Abstract
The existence of extended defects (i.e., dislocations) in inorganic semiconductors, such as GaN or ZnO, responsible for broad emission peaks in photoluminescence analysis remains unresolved. The possible assignments of these luminescence bands are still matter of discussion. In this study, two different zinc oxide samples, grown under different oxygen partial pressures and substrate temperatures, are presented. Epitaxial and structural properties were analysed by means of X‐ray diffraction and transmission electron microscopy techniques. They confirm that the layers are single‐phase with a good crystalline quality. Nevertheless, a different density of threading dislocations, with a higher contribution of edge dislocations, was found. Photoluminescence spectroscopy has been used to investigate the optical properties. The steady state luminescence spectra performed at 14 K evidenced the donor bound exciton recombination and deep green and red emission bands. The red band with a maximum at 1.78 eV was found to be stronger in the sample grown at lower oxygen pressure which also shows higher density of threading dislocations. From the temperature and excitation density dependence of the red band, a donor acceptor pair recombination model was proposed, where hydrogen and zinc vacancies are strong candidates for the donor and acceptor species, respectively.
Highlights
Nowadays ZnO is among other semiconductors, one of the most studied materials, due to the potentialities offered by its wide direct band gap (3.37 eV) at room temperature and high (∼60 meV) free exciton binding energy [1, 2]
Concerning threading dislocations (TDs) characterization by transmission electron microscopy (TEM), the method used in this work is based on the combination of DC-2B-Bright field (BF) TEM images from XTEM and PVTEM preparations [23] which allows obtaining on the one hand edge + mixed and screw + mixed TDs and on the other hand density of TDs at different depths of the ZnO layers
Assuming that the twisted angle is proportional to the density of the edge dislocations [31, 32], these results suggest that a high density of edge dislocations is present in the sample Z1
Summary
Nowadays ZnO is among other semiconductors, one of the most studied materials, due to the potentialities offered by its wide direct band gap (3.37 eV) at room temperature and high (∼60 meV) free exciton binding energy [1, 2]. These characteristics together with the easiness of depositing thin ZnO films by different techniques with a considerable quality make this material a suitable semiconductor for a broad range of applications in optical and electrical devices (light emitting diodes, transparent thin film transistors, and surface acoustic wave systems [2,3,4,5,6]). A correlation between the red luminescence band and the highest TD density is discussed in the context of this paper
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