In this study, we use terahertz time-domain spectroscopy to figure out the transmittance of zinc oxide nanorods structure, and then calculate the complex dielectric coefficient, and use Drude-Smith model in different hydrothermal growth condition. The model derives the mobility of the zinc oxide mobility and the terahertz conductivity. In this thesis, a hydrothermal method is used to grow a zinc oxide nanopillar array, and the material is analyzed using terahertz time-domain spectrum of a photoconductive antenna configuration. The femtosecond laser is split into a pump beam and a probe beam by a beam splitter, both of which are focused by an objective lens on a photoconductive dipole antenna. The pump pulse excites the carriers in the photoconductive antenna, and then we use a parabolic mirror to the direct megahertz wave is focused on the sample, and finally another pair of parabolic mirrors are used to collect the terahertz transmittance. Finally, the complex dielectric coefficient, light conductivity and mobility of the material were obtained using the calculation software, and compared the influence of the zinc oxide nanorods in different hydrothermal time on the time-domain spectrum of the terahertz wave.