We investigate theoretically Raman spectra of few-electron quantum dots. Spectra obtained by an exact many-body treatment and by a time-dependent local-density approximation are compared. We show that single-particle-like excitations can be expected for systems with only six electrons. The energies of these excitations are close to the Kohn-Sham level spacings
Quantum many-body states of up to four excitons are studied in small parallelepipedal quantum dots w...
We analyze few-particle effects in the optical spectra of semiconductor quantum dots using a density...
We investigate the effects of few-particle population of a single strain-induced quantum dot by opti...
We investigate theoretically Raman spectra of few-electron quantum dots. Spectra obtained by an exac...
In this article we review our recent experimental and theoretical investigations of electronic excit...
We investigate experimentally and theoretically few-particle effects in the optical spectra of singl...
We have investigated electronic excitations in GaAs-AlxGa1-xAs quantum wires, and dots by resonance ...
We investigate theoretically and experimentally the resonant Raman scattering on modulation-doped, d...
Advances in submicron technology make it possible to realize man-made low-dimensional electronic sys...
Electronic Raman scattering provides information on excited states, whose collective character as be...
We theoretically investigate the resonant Raman scattering of GaAs quantum dots. The electron system...
We analyze few-particle effects in the optical spectra of semiconductor quantum dots using a density...
We construct an optimal set of single-particle states for few-electron quantum dots (QDs) using the ...
A detailed discussion of the optical properties of single n-type modulation-doped semiconductor quan...
We employ a self-consistent, dynamic spin-density functional concept beyond the dipole approximation...
Quantum many-body states of up to four excitons are studied in small parallelepipedal quantum dots w...
We analyze few-particle effects in the optical spectra of semiconductor quantum dots using a density...
We investigate the effects of few-particle population of a single strain-induced quantum dot by opti...
We investigate theoretically Raman spectra of few-electron quantum dots. Spectra obtained by an exac...
In this article we review our recent experimental and theoretical investigations of electronic excit...
We investigate experimentally and theoretically few-particle effects in the optical spectra of singl...
We have investigated electronic excitations in GaAs-AlxGa1-xAs quantum wires, and dots by resonance ...
We investigate theoretically and experimentally the resonant Raman scattering on modulation-doped, d...
Advances in submicron technology make it possible to realize man-made low-dimensional electronic sys...
Electronic Raman scattering provides information on excited states, whose collective character as be...
We theoretically investigate the resonant Raman scattering of GaAs quantum dots. The electron system...
We analyze few-particle effects in the optical spectra of semiconductor quantum dots using a density...
We construct an optimal set of single-particle states for few-electron quantum dots (QDs) using the ...
A detailed discussion of the optical properties of single n-type modulation-doped semiconductor quan...
We employ a self-consistent, dynamic spin-density functional concept beyond the dipole approximation...
Quantum many-body states of up to four excitons are studied in small parallelepipedal quantum dots w...
We analyze few-particle effects in the optical spectra of semiconductor quantum dots using a density...
We investigate the effects of few-particle population of a single strain-induced quantum dot by opti...
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