Two-dimensional stacking fault defects embedded in a bulk crystal can provide a homogeneous trapping potential for carriers and excitons. Here we utilize state-of-the-art structural imaging cou- pled with density functional and effective-mass theory to build a microscopic model of the stacking- fault exciton. The diamagnetic shift and exciton dipole moment at different magnetic fields are calculated and compared with the experimental photoluminescence of excitons bound to a single stacking fault in GaAs. The model is used to further provide insight into the properties of excitons bound to the double-well potential formed by stacking fault pairs. This microscopic exciton model can be used as an input into models which include exciton-exciton interactions to determine the excitonic phases accessible in this system.
Revised: June 1, 2020 |
Published: March 15, 2020
Citation
Durnev M., M. Glazov, X. Linpeng, M. Viitaniemi, B.E. Matthews, S.R. Spurgeon, and P.V. Sushko, et al. 2020.Microscopic model for the stacking-fault potential and the exciton wave function in GaAs.Physical Review B 101, no. 12:Article No. 125420.PNNL-SA-148814.doi:10.1103/PhysRevB.101.125420