ZnO nanostructures were synthesized via hydrothermal method which was using ZnCl2 and HMTA mixed solution as the precursor. The parameters , such as solution concentration, growth temperature, and growth time, greatly influenced the morphology of nanostructures. The nanotubes(NTs), nanowires(NWs), and well-aligned nanorods(NRs) could effectively be fabricated by controlling the growth condition. By multiple-step growth, not only the length but the aspect ratio were increased with steps of growth, and the shape of NRs kept integrity. Furthermore, PL spectra which had near-bnad-emission(~3.37 eV) and defect-related emission showed the optical properties of ZnO nanostructures. The defected-related emission intensity was greatly enhanced as the more and more area of ZnO contributed. The amount of OH group, which increased as the steps of growth increased, was closely related to yellow emission (~580 nm) and caused the red shift phenomenon. In addition, the electrical transport property of single NW was investigated. It was found that the diameters of NWs had a inverse proportion with resistivity and the electron mobility of single NW FET was higher than thin film FET. Here we fabricated two types of UV photodetector including single NW device and well-aligned NRs device, both of which demonstrated a very small voltage bias (less than 0.005 V). With the lower energy consumption and the weaker persistent photoconductive (PPC) effect, our UV photodetector was found to exhibit short response time and high sensitivity.