Theoretical Study Of Excitonic Complexes In Gaas/Algaas Quantum Dots Grown By Filling Of Nanoholes

In this work, a theoretical study of the electronic and the optical properties of a new family of strain-free GaAs/AlGaAs quantum dots (QDs) obtained by AlGaAs nanohole filling is presented. The considered model consists of solving the three-dimensional effective-mass Schrodinger equation, thus providing a complete description of the neutral and charged complex excitons' fine structure. The QD size effect on carrier confinement energies, wave functions, and s-p splitting is studied. The direct Coulomb interaction impact on the calculated s and p states' transition energies is investigated. The behaviour of the binding energy of neutral and charged excitons (X- and X+) and biexciton XX versus QD height is studied. The addition of the correlation effect allows to explain the nature of biexcitons often observed experimentally.