Add to ORKGWe construct an optimal set of single-particle states for few-electron quantum dots (QDs) using the method of natural orbitals (NOs). The NOs include also the effects of the Coulomb repulsion between electrons. We find that they agree well with the noniteracting orbitals for GaAs QDs of realistic parameters, while the Coulomb interactions only rescale the radius of the NOs compared to the noninteracting case. We use NOs to show that four-electron QDs are less susceptible to charge noise than their two-electron counterparts
Self-assembled semiconductor quantum dots confine single carriers on the nanometer-scale. For the co...
We study acoustic-phonon-induced relaxation of charge excitations in single and tunnel-coupled quant...
Though atoms and quantum dots typically contain a comparable number of electrons, the number of disc...
We construct an optimal set of single-particle states for few-electron quantum dots (QDs) using the ...
We investigate experimentally and theoretically few-particle effects in the optical spectra of singl...
Singlet-triplet spin qubits in six-electron double quantum dots, in moderate magnetic fields, can sh...
We investigate theoretically Raman spectra of few-electron quantum dots. Spectra obtained by an exac...
We report the investigation of electronic excitations in InGaAs self-assembled quantum dots using re...
We discuss the quantum dot-ring nanostructure (DRN) as canonical example of a nanosystem, for which ...
The problem of two electrons in a three-dimensional quantum dot with Gaussian confinement is investi...
Based upon the tunneling Hamiltonian, the lifetime of electrons in the quasibound state of quantum d...
We study the effect of Coulomb interaction on the few-electron dynamics in coupled semiconductor qua...
We discuss decoherence in charge qubits formed by multiple lateral quantum dots in the framework of ...
The time evolution of the quantum mechanical state of an electron is calculated in the framework of ...
We consider the system of an electronic quantum dot with a base set of discrete single-particle leve...
Self-assembled semiconductor quantum dots confine single carriers on the nanometer-scale. For the co...
We study acoustic-phonon-induced relaxation of charge excitations in single and tunnel-coupled quant...
Though atoms and quantum dots typically contain a comparable number of electrons, the number of disc...
We construct an optimal set of single-particle states for few-electron quantum dots (QDs) using the ...
We investigate experimentally and theoretically few-particle effects in the optical spectra of singl...
Singlet-triplet spin qubits in six-electron double quantum dots, in moderate magnetic fields, can sh...
We investigate theoretically Raman spectra of few-electron quantum dots. Spectra obtained by an exac...
We report the investigation of electronic excitations in InGaAs self-assembled quantum dots using re...
We discuss the quantum dot-ring nanostructure (DRN) as canonical example of a nanosystem, for which ...
The problem of two electrons in a three-dimensional quantum dot with Gaussian confinement is investi...
Based upon the tunneling Hamiltonian, the lifetime of electrons in the quasibound state of quantum d...
We study the effect of Coulomb interaction on the few-electron dynamics in coupled semiconductor qua...
We discuss decoherence in charge qubits formed by multiple lateral quantum dots in the framework of ...
The time evolution of the quantum mechanical state of an electron is calculated in the framework of ...
We consider the system of an electronic quantum dot with a base set of discrete single-particle leve...
Self-assembled semiconductor quantum dots confine single carriers on the nanometer-scale. For the co...
We study acoustic-phonon-induced relaxation of charge excitations in single and tunnel-coupled quant...
Though atoms and quantum dots typically contain a comparable number of electrons, the number of disc...