This study is devided into three parts. First, by using hydrothermal growth, we use different alkalis to react with Zn(NO3)2 to synthesize ZnO nanoparticles in different solvents(water and ethanol) and discuss the effects on morphology and crystallinity. Second, we synthesize conducting polymer - PEDOT by oxidative polymerization and discuss the effect of solutions with different pH value on the doping level of PEDOT film. Third, we combine PEDOT and ZnO films to synthesize ZnO rods on each film, and discuss the effects of substrates and reaction conditions on the morphology and pH tuning ability of PEDOT/ZnO composite films. In the first part, we synthesize ZnO nanoparticles by hydrothermal growth method. The composition, crystallinity, and morphology of the ZnO nanoparticles are characterized by Fourier-Transformed Infrared Spectrophotometer(FT-IR), X-Ray Diffractometer(XRD), and Scanning Electron Microscope(SEM), respectively. ZnO particles can be obtained both in water and ethanol, and the paritcle size of ZnO synthesized in ethanol is smaller than that in water. And the pH tuning is better in ethanol than that in water. In the second part, the UV-Vis absorbance peak of PEDOT film is used to determine the doping level of PEDOT film. The doping level of PEDOT film increases when contacting with acid solutions, and decreases when contacting with alkali solutions. PEDOT film can tune solutions from pH=3-7 to pH=3, and pH=9 to pH=7. In the third part, we combine PEDOT and ZnO to synthesize a PEDOT/ZnO composite film. The substrate is first modified with ZnO film, PEDOT film, or both PEDOT and ZnO film. Then one dimensional hexagonal ZnO rods are grown on pre-modified substrates. Morphology of PEDOT/ZnO composite film is observed with SEM and the pH tuning effect is evaluated. After pre-modified by PEDOT/ZnO film on the glass or PET non-woven, ZnO rods of hexagonal structure can be obtained, with aspect ratio of 3. It can tune solutions of pH=3-9 to pH=7. Therefore, the PEDOT/ZnO composite film really works on pH tuning.