Mist chemical vapor deposition (Mist-CVD) is a low cost, safe, low vacuum system demand, and simple green process. By this process, inexpensive and solid precursors in solution can be vaporized by ultrasonic, which enables deposition of ZnO (zinc oxide) at atmospheric pressure. In this thesis , x-ray diffraction (XRD) and scanning electron microscopy (SEM) are mainly used to characterize crystallinities, epitaxial relationships and surface morphologies of ZnO deposited at various concentrations of zinc acetate (Zn(OOCCH3)2˙2H2O) and temperature. The precursor solution composed of deionized water, acetic acid as solvent, and zinc acetate as provision of zinc source was prepared. Nitrogen gas was used as carrier gas of mist, while oxygen gas which provided oxygen source was used as reaction gas. (0001) c-plane single crystal sapphire was used as substrate. For ZnO deposition at 500°C, both the nucleation density and the amount of deposition increased with the zinc acetate concentration. A nanowall structure emerged when the concentration increased to 0.05 M. Deposition of ZnO at temperatures between 500°C and 800°C was also investigated. It was found that the thickness of ZnO decreases with increasing temperature. When the temperature was raised to 700°C, the nanowall structure was not observed, instead a flat film surface appeared with incomplete coalescence of the grains in a few areas. For deposition at 800°C, the ZnO surface became rough due to the irregular grain shape morphologies. Good ZnO crystallinity can be obtained at 600°C with the FWHM (Full width at half maximum) of (0002) X-ray rocking curve (XRC) of 385 arcsec. To obtain a smooth and continuous ZnO film without the nanowall structure, a two-step growth was developed, in which the growth temperature in the first step was set at 600C, followed by the second step growth at 700C. The film quality with the (0002) XRC FWHM of 450 arcsec was obtained with a smooth surface morphology. Photoluminescence measurements at room temperature show that the deposited ZnO films exhibit strong near band edge emission at 3.28 eV with negligible green and yellow emissions.