Eu3+-doped (Y,Gd)NbO4 phosphor was synthesized by solid-state reaction for possible application in cold cathode fluorescent lamps. A broad absorption band with peak maximum at 272 nm was observed which was due to the charge transfer between Eu3+ ions and neighboring oxygen anions. A deep red emission at the peak wavelength of 612 nm was observed which could be attributed to the 5D0→7F2 transition in Eu3+ ions. The highest luminance for Y1-x-yGdyNbO4:Eux3+ under 254 nm excitation was achieved at Eu3+ concentration of 18 mol.% (x=0.18) and Gd3+ concentration of 8.2 mol.% (y=0.082). The luminance of Y0.738Gd0.082NbO4:Eu3+0.18 was higher than that of a typical commercial phosphor Y2O3:Eu3+ and the CIE chromaticity coordinate was (0.6490, 0.3506), which was deeper than that of Y2O3:Eu3+. The particle size of the synthesized phosphors was controlled by the NaCl flux and particle size as high as 8 μm with uniform size distribution of particles was obtained. Eu3 + -doped (Y, Gd) NbO4 phosphor was synthesized by solid-state reaction for possible application in cold cathode fluorescent lamps. A broad absorption band with peak maximum at 272 nm was observed which was due to the charge transfer between Eu3 + ions and neighboring A deep red emission at the peak wavelength of 612 nm was observed which could be attributed to the 5D0 → 7F2 transition in Eu3 + ions. The highest luminance for Y1-x-yGdyNbO4: Eux3 + under 254 nm excitation was achieved at Eu3 + concentration of 18 mol.% (x = 0.18) and Gd3 + concentration of 8.2 mol.% (y = 0.082). The luminance of Y0.738Gd0.082NbO4: Eu3 + 0.18 was higher than that of a typical commercial phosphor Y2O3: Eu3 + and the CIE chromaticity coordinate was (0.6490, 0.3506), which was more than that of Y2O3: Eu3 +. The particle size of the synthesized phosphors was controlled by the NaCl flux and particle size as high as 8 μm with uniform size distribution of particles was obtained.