Lightweighting has become a key issue in automotive industries recently. Magnesium alloy, consequently, has become one of the major materials for structures. In addition, the solid-state bonding and other excellent features of the friction stir spot welding (FSSW) makes it inherently attractive for body assembly and other similar applications. This study aims to investigate the welding characteristics of the AZ80-F magnesium alloy of FSSW. A 3D finite element coupling model is employed to investigate the effects of welding parameters on the thermal-mechanical behavior of the welds. Then, the experimental samples are made by using FSSW process and, the tensile-shear test, direct tensile test, nano-indentation test and metallographic test are performed to understand the corresponding characteristics of the spot welds. The results show that the welding parameters of tool rotation speed and pressure are more sensitive to the temperature distribution of the welds. In addition, the temperature distribution curve can be used to evaluate the properties of the welds. The results obtained from microstructure observation reveal that the geometry of the tool has a strong effect on the plastic flow and grain size in the welds during the welding process. The welds with the dual-conical tool have the best microstructure distribution and welding strength. Its welding strength increases with the increase of tool rotation speed and pressure to a critical value.