Tags: nanoelectronics

Description

Progress in technology has brought microelectronics to the nanoscale, but nanoelectronics is not yet a well-defined engineering discipline with a coherent, experimentally verified, theoretical framework. The NCN has a vision for a new, 'bottom-up' approach to electronics, which involves: understanding electronic conduction at the atomistic level; formulating new simulation techniques; developing a new generation of software tools; and bringing this new understanding and perspective into the classroom. We address problems in atomistic phenomena, quantum transport, percolative transport in inhomogeneous media, reliability, and the connection of nanoelectronics to new problems such as biology, medicine, and energy. We work closely with experimentalists to understand nanoscale phenomena and to explore new device concepts. In the course of this work, we produce open source software tools and educational resources that we share with the community through the nanoHUB.

This page is a starting point for nanoHUB users interested in nanoelectronics. It lists key resources developed by the NCN Nanoelectronics team. The nanoHUB contains many more resources for nanoelectronics, and they can be located with the nanoHUB search function. To find all nanoelectronics resources, search for 'nanoelectronics.' To find those contributed by the NCN nanoelectronics team, search for 'NCNnanoelectronics.' More information on Nanoelectronics can be found here.

All Categories (61-80 of 2050)

  1. Circuits on Cellulose: From Transistors to LEDs, from Displays to Microfluidics on Paper

    14 Feb 2017 | | Contributor(s):: Andrew Steckl

    In this lecture I will review the use of cellulose-based paper as a material in a variety of electronic (and related) applications, including transistors, light emitting diodes, displays, microfluidics. Paper is a very attractive material for many device applications: very low cost, available in...

  2. Topological Spintronics: from the Haldane Phase to Spin Devices

    31 Jan 2017 | | Contributor(s):: Nitin Samarth

    e provide a perspective on the recent emergence of “topological spintronics,” which relies on the existence of helical Dirac electrons in condensed matter. Spin‐ and angle‐resolved photoemission spectroscopy shows how the spin texture of these electronic states can be engineered...

  3. Abhijith Ananthan

    https://nanohub.org/members/161798

  4. jesus alexis Gonzalez

    https://nanohub.org/members/161639

  5. Shaik Jani Babu

    https://nanohub.org/members/161382

  6. abhishek kumar

    https://nanohub.org/members/160954

  7. Akhil Devdas Prabhu

    https://nanohub.org/members/160853

  8. Sourangsu Banerji

    Sourangsu is pursuing his PhD in the Department of Electrical and Computer Engineering at University of Utah, USA. He finished his B.Tech. in 2014, from West Bengal University of Technology ,...

    https://nanohub.org/members/160236

  9. Arif Hossain

    https://nanohub.org/members/159206

  10. Modeling of Inter-ribbon Tunneling in Graphene

    11 Nov 2016 | | Contributor(s):: Maarten Van de Put, William Gerard Hubert Vandenberghe, Massimo V Fischetti

    IWCE presentation. In this paper we investigate the finite-size effect in nano-scaled graphene flakes. Improving on the bulk description, and because the structures are – atomistically speaking – large in size, we use the empirical pseudopotential method[2].

  11. NEMO5, a Parallel, Multiscale, Multiphysics Nanoelectronics Modeling Tool
: From Basic Physics to Real Devices and to Global Impact on nanoHUB.org

    10 Nov 2016 | | Contributor(s):: Gerhard Klimeck

    The Nanoelectronic Modeling tool suite NEMO5 is aimed to comprehend the critical multi-scale, multi-physics phenomena and deliver results to engineers, scientists, and students through efficient computational approaches. NEMO5’s general software framework easily includes any kind of...

  12. Low Temperature Enhancement of the Thermoelectric Seebeck Coefficient in Semiconductor Nanoribbons

    09 Nov 2016 | | Contributor(s):: Kommini Adithya, Zlatan Aksamija

    IWCE 2015 Presentation. We propose a novel approach to achieving a narrow window-shaped TDF through a combination of a step-like 2-dimensional density-of-states (DOS) and inelastic optical phonon scattering. A shift in the onset of scattering with respect to the step-like DOS creates a TDF which...

  13. LAMMPS structure generator

    01 Nov 2016 | | Contributor(s):: Benjamin P Haley

    Convert a molecular structure file to a LAMMPS data file with force field parameters

  14. Finite Difference Schemes for k.p Models: A Comparative Study

    21 Oct 2016 | | Contributor(s):: Jun Huang, Kuang-Chung Wang, William R Frensley, Gerhard Klimeck

    IWCE 2015 Presentation.

  15. 15-Band Spectral Envelope Function Formalism Applied to Broken Gap Tunnel Field-Effect Transistors

    21 Oct 2016 | | Contributor(s):: Devin Verreck, Maarten Van de Put, Anne Verhulst, Bart Soree, G. Groeseneken, Ashish Dabral

    IWCE 2015 presentation.

  16. OpenKIM Explorer

    09 Jun 2015 | | Contributor(s):: Benjamin P Haley, Dan Karls, Alejandro Strachan, Ryan S Elliott, Ellad B Tadmor

    Query the OpenKIM repository for names of interatomic Models for simulating selected materials

  17. The Role of Dimensionality on Phonon-Limited Charge Transport: from CNTs to Graphene

    21 Oct 2016 | | Contributor(s):: Jing Li, Yann-Michel Niquet

    IWCE 2015 presentation.

  18. M-file/Mif Automatic GEnerator

    23 Sep 2016 | | Contributor(s):: Jakub Chęciński

    A GUI tool for automatic generation of OOMMF configuration files and Matlab scripts for results analysis

  19. Transferable Tight Binding Model for Strained Heterostructures

    21 Oct 2016 | | Contributor(s):: Yaohua Tan, Michael Povolotskyi, Tillmann Christoph Kubis, Timothy Boykin, Gerhard Klimeck

    IWCE 2015 presentation.

  20. NEMO5 and 2D Materials: Tuning Bandstructures, Wave Functions and Electrostatic Screening

    18 Oct 2016 | | Contributor(s):: Tillmann Christoph Kubis

    In this talk, I will briefly discuss the MLWF approach and compare it to DFT and atomistic tight binding. Initial results using the MLWF approach for 2D material based devices will be discussed and compared to experiments. These results unveil systematic band structure changes as functions of...