Abstract
ZnO films were deposited by metal-organic chemical vapor deposition on (0001) sapphire substrates at various partial pressure ratios of oxygen and zinc precursors (R
VI/II). The annealing and the R
VI/II ratio effects on the vibrational and optical properties of ZnO films have been investigated by Micro-Raman scattering and low temperature photoluminescence (PL) spectroscopy. As confirmed by characterizations used in this study, the quality of the ZnO films was improved by thermal annealing at 900
°C in oxygen ambient. Raman spectra of the as-deposited films show a broad band (BB) centered at about 518
cm
−1 whose intensity increases when the R
VI/II ratio decreases. After annealing, the intensity ratio of the BB to the E
2 high (E
2
H) peak decreases rapidly with increasing the annealing time (t
an). The vibrational properties of the annealed films grown at R
VI/II
=
1 need only 1
h to be improved in contrast to those of films grown in Zn-rich condition, which need 4
h. From the E
2
H mode frequency, the residual stress in both the as-grown and the annealed films has been estimated. Micro-Raman measurements show that as-grown films are under a compressive stress which vanishes upon annealing and is not strongly dependent on t
an for t
an up to 1
h. PL spectra show that sharp donor bound exciton and A-free exciton emissions are observed for the as-deposited films grown at R
VI/II
≥
0.5 and are enhanced after annealing for 1
h. However, in ZnO films grown in Zn-rich condition these emissions are absent and a t
an
=
4
h is needed to annihilate non-radiative recombination centers and improve their luminescent efficiency.