Image charges in semiconductor quantum wells: Effect on exciton binding energy
- 15 September 1990
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 42 (9) , 5906-5909
- https://doi.org/10.1103/physrevb.42.5906
Abstract
Binding energies of excitons in a quantum-well structure are calculated including fully the effects of image charges, finite barriers, the z correlation of electrons and holes, and anisotropic hole masses. The influence of discontinuous masses and discontinuous dielectric constants across the interfaces is evaluated in detail: While the mass difference becomes important only when the excitonic wave function penetrates into the barrier, the image charges appreciably modify the Coulomb interaction and therefore influence the exciton binding energy even at well widths larger than the exciton Bohr radius. Results for technologically important, particular material systems are presented.Keywords
This publication has 21 references indexed in Scilit:
- Excitonic and nonlinear-optical properties of dielectric quantum-well structuresPhysical Review B, 1989
- Binding energies of wannier excitons in semiconductor quantum wells: Numerical integration of the in-plane radial equationSolid State Communications, 1989
- Anisotropy effects on excitonic properties in realistic quantum wellsPhysical Review B, 1988
- Theory of magneto-exciton binding energy in realistic quantum well structuresSolid State Communications, 1988
- Excitons and polaritons in semiconductor/insulator quantum wells and superlatticesSuperlattices and Microstructures, 1988
- Room-temperature excitonic nonlinear-optical effects in semiconductor quantum-well structuresJournal of the Optical Society of America B, 1985
- Binding energies of wannier excitons in GaAs-Ga1−xAlxAs quantum well structuresSolid State Communications, 1983
- Exciton binding energy in quantum wellsPhysical Review B, 1982
- Observation of the excited level of excitons in GaAs quantum wellsPhysical Review B, 1981
- Intrinsic radiative recombination from quantum states in GaAs-AℓxGa1−xAs multi-quantum well structuresSolid State Communications, 1981