Spherical Sn1-xO2: Sm phosphors were successfully synthesized via a microwave-assisted solvothermal route. A broad excitation band ascribed to the host absorption was observed at 318 nm. The prepared phosphors had several emission peaks at 560-700 nm assigned to f-f transition of Sm3+. The emission intensity of Sn1-xO2: Sm phosphors was increased with increasing the concentration of Sm3+ up to x = 0.9%. When the concentration of Sm3+ was further increased, the emission intensity was reduced due to the formation of an impurity phase. As the power of microwave increased, the particle size was reduced because of the increase in the number of nuclei. The luminescence intensity of the phosphors was slightly decreased with increasing the applied power due to an increase in surface defects. SnO2: Eu3+ phosphors were successfully synthesized via a microwave -assisted solvothermal route. The solvents used were found to have significant effects on the morphology and the luminescent properties of the obtained phosphors. Using ethanol as a solvent resulted in the formation of spherical phosphors with enhanced luminescent intensity. SnO2: Eu3+ phosphors exhibited a reddish-orange emission under excitation at 314 nm, and displayed a broad excitation band in the range of 240-370 nm due to the host absorption. In the microwave irradiation process, increasing the concentration of urea resulted in complete precipitation of Eu3+ ions, thereby enhancing the luminescent intensity.