This research fabricated high-gain avalanche rushing amorphous photoconductors (HARP) for medical low dose X-ray detector applications, using amorphous selenium (a-Se) as the photoconductive layer. The greatest advantage of a-Se is its high photoconversion efficiency result from avalanche multiplication under high electric field. For application of low dose X-ray exposure, HARP devices should have a high photoconversion gain with a very low dark current so that a high image contrast can be obtained. In order to reduce dark current, a hole blocking layer is used between the photoconductive layer and the anode of HARP device. Here are two goals of this research about ZnO hole blocking layer prepared by rf magnetron reactive sputter deposition. First, we optimized the ZnO hole blocking layer. Second, by changing the oxygen flow rate and substrate temperature during deposition, we investigate how these parameter affect the ZnO hole blocking layer and discover the relationship between the microstructure and traps of ZnO hole blocking layer and the dark current of HARP. We concluded that because the deep hole traps related to oxygen vacancy in ZnO hole blocking layer can prevent hole from injecting into the photoconductive layer, the dark current of HARP can be reduce if ZnO hole blocking layer is introduced in HARP.