Tags: simulation and modeling of nanoscale transistors/devies

All Categories (1-20 of 21)

  1. Qt Z

    http://nanohub.org/members/108116

  2. Pawan Shantaram Rewatkar

    http://nanohub.org/members/105699

  3. Jeronimo Peralta

    PhD in Physics, University of Buenos AiresResearcher in transport phenomena, device physics.

    http://nanohub.org/members/101149

  4. Hitesh Kamble

    I'm working at IIT Bombay Nanofabrication Facility, Mumbai, IN. My expertise lies in semiconductor nano/microfabrication process technologies.

    http://nanohub.org/members/93922

  5. Atif Awan

    FROM THE LAND OF PARADISE ON EARTH '''__THE AZAD JAMMU & KASHMIR__'''

    http://nanohub.org/members/83974

  6. Roman Beletsky

    http://nanohub.org/members/80796

  7. julio cesar bolanos

    http://nanohub.org/members/65010

  8. Manuel Toledo

    http://nanohub.org/members/62103

  9. NEMO3D User Guide for Quantum Dot Simulations

    29 Nov 2011 | Papers | Contributor(s): M. Usman, Gerhard Klimeck

    NEMO 3D is a large and complex simulator; and understanding of its source code requires considerable knowledge of quantum mechanics, condensed matter theory, and parallel programming.

    http://nanohub.org/resources/12593

  10. ZAHRA AHANGARI

    http://nanohub.org/members/56016

  11. Quantum Dot Wave Function (Quantum Dot Lab)

    02 Feb 2011 | Animations | Contributor(s): Gerhard Klimeck, David S. Ebert, Wei Qiao

    Electron density of an artificial atom. The animation sequence shows various electronic states in an Indium Arsenide (InAs)/Gallium Arsenide (GaAs) self-assembled quantum dot.

    http://nanohub.org/resources/10751

  12. Self-Assembled Quantum Dot Structure (pyramid)

    02 Feb 2011 | Animations | Contributor(s): Gerhard Klimeck, Insoo Woo, Muhammad Usman, David S. Ebert

    Pyramidal InAs Quantum dot. The quantum dot is 27 atomic monolayers wide at the base and 15 atomic monolayers tall.

    http://nanohub.org/resources/10730

  13. Quantum Dot Wave Function (still image)

    31 Jan 2011 | Animations | Contributor(s): Gerhard Klimeck, David S. Ebert, Wei Qiao

    Electron density of an artificial atom. The image shown displays the excited electron state in an Indium Arsenide (InAs) / Gallium Arsenide (GaAs) self-assembled quantum dot.

    http://nanohub.org/resources/10692

  14. Self-Assembled Quantum Dot Wave Structure

    31 Jan 2011 | Animations | Contributor(s): Gerhard Klimeck, Insoo Woo, Muhammad Usman, David S. Ebert

    A 20nm wide and 5nm high dome shaped InAs quantum dot grown on GaAs and embedded in InAlAs is visualized.

    http://nanohub.org/resources/10689

  15. Electron Density in a Nanowire

    30 Jan 2011 | Animations | Contributor(s): Gerhard Klimeck, Saumitra Raj Mehrotra

    Electron Density in a circular Silicon nanowire transistor.

    http://nanohub.org/resources/10666

  16. Tunneling in an Nanometer-Scaled Transistor

    25 Jan 2011 | Animations | Contributor(s): Gerhard Klimeck, Mathieu Luisier, Neerav Kharche, George A. Howlett, Insoo Woo, David Ebert

    Electrons tunneling through the gate of an ultra-scaled transistor.

    http://nanohub.org/resources/10537

  17. Karim Ahmed Elgammal

    I am a PhD student at the Royal Institute of Technology ()

    http://nanohub.org/members/47839

  18. Hesameddin Ilatikhameneh

    http://nanohub.org/members/42735

  19. Nanoelectronic Modeling Lecture 22: NEMO1D - Motivation, History and Key Insights

    07 Feb 2010 | Online Presentations | Contributor(s): Gerhard Klimeck

    The primary objective of the NEMO-1D tool was the quantitative modeling of high performance Resonant Tunneling Diodes (RTDs). The software tool was intended for Engineers (concepts, fast...

    http://nanohub.org/resources/8389

  20. MOSFet Demonstration: MOSFET Device Simulation and Analysis

    11 Jun 2009 | Animations | Contributor(s): Gerhard Klimeck, Benjamin P Haley

    This video shows the simulation and analysis of a MOSFET device using the MOSFet tool. Several powerful analytic features of this tool are demonstrated.

    http://nanohub.org/resources/6830