In this paper, x wt% LiF (1 ≤ x ≤ 10) is utilized to decrease sintering temperature, improve microstructure and enhance Q × f of Li3Mg3NbO7 ceramics. Remarkably, the appropriate addition of LiF leads to the dramatic reduction in sintering temperature (reduced by 300 °C) and the significant improvement in Q × f (increase ratio: 26%). The addition of LiF causes the generation of cubic oxyfluoride solid solution, which is confirmed by XRD, SEM and TEM. When x ≤ 8, both orthorhombic oxide and cubic oxyfluoride solid solution exist in ceramics. When x = 10, the ceramic is composed of cubic oxyfluoride solid solution and LiF. It is confirmed that the maximum mass percentage of LiF required to fully form a cubic solid solution is between 8wt % and 10wt %. The significant improvement in Q × f is mainly attributed to increase in relative density and orthorhombic-cubic phase transition. In this system, Li3Mg3NbO7 + 8wt% LiF ceramics sintered at 900 °C possess the optimal dielectric properties: εr = 14.10, Q × f = 152,510GHz and τf = -43.5 ppm/°C. The Li3Mg3NbO7 + 8wt% LiF ceramics show an outstanding combination of low εr, high Q × f and low sintering temperature, surpassing the performance of most low-temperature dielectric materials. The excellent chemical compatibility with Ag electrodes suggests that the Li3Mg3NbO7 + 8wt% LiF ceramics are particularly promising for LTCC applications.