Zinc oxide is an n-type transparent semiconductor with wide band gap of 3.2 eV, which has been extensively applied to photoelectric components and flat panel displays. This thesis was aimed at ZnO thin film preparing by solution method, the properties of the grown ZnO films, and the physical and electrical characteristics of the thin film transistors. The solution methods were including chemical bath deposition (CBD) and sol-gel deposition. In addition, this investigation explored the influence of cation-mediation on the orientation and transmittance of ZnO crystals in chemical bath deposition. Moreover, the doping effect of ZnO crystalline which grown in Mg ion (Mg2+) contained solution was investigated. In particular, the prefer orientation of the ZnO crystalline was changed by the Mg ion mediating in chemical solution. The ZnO crystalline film exhibited good optical transmittance of over 90%. Additionally, the direct band gap value was 3.22eV, which is less than 3.38eV obtained using a non-mediation solution bath. Finally, the ZnO sol-gel films were annealed at different temperatures, which were used as seed layers and nuclei sites for further ZnO films fabrication by chemical bath deposition. Base on the investigation, the influence of sol-gel seed layers on crystallinity and orientation of ZnO by chemical bath deposition were discussed. Also, the electrical characteristics of transparent thin film transistors obtained using this active layer were demonstrated. In the ZnO films study, the physical properties of the ZnO film by solution methods, including the growth mechanism on crystallization, the optical property, the crystal size, and carrier concentration of the ZnO thin film were investigated. In the ZnO thin film transistors (TFTs) study, the electrical characteristics of ZnO thin film transistors by using low temperature solution process without annealing were demonstrated. In addition, the electrical characteristics of ZnO TFTs with Mg doped and without Mg doped by sol-gel method were demonstrated respectively. The A significant improvement of surface roughness with Mg doping could be noticed. In addition, this result was in good agreement with the discussions of higher current on and current off ratio. Finally, the ZnO film were grown by sol-gel and chemical solution bath combination method, to resolve the doping effect on thin film transistors by using the self-crystal as the growing sites for further deposition. Since indium tin oxide was used as the conducting electrodes (source, drain, and gate) for transparent thin film transistors. Current-voltage properties measured through the gate infer that the ZnO channel was n-type enhancement mode device due to a positive gate voltage were required to induce a conducting channel, and the current increases with increasing positive gate bias. The optimum device had field-effect mobility of 0.67 cm2 /V s and an on-off ratio more than 10E7.