Low-loss optical communication requires light sources at 1.5 mu m wavelengths. Experiments showed, without much theoretical guidance, that InAs/GaAs quantum dots (QDs) may be tuned to such wavelengths by adjusting the In fraction in an InxGa1-xAs strain-reducing capping layer. In this paper, systematic multimillion-atom electronic structure calculations explain, qualitatively and quantitatively, for the first time, available experimental data. The nanoelectronic modeling NEMO 3-D simulations treat strain in a 15-million-atom system and electronic structure in a subset of similar to 9 million atoms using the experimentally given nominal geometries, and without any further parameter adjustments, the simulations match the nonlinear behavior of...
Device physics and material science meet at the atomic scale of novel nanostructured semiconductors,...
InAs/GaAs quantum dot systems can emit light at the wavelengths above 1.3μm by covering the InAs qua...
Strain and electronic structure of InAs/GaAs quantum dot molecules made up of identical and non-iden...
Low-loss optical communication requires light sources at 1.5μmwavelengths.Experiments showed,without...
Quantum dots grown by self-assembly process are typically constructed by 50,000 to 5,000,000 structu...
Material layers with a thickness of a few nanometers are common-place in today’s semiconductor devic...
Strain in self-assembled quantum dots is a long-range phenomenon, and its realistic determination re...
Coherent coupling and formation of molecular orbitals in vertically coupled quantum-dot molecules is...
Abstract: Material layers with a thickness of a few nanometers are common-place in today’s semicondu...
Abstract―In Part−I, development and deployment of a general Nanoelectronic Modeling tool (NEMO 3-D) ...
A new capability of our well-known NEMO 3-D simulator (Ref. Klimeck et al., 2007 [10]) is introduced...
Abstract: Material layers with a thickness of a few nanometers are common-place in today’s semicondu...
In Part 1, the development and deployment of a general nanoelectronic modeling tool (NEMO 3-D) has b...
The rapid progress in nanofabrication technologies has led to the development of novel devices and s...
As applications in nanotechnology reach the scale of countable atoms, computer simulation has become...
Device physics and material science meet at the atomic scale of novel nanostructured semiconductors,...
InAs/GaAs quantum dot systems can emit light at the wavelengths above 1.3μm by covering the InAs qua...
Strain and electronic structure of InAs/GaAs quantum dot molecules made up of identical and non-iden...
Low-loss optical communication requires light sources at 1.5μmwavelengths.Experiments showed,without...
Quantum dots grown by self-assembly process are typically constructed by 50,000 to 5,000,000 structu...
Material layers with a thickness of a few nanometers are common-place in today’s semiconductor devic...
Strain in self-assembled quantum dots is a long-range phenomenon, and its realistic determination re...
Coherent coupling and formation of molecular orbitals in vertically coupled quantum-dot molecules is...
Abstract: Material layers with a thickness of a few nanometers are common-place in today’s semicondu...
Abstract―In Part−I, development and deployment of a general Nanoelectronic Modeling tool (NEMO 3-D) ...
A new capability of our well-known NEMO 3-D simulator (Ref. Klimeck et al., 2007 [10]) is introduced...
Abstract: Material layers with a thickness of a few nanometers are common-place in today’s semicondu...
In Part 1, the development and deployment of a general nanoelectronic modeling tool (NEMO 3-D) has b...
The rapid progress in nanofabrication technologies has led to the development of novel devices and s...
As applications in nanotechnology reach the scale of countable atoms, computer simulation has become...
Device physics and material science meet at the atomic scale of novel nanostructured semiconductors,...
InAs/GaAs quantum dot systems can emit light at the wavelengths above 1.3μm by covering the InAs qua...
Strain and electronic structure of InAs/GaAs quantum dot molecules made up of identical and non-iden...