As seen in Figure 3c, APR-246 cell line the PL spectrum is mainly constituted by the Gaussian peaks around 500 and 575 nm. The visible ZnO emission is due to defects in the sample which can be attributed to the great number of ZnO clusters and the relatively poor ZnO-NC crystallinity, especially at the ZnO-NC/SiO2 interface, as seen in the TEM image (Figure 2a). The ZnO defects are mainly oxygen-related defects. The emission at 417 nm can be assigned to oxygen interstitials [17], while the other visible emissions at 450, 500, and 575 nm can be related
to oxygen vacancies [5, 13, 18]. These defects are consistent with our long annealing data, which will be discussed in the next section. Figure 3 The PL spectra HKI-272 purchase of the samples at various temperatures. (a) Photoluminescence spectra of the ZnO-NCs in the SiO2matrix at various RTP annealing temperatures. (b) The spectrum can be accounted for by two main contributions in the UV-blue and visible regions, respectively. (c) The evolution of various peaks as a function of annealing temperature is shown. For comparison, the volume evolution calculated from the NC size
obtained from the TEM analysis is also shown. The decrease of the signal at high annealing temperature can be roughly accounted for by the decrease of the NC absorption cross section. On the other hand, the few ZnO-NCs that exist in the sample give rise to some UV emission, which results in the broad PL spectrum. At 500°C annealing temperature, the PL spectrum exhibits an overall blueshift which is due to the increase of the UV-blue emission in the sample. As shown in Figure 3c, the RTP annealing at 500°C is accompanied by an increase of the blue and UV emission between 360 and 450 nm and a decrease of defect emissions at higher wavelengths. The drastic change in the emission spectrum of the sample can be attributed to an increase in the ZnO-NCs and the decrease of ZnO clusters in the sample (Figure 2b), which should in turn increase the ZnO near-band-edge emission in the UV region. The emission peak at 378 nm can be related to ZnO near-band-edge (excitonic) emission [19, 20]. The emission peak at 396 nm RAS p21 protein activator 1 could
possibly be related to the electron transition from Zn interstitial to Zn vacancy as reported by Panigrahi et al.[5]. While being relatively weak, it is worth noting the this website appearance of a peak at 360 nm for the smallest NCs for which quantum confinement is expected to occur as already reported in a transmission experiment in solution [16]. Further analysis and especially low-temperature PL measurement are needed to confirm the peak origin. For annealing temperatures higher than 550°C, no drastic change is observed in the shape of the emission spectra, as seen in Figure 3a. Instead, the PL spectra mainly exhibit a decrease in the emission intensity. Indeed the Gaussian fitting analysis shows that the peak amplitudes decreased by the same proportion compared to its value at 500°C.