Confined electrons are found everywhere in nature in the form of atoms in which the Coulomb attraction of the nucleus confines the orbiting electrons. Nanotechnology has provided us an alternative way to confine electrons by means of an artificial confining potential. Quantum dots are typical examples that represent nanoscale systems made of a few confined electrons. There are many types of quantum dots, ranging from self-assembled to lithographically engineered semiconductor quantum dots. In this work we mostly describe electrostatically confined semiconductor quantum dots where the electrostatic confining potential is generated by external electrodes, doping, strain, or other factors. The main focus of this contribution is on low-dimensio...
Semiconducting quantum dots, whose particle sizes are in the nanometer range, have very unusual prop...
This paper discusses the growth and the properties of semiconductor nanostructures based on self-ass...
Semiconductor quantum dots are usually compared to artificial atoms, because their electronic struct...
Systems of confined electrons are found everywhere in nature in the form of atoms where the orbiting...
Semiconductor quantum dots represent nanoscale systems with few electrons confined in a semiconducto...
Recent advances in the field of nanotechnology have enabled the precise, controlled fabrication of m...
This paper will review atomic-like phenomena in a semiconductor quantum dot which their size, shape ...
This paper will review otomic-like phenomena in a semiconductor quantum dot which their size, shape ...
Self-assembled semiconductor quantum dots confine single carriers on the nanometer-scale. For the co...
Pulsed magnetic fields are used to study a variety of self-assembled semiconductor nanostructures. W...
Semiconductor quantum dots are artificial nanoscale systems in which charge carriers, such as electr...
Our recent work on the electronic and optical properties of semiconductor and graphene quantum dots ...
Quantum dots, also known as artificial atoms, are created by tightly confining electrons, and thereb...
We explore two routes to wave function engineering in elongated colloidal CdSe/CdS quantum dots, pro...
Usually, semiconductor quantum dots represent a two-dimensional nanoscale system with few electrons ...
Semiconducting quantum dots, whose particle sizes are in the nanometer range, have very unusual prop...
This paper discusses the growth and the properties of semiconductor nanostructures based on self-ass...
Semiconductor quantum dots are usually compared to artificial atoms, because their electronic struct...
Systems of confined electrons are found everywhere in nature in the form of atoms where the orbiting...
Semiconductor quantum dots represent nanoscale systems with few electrons confined in a semiconducto...
Recent advances in the field of nanotechnology have enabled the precise, controlled fabrication of m...
This paper will review atomic-like phenomena in a semiconductor quantum dot which their size, shape ...
This paper will review otomic-like phenomena in a semiconductor quantum dot which their size, shape ...
Self-assembled semiconductor quantum dots confine single carriers on the nanometer-scale. For the co...
Pulsed magnetic fields are used to study a variety of self-assembled semiconductor nanostructures. W...
Semiconductor quantum dots are artificial nanoscale systems in which charge carriers, such as electr...
Our recent work on the electronic and optical properties of semiconductor and graphene quantum dots ...
Quantum dots, also known as artificial atoms, are created by tightly confining electrons, and thereb...
We explore two routes to wave function engineering in elongated colloidal CdSe/CdS quantum dots, pro...
Usually, semiconductor quantum dots represent a two-dimensional nanoscale system with few electrons ...
Semiconducting quantum dots, whose particle sizes are in the nanometer range, have very unusual prop...
This paper discusses the growth and the properties of semiconductor nanostructures based on self-ass...
Semiconductor quantum dots are usually compared to artificial atoms, because their electronic struct...