Color-tunable phosphors Sr0.94MoO4:xEu^3+, (0.06 - x)Tb^3+ were synthesized rapidly by microwave ra- diation method with active carbon particle as microwave absorbent. The synthesized phosphors were investigated ...Color-tunable phosphors Sr0.94MoO4:xEu^3+, (0.06 - x)Tb^3+ were synthesized rapidly by microwave ra- diation method with active carbon particle as microwave absorbent. The synthesized phosphors were investigated by X-ray powder diffraction (XRD) and fluorescence spec- trophotometer. The effects of the ratio of Eu^3+ and Tb^3+ on the phase structure and luminescent properties of the phos- phors were discussed. The results show that Eu^3+,Tb^3+-doped samples can be well indexed to the pure tetragonal scheelite- type SrMoO4, indicating that Eu^3+ and Tb^3+ are effectively doped into the SrMoO4 host lattices. The as-synthesized Sro.94MoO4:xEu^3+,(0.06 - x)Tb^3+ phosphors have two luminescent centers (Eu^3+ and Tb^3+), which can show red and green emissions under ultraviolet light excitation, respec- tively. Doping concentration of Eu^3+ and Tb^3+ has great effect on the intensity of emission peaks and the chromaticity of the samples, and the full color between green and red light can be achieved by adjusting the relative concentration of Eu^3+ and Tb^3+.展开更多
基金financially supported by the National Natural Science Foundation of China (No.21301046)
文摘Color-tunable phosphors Sr0.94MoO4:xEu^3+, (0.06 - x)Tb^3+ were synthesized rapidly by microwave ra- diation method with active carbon particle as microwave absorbent. The synthesized phosphors were investigated by X-ray powder diffraction (XRD) and fluorescence spec- trophotometer. The effects of the ratio of Eu^3+ and Tb^3+ on the phase structure and luminescent properties of the phos- phors were discussed. The results show that Eu^3+,Tb^3+-doped samples can be well indexed to the pure tetragonal scheelite- type SrMoO4, indicating that Eu^3+ and Tb^3+ are effectively doped into the SrMoO4 host lattices. The as-synthesized Sro.94MoO4:xEu^3+,(0.06 - x)Tb^3+ phosphors have two luminescent centers (Eu^3+ and Tb^3+), which can show red and green emissions under ultraviolet light excitation, respec- tively. Doping concentration of Eu^3+ and Tb^3+ has great effect on the intensity of emission peaks and the chromaticity of the samples, and the full color between green and red light can be achieved by adjusting the relative concentration of Eu^3+ and Tb^3+.
