A series of K3Gd1-x-y(PO4)2:xCe^3+, yTb^3+ phosphors are synthesized by the solid-sate reaction method. X-ray diffraction and photoluminescence spectra are utilized to characterize the structures and luminescence properties of the as-synthesized phosphors. Co-doping of Ce^3+ enhances the emission intensity of Tb^3+ greatly through an efficient energy transfer process from Ce^3+ to Tb^3+. The energy transfer is confirmed by photoluminescence spectra and decay time curves analysis. The efficiency and mechanism of energy transfer are investigated carefully. Moreover, due to the non- concentration quenching property of K3Tb(PO4)2, the photoluminescence spectra of K3Tb1-x(PO4)2:xCe^3+ are studied and the results show that when x = 0.11 the strongest Tb^3+ green emission can be realized.
KaGd(PO4)2:Tb3+ phosphors are synthesized by the solid reaction method, and the phases and lu- minescence properties of the obtained phosphors are well characterized. The emission spectra of KaGd(PO4)2:Tb3+ exhibit the typical emissions of Tb3+. Concentration quenching of Tb3+ is not observed in KaGd(PO4)2:Tb3+, likely because the shortest average distance of Tb3+-Tb3+ in KaGd(POn)2:Tb3+ is adequately long such that energy transfer between Tb3+-Tb3+ ions cannot take place effectively. This re- sult indicates that KaTb(P04)2 phosphors have potential application in near ultraviolet (n-UV)-convertible phosphors for white light-emitting diodes.
A series of Ca499(PO4)3F:1%Eu^3+, 1%X (X = Li+, Au3+, and Bi3+) nanoparticles are prepared using hydrothermal method, with an average size of 33-62 nm. We study the improved photoluminescence properties of Ca4.99(PO4)3F:1%Eu3+ by co-doping with Li+, Au3+, and Bi3+ ions, respectively, and the enhancement of the emission intensities of Eu3+ is observed in these samples. The effects of Li+ acting as a charge compensator, Au3+ as a plasma surface sensitizer, and Bi3+ as an energy conversion agent are discussed. The results show Ca4.99(PO4)3F:1%Eu3+, 1%X nanoparticles are a promising candidate as a red component for near-ultraviolet light-emitting diodes.
A series of single-phased Ca2Al2SiOT:EU2+phosphors were synthesized by the solid-state reaction. Their structure and photoluminescence properties were investigated by the X-ray powder diffraction (XRD) and excitation and emission spectra in detail. The emission spectra of Ca2Al2SiO7:Eu2+ phosphors consisted of blue and green band located at 419 and 542 nm, respectively. The relative intensities of the blue and green emission changed with Eu2+ concentration and were sensitive to the excitation wavelength. The unique photoluminescence property originated from the 4f^7→4f65d transition of Eu2+ at different energy levels, on which the effect of the crystal field strength was con- sidered to be tailed by adjusting the host composition.
A series of K3Gd(PO4)2:Tb3+,Sm3+ phosphors were synthesized through solid state reaction. By co-doping Tb3+ and Sm3+ into K3Gd(PO4)2 host and singly varying the doping concentration of Sm3+, ttmable colors from green to yellow and then to orange were obtained in K3Gd(POa)2:Tb3+,Sm3+ phosphors under the excitation at 373 nm. The energy transfer process from Tb3~ to Sm3- was verified through luminescence spectra and fluorescence decay curves. Moreover, the energy transfer mechanism was demon- strated to be the quadrupole-quadrupole interaction. The results indicated that K3Gd(POa)2:Tb3+,Sm3+ phosphors could be a potential application for n-UV white light emitting diodes.
A novel red-emitting phosphor, CaYA1307: Eu^3+, Sm^3+, is synthesized by a combustion method at a low temperature (850 ℃), and the single phase of CaYA1307 is confirmed by powder X-ray diffraction measurements. The photoluminescence property results reveal that the red emission intensity of Eu^3+ is strongly dependent on the Sm^3+ concentration. Only the Eu^3+ luminescence is detected in the Eu^3+-Sm^3+ co-doped CaYA1307 phosphor with 393 nm excitation. However, under the characteristic excitation (402 nm) of Sm^3+, not only the Sm^3+ emission but also the Eu^3+ emission are observed. A possible mechanism of the energy transfer between Sm^3+ and Eu3+ is investigated in detail.
We report the photoluminescence(PL) of Eu^3+-doped glass with Bi^3+as a sensitizer. The specific glass system with the strong enhancement of the red emission of Eu3+is obtained by adding a small number of Bi3+ions instead of increasing the Eu^3+ concentration. The emission band of Bi3+overlaps with the excitation band of Eu^3+ and the lifetime decay curves,resulting in a very efficient energy transfer from Bi^3+ to Eu^3+. The probability of energy transfer is strongly dependent on Bi^3+ concentration. In addition, the intensity of 4f–4f transition is much stronger than that of a charge-transfer(CT) band in the excitation spectrum, which indicates that the Na2O–Ca O–Ge O2-Si O2 glass is a suitable red-emitting phosphor with high stability as a candidate for light-emitting diodes(LEDs).
The structure and photoluminescence (PL) properties of Sr3 SiO5: Sm3+ and Li+-doped Sr3SiOs: Sm3+ red-emitting phosphors were investigated. Samples were prepared by the high-temperature solid-state method. PL spectra show that the concentration quenching occurs when the Sm3+ concentration is beyond 1.3 mol% in Sr3SiOs: Sm3+ phosphor without doping Li+ ions. The concentration-quenching mechanism can be explained by the electric dipole-dipole interaction of Sm3+ ions. The incorporation of Li+ ions into Sr3SiOs: Sm3+ phosphors, as a charge compensator, improves the PL properties. The lithium ions also suppress the concentration quenching in Sm3+ with concentration increased from 1.3 tool% to 1.7 tool%.
