Zinc oxide nanostructures of various types, including nanobelts, nanoplatelets, nanowires, and nanorods, have been synthesized via well-developed routes by many research groups. However, so far, the underlying mechanism for the morphology derivation and evolution of the nanostructures has not been elucidated in depth. In this article, we report the systematic investigation of the morphology evolution characteristics of ZnO nanostructures from dense rods to dense nanoplatelets, nanoplatelet flowers, dense nanobelt flowers, and nanowire flowers in an evaporation-physical transport-condensation approach. Through the use of crystal growth theory, the determining factors for the formation of different nanostructural morphologies were found to be gas-phase supersaturation and the surface energy of the growing surface planes. Other experimental parameters such as the temperature at the source and the substrate, the temperature difference and the distance between the source and the substrate, the heating rate of the furnace, the gas flow rate, the ceramic tube diameter, and the starting material are all correlated with supersaturation and impose an effect on the morphology evolution. This finding may have an important impact on the qualitative understanding of the morphology evolution of nanostructures and the achieving of desired nanostructures controllably.
A simple seed-layer assisted electrochemical deposition (ECD) route has been successfully developed for
preparation of different ZnO nanostructures, and their optical and field emission properties are also studied.
ZnO films, nanowires, and nanosheets could be prepared in a rational way by just controlling the ECD current
density. The corresponding growth mechanisms are also discussed on the basis of the characteristics of the
ZnO crystal structure and the influences of the seed-layer and ECD current density. Except for ZnO nanosheets,
both the room-temperature and low-temperature photoluminescence measurements of the ZnO films and
nanowire arrays show strong ultraviolet excitonic emission, which proves their good crystal quality. Detailed
analysis of the field emission (FE) properties indicates that the hierarchical ZnO nanowire array shows good
FE property due to their high aspect ratio, small radius curvature, and proper density.
The optical properties of δ-Bi2O3 thin films were investigated using spectroscopic ellipsometry and optical absorption spectrum. δ-Bi2O3 thin films were grown on Si and quartz substrates under different oxygen flow ratios (OFR) by radio frequency reactive magnetron sputtering. The Tauc-Lorentz dispersion method was adopted to model the optical dispersion functions of the thin films. The optical bandgap was obtained by three different methods. It was found that refractive index and extinction coefficient decrease, and the optical bandgap has a slight blue shift with increasing the OFR. Factors influencing the optical constants and optical bandgap are discussed.
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