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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.
Purdue University Bifacial Module Calculator (PUB)
20 Feb 2018 | Contributor(s):: Binglin Zhao, Xingshu Sun, Mohammad Ryyan Khan, Muhammad Ashraful Alam
A tool to simulate and optimize the energy yield of both bifacial and monofacial solar modules
SPICE Subcircuit Generator for Ferromagnetic Nanomaterials
05 Feb 2018 | Contributor(s):: Onur Dincer, Azad Naeemi
Generates SPICE subcircuit netlist for ferromagnetic nanometarials for spintronic devices
Electrostatic Properties Simulation of Layered 2D Material Devices
out of 5 stars
07 Aug 2017 | | Contributor(s):: Abhinandan Borah, Jamie Teherani
Simulate charge carrier density, potential drop and energy band diagram across any vertical 1D cross-section in a layered heterostructure of 2D semiconductors, graphene and metals.
Spectral analysis of non-equilibrium molecular dynamics
28 Jun 2017 | | Contributor(s):: Tianli Feng, Yang Zhong, Divya Chalise, Xiulin Ruan
Extract the phonon modal temperature and heat flux from non-equilibrium molecular dynamics
Specific Resistance for Copper Interconnects
15 Nov 2017 | | Contributor(s):: Daniel A. Valencia-Hoyos, Gustavo A Valencia, Daniel F Mejia, Kuang-Chung Wang, Zhengping Jiang, Gerhard Klimeck, Michael Povolotskyi
This tool calculates the specific resistance $rho(alpha,beta,gamma)$ based on the atomistic model reported in preprint arXiv:1701.04897
Purdue University Meteorological Tool
24 Oct 2017 | | Contributor(s):: Binglin Zhao, Xingshu Sun, Mohammad Ryyan Khan, Muhammad Ashraful Alam
Provide meteorological data from national databases.
LAMMPS Data-File Generator
01 Aug 2017 | | Contributor(s):: Carlos Miguel Patiño, Lorena Alzate-Vargas, Chunyu Li, Benjamin P Haley, Alejandro Strachan
This tool generates all necessary input files for LAMMPS simulations of molecular systems starting with an atomistic structure.
Electron Transport in Schottky Barrier CNTFETs
24 Oct 2017 | | Contributor(s):: Igor Bejenari
A given review describes models based on Wentzel-Kramers-Brillouin approximation, which are used to obtain I-V characteristics for ballistic CNTFETs with Schottky-Barrier (SB) contacts. The SB is supposed to be an exponentially or linearly decaying function along the channel. The ...
20 Jul 2017 | | Contributor(s):: Joseph Anderson
Simulate molecular dynamics using LAMMPS as well as an addition electrochemical force field (EChemDID)
SPICE Subcircuit Generator for Spintronic Nonmagnetic Metallic Channel Components
23 Sep 2017 | | Contributor(s):: Onur Dincer, Azad Naeemi
Generates SPICE subcircuit netlist for electronic and spintronic transport in nanoscale nonmagnetic metallic channels
Monte Carlo Phonon Transport Simulator
30 Aug 2017 | | Contributor(s):: Mohammad Zunaidur Rashid, Sasi Sekaran Sundaresan, Shaikh S. Ahmed
Calculates thermal conductivity of semiconductors by solving the Boltzmann transport equation via particle-based Monte Carlo method
Quantum Dot Lab via Jupyter
30 Aug 2017 | | Contributor(s):: Khaled Aboumerhi, Tarek Ahmed Ameen, Prasad Sarangapani, Daniel F Mejia, Gerhard Klimeck
Simulate 3-D confined states in quantum dot geometries using Jupyter notebook for educational purposes
28 Sep 2016 | | Contributor(s):: Ricardo Carvalho de Melos
A RTN behavior Simulation Tool
Quantum Spins in the Solid-State: An Atomistic Material-to-Device Modeling Approach
28 Aug 2017 | | Contributor(s):: Rajib Rahman
In this talk, I will present an atomistic modeling approach that combines intrinsic material and extrinsic device properties under a unified framework to describe spins and their interactions with theenvironment. This approach captures important spin properties such as exchange, spin-orbit,...
Spin Transport Modeling Tool
21 Aug 2017 | | Contributor(s):: Onur Dincer, Azad Naeemi
Calculates spin transport parameters in nanoscale metallic interconnects.
MEM oscillator network application simulation
30 Jul 2017 | | Contributor(s):: Xinrui Wang
Simulate pattern recognition and convolution using a MEMS oscillator network solver. (To get started, click dashboard preview and go to "run all" under menu "cell".)
Spin-Orbitronics: A Route to Control Magnets via Spin-Orbit Interaction
20 Jul 2017 | | Contributor(s):: Upadhyaya, Pramey
In this talk, I will present this “spin-orbitronic” control for various magnetic systems. In particular, we will focus on the example of spin-orbit-induced manipulation of magnetic domain walls and skyrmions, i.e. particle-like magnetic configurations capable of storing and...
19 Jul 2017 | | Contributor(s):: Martin Hunt
Edit a Lua script for the Stanford Stratified Structure Solver and visualize the output
Building a Topological Quantum Computer 101
19 Jun 2017 | | Contributor(s):: Michael Freedman
Michael Freeman shares his perspective on how we should approach building a quantum computer, starting with the mathematical roots and moving through the physics to concrete engineering and materials growth challenges on which success will hinge. He will then discuss a new, enhanced,...
Soft, Biocompatible Optoelectronic Interfaces to the Brain
07 Jun 2017 | | Contributor(s):: John A. Rogers
In this talk, we will describe foundational concepts in physics and materials science for these types of technologies, in 1D, 2D and 3D architectures. Examples in system level demonstrations include experiments on freely moving animals with ‘cellular-scale’, injectable optofluidic...