Add to ORKGWe apply the exact numerical diagonalization technique to study two interacting electrons in a one-dimensional parabolic quantum dot. We consider a modified Coulomb interaction potential between the electrons with a truncation parameter that serves to regularize the behaviour of the bare Coulomb potential in one dimension. We report the dependence of ground and excited state energies for several values of the truncation parameter as the strength of electronic correlations is varied relative to the confinement energy. The similarity of this quantum dot system to the ammonia molecule is pointed out. © IOP Publishing Ltd
Quantum chemical methods originally developed for studying atomic and molecular systems can be appli...
PDFLaTeX, RevTeX, 12 pages with 16 included pdf figuresInternational audienceWe compare the response...
The few-particle state of carriers confined in a quantum dot is controlled by the balance between th...
We apply the exact numerical diagonalization technique to study two interacting electrons in a one-d...
We investigate the properties of interacting electrons in a parabolic confinement. To this end we nu...
One of the standard approaches to calculate the ground-state properties of strongly correlated elect...
Quantum dots are intricate and fascinating systems to study novel phenomena of great theoretical and...
A calculation of the variations of the energy and oscillator strength of the ground state of an exci...
Exact solutions of the eigenstates of two-interacting electron quantum dot nanostructures in an exte...
We investigate the momentum distribution of interacting electrons confined in a two-dimensional para...
In this study, we develop and demonstrate an efficient self-consistent calculation schema that compu...
In this work, we propose an efficient method of reducing the computational effort of variational cal...
p.1-11A variational method called discrete variable representation is applied to study the energy sp...
The low-energy eigenstates of two interacting electrons in a square quantum dot in a magnetic field ...
Recent advances in the field of nanotechnology have enabled the precise, controlled fabrication of m...
Quantum chemical methods originally developed for studying atomic and molecular systems can be appli...
PDFLaTeX, RevTeX, 12 pages with 16 included pdf figuresInternational audienceWe compare the response...
The few-particle state of carriers confined in a quantum dot is controlled by the balance between th...
We apply the exact numerical diagonalization technique to study two interacting electrons in a one-d...
We investigate the properties of interacting electrons in a parabolic confinement. To this end we nu...
One of the standard approaches to calculate the ground-state properties of strongly correlated elect...
Quantum dots are intricate and fascinating systems to study novel phenomena of great theoretical and...
A calculation of the variations of the energy and oscillator strength of the ground state of an exci...
Exact solutions of the eigenstates of two-interacting electron quantum dot nanostructures in an exte...
We investigate the momentum distribution of interacting electrons confined in a two-dimensional para...
In this study, we develop and demonstrate an efficient self-consistent calculation schema that compu...
In this work, we propose an efficient method of reducing the computational effort of variational cal...
p.1-11A variational method called discrete variable representation is applied to study the energy sp...
The low-energy eigenstates of two interacting electrons in a square quantum dot in a magnetic field ...
Recent advances in the field of nanotechnology have enabled the precise, controlled fabrication of m...
Quantum chemical methods originally developed for studying atomic and molecular systems can be appli...
PDFLaTeX, RevTeX, 12 pages with 16 included pdf figuresInternational audienceWe compare the response...
The few-particle state of carriers confined in a quantum dot is controlled by the balance between th...