The characteristic of a novel planar Si:B Blocked-Impurity-Band photodetector (BIB photodetector) has been studied in the thesis. We used high-pure substrate, ion-implantation and photolithography to fabricate planar structure. Ion-implantation was used to form the absorbing layer and high-pure substrate served as the blocking layer. The spectral response is successfully extended from 357 cm-1 down to 250 cm-1. Then, we discussed the device characteristic by differing the blocking layer widths, 30 μm (sample A) and 10 μm (sample B), under fixed contact distance. At high bias, two peaks corresponding to the transitions of the isolated impurity levels occur in the response spectrum of sample B. The occurrence of these two peaks could be due to the generation of the free carriers by impact ionization of the excited carriers under high electric field which is not found in sample A. Before the impact ionization, sample A has higher responsivity and slightly lower noise current than those of sample B. The impact process increases not only the responsivity but also the noise current. Therefore, the detectivity of the device shows no great improvement. These results show that the ratio of the blocking layer width to the absorbing layer width is one of the key factors deciding the performances of the BIB photodetectors. Compared with the conventional vertical BIB photodetectors, our devices have comparable value in responsivity. The noise current and detectivity, however, are obviously worse. We might improve the drawbacks by modifying the annealing process or using substrates with higher purity.