Deep levels in metamorphic InAs/InGaAs quantum dot structures with different composition of the embedding layers

Golovynskyi, S., Datsenko, O., Seravalli, L., Kozak, O., Trevisi, G., Frigeri, P., Babichuk, I. S., Golovynska, I., & Qu, J. (2017). Deep levels in metamorphic InAs/InGaAs quantum dot structures with different composition of the embedding layers. Semiconductor Science and Technology, 32(12), 125001. https://doi.org/10.1088/1361-6641/aa91e7

Deep levels in metamorphic InAs/InxGa1−xAs quantum dot (QD) structures are studied with deep level thermally stimulated conductivity (TSC), photoconductivity (PC) and photoluminescence (PL) spectroscopy and compared with data from pseudomorphic InGaAs/ GaAs QDs investigated previously by the same techniques. We have found that for a low content of indium (x=0.15) the trap density in the plane of self-assembled QDs is comparable or less than the one for InGaAs/GaAs QDs. However, the trap density increases with x, resulting in a rise of the defect photoresponse in PC and TSC spectra as well as a reduction of the QD PL intensity. The activation energies of the deep levels and some traps correspond to known defect complexes EL2, EL6, EL7, EL9, and EL10 inherent in GaAs, and three traps are attributed to the extended defects, located in InGaAs embedding layers. The rest of them have been found as concentrated mainly close to QDs, as their density in the deeper InGaAs buffers is much lower. This an important result for the development of light-emitting and light-sensitive devices based on metamorphic InAs QDs, as it is a strong indication that the defect density is not higher than in pseudomorphic InAs QDs.