
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 multiscale, multiphysics phenomena and deliver results to engineers, scientists, and students through efficient computational approaches. NEMO5’s general software framework easily includes any kind of...

NEMO5, a Parallel, Multiscale, Multiphysics Nanoelectronics Modeling Tool
19 Sep 2016   Contributor(s):: Gerhard Klimeck
The Nanoelectronic Modeling tool suite NEMO5 is aimed to comprehend the critical multiscale, multiphysics phenomena and deliver results to engineers, scientists, and students through efficient computational approaches. NEMO5’s general software framework easily includes any kind of...

E304 L3.3.2: Nanoscale Physics  Wavefunctions and the Infinite Potential Well
16 Mar 2016 

NEMO5 Tutorial 5C: Quantum Dots with Strain and Electronic Wave Functions
18 Jul 2012   Contributor(s):: Yuling Hsueh

NEMO5 Tutorial 3: Models
17 Jul 2012   Contributor(s):: Jean Michel D Sellier
This tutorial presents the models implemented in NEMO5. A description on how the solvers interact with each other is reported along with the options of the various solvers. An example on how to make a simulation that involves strain calculations, Schroedinger wave functions calculations and an...

Largescale first principles configuration interaction calculations of optical absorption in boron clusters
07 Mar 2012   Contributor(s):: Ravindra L Shinde
We have performed systematic largescale allelectron correlated calculations on boron clustersBn (n=2–5), to study their linear optical absorption spectra. Several possible isomers of each cluster were considered, and their geometries were optimized at the coupledcluster singles doubles(CCSD)...

Quantum Dot Wave Function (Quantum Dot Lab)
02 Feb 2011   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) selfassembled quantum dot.

SelfAssembled Quantum Dot Structure (pyramid)
02 Feb 2011   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.

Quantum Dot Wave Function (still image)
31 Jan 2011   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) selfassembled quantum dot.

SelfAssembled Quantum Dot Wave Structure
31 Jan 2011   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.

Tutorial 3b: Materials Simulation by FirstPrinciples Density Functional Theory II
14 Sep 2010   Contributor(s):: Umesh V. Waghmare

Nanoelectronic Modeling Lecture 35: Alloy Disorder in Nanowires
05 Aug 2010   Contributor(s):: Gerhard Klimeck, Timothy Boykin, Neerav Kharche, Mathieu Luisier, Neophytos Neophytou
This presentation discusses the consequences of Alloy Disorder in unstrained strained AlGaAs nanowiresRelationship between dispersion relationship and transmission in perfectly ordered wiresBand folding in Si nanowiresTranmisison in disordered wires – relationship to an approximate...

Nanoelectronic Modeling Lecture 31a: LongRange Strain in InGaAs Quantum Dots
04 Aug 2010   Contributor(s):: Gerhard Klimeck
This presentation demonstrates the importance of longrange strain in quantum dotsNumerical analysis of the importance of the buffer around the central quantum dot  local band edges – vertical and horizontal extension of the bufferControlled overgrowth can tune the electron energies in the...