-Gate Capacitors using SCHRED

  Type	Learning Modules
  Contributor(s)	Dragica Vasileska
  Date	31 Mar. 2006
  Avg. Rating	0.0 out of 5 stars  (0)
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  SCHRED stands for self-consistent solver of the 1D Poisson and 1D effective mass Schrodinger equation as applied to modeling single gate or dual-gate capacitors. The program incorporates many features such as choice of degenerate and non-degenerate statistics for semiclassical charge description, ...

• 5.7 Ranking Fodor: Introduction to Schred

  Introduction to Schred

  Type	Learning Modules
  Contributor(s)	James K Fodor, Jing Guo
  Date	28 Jun. 2007
  Avg. Rating	0.0 out of 5 stars  (0)
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  This learning module introduces nanoHUB users to the Schred simulator. A brief introduction to Schred 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 ...