Photoluminescence studies of transparent conductive ZnO films to identify their donor species

Abstract

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We studied the correlation between defect species, as probed by using photoluminescence (PL), and the transparent conductive properties of undoped ZnO films sputter-deposited on glass substrates at room temperature. The near-stoichiometric but slightly oxygen-deficient ZnO films had resistivities of 3×10−3 Ωcm and optical transmittances of 85% at visible wavelengths. The PL spectra exhibited only a band-edge emission peaking at 380 nm, suggesting that intrinsic defects were not the origin of the n-type conduction. Post annealing at 500°C in a vacuum reduced the carrier concentration by five orders of magnitude. However, the spectral features of the PL remained intact; i.e., the change was only attenuated band-edge emission. These observations can be consistently explained if we suppose that the donors are hydrogen impurities. Colored ZnO films deposited under a reducing condition had resistivities of 2−4×10−3 Ωcm, and their optical transmittances were 50−70% because of Zni atoms. Post annealing at 500°C desorbed some Zni atoms, and consequently transparency increased. The resultant PL spectra exhibited an emission at 396 nm accompanied with a deep-level emission at 400−500 nm, each corresponding to transitions from the conduction band to VZn and from Zni to the valence band. Thus, Zni was the primary donor in the Zn-rich films. Deposition under a flow of O2 gas produced resistive ZnO films. Incorporating excess oxygen atoms disordered the crystal lattice, as indicated by the broad deep-level emissions from Zni, Oi, VZn, and VO. The high resistivity was due to charge compensation between donors (Zni) and acceptors (Oi and VZn).