Silicon wafer is the main material for silicon solar-cell industry. However, to generate a silicon P-N junction solar cell, the material cost and the high-temperature process are expensive. In this study, we aim the deposition of the hydrogenated amorphous silicon (a-Si:H) thin film on the silicon wafer to generate the heterojunction silicon solar cell. The high doping concentration (high conductivity) and the low absorption coefficient are the important parameters for the P-type a-Si:H thin film, because of the higher doping of the a-Si:H thin film can achieve the higher conversion efficiency of the heterojunction solar cell. We also optimized the thicknesses of the a-Si:H thin film and the substrate wafer to improve the conversion efficiency. Besides, the interfaces of the semiconductor ─ semiconductor and metal ─ semiconductor have been analyzed explored to improve the performance of the solar cells. The a-Si:H heterojunction solar cells have been fabricated using radio-frequency magnetron sputtering to deposit a P-type a-Si: H film on the N-type Si wafer. The sputtering target is a bulk P-type Si with boron grains on it. We modulated the hydrogen and argon partial pressure ratio and the rapid thermal annealing to control the quality of the P-type a-Si:H thin film. The results show the P-type a-Si:H thin film behaved highly conductive. After depositing the P-type a-Si:H thin film on the N-type Si substrate to form the heterojunction solar cell, the conversion efficiency of the solar cell is 1.9%, the open circuit voltage VOC is about 0.5 V, the short-circuit current density JSC is about 9.6 mA/cm2 and fill factor FF is about 39.7% .