In the presented work the dynamical properties of a population of bound excitons in a semiconductor quantum-wire is modelled theoretically. To this end, the Hamilton-operator H of the system is derived. Using the Heisenberg equation, equations of motion for the relevant elements of the reduced density matrix are obtained from the commutation with H. In our studies, we have have numerically simulated the coupled system of charge-carriers, longitudinal-accoustical (LA) phonons and many-body correlations.
In the first part of the presented work, the stability of a population of bound excitons against scattering with LA-phonons is examined. A pronounced dependence on carrier-density and lattice-temperature is observed. The results are compared to calculations with a simple mass-action-law formalism.
In the second part, dynamically calculated many-body correlations are used to study the influence of bound electron-hole pairs on exciton-spectra in linear absorption experiments.
Electron states and collective excitations in multilayers, quantum wells, mesoscopic, and nanoscale systems (for electron states in nanoscale materials, see 73.22.-f)Exciton-spectrumQuantumwireExcitons and related phenomenaSemiconductorExciton-phonon interactionExcitonTheories and models of many-electron systems
