Highly Efficient Broad-Band Green-Emitting Cerium(III)-Activated Garnet Phosphor Allows the Fabrication of Blue-Chip-Based Warm-White LED Device with a Superior Color Rendering Index

Abstract: High-performance warm-white light-emitting diode (LED) devices are in great demand toward green and comfortable solid-state lighting. Herein, we report a creative green-emission CaY 2 HfGa(AlO 4 ) 3 :Ce 3+ phosphor. CaY 2 HfGa(AlO 4 ) 3 :Ce 3+ compounds with different cerium ion doping contents have been successfully prepared through a conventional high-temperature solid-state method, and their phase and crystal structure have been revealed via the powder X-ray diffraction and Rietveld refinement. Impressively… Show more

“…Though s-g-C 3 N 4 -Ph is a yellowish-green-emitting material, the results of its application in white LEDs suggest that it can provide a high-quality green light component for white light. Most of the reported green phosphors usually use rare-earth ions for green emission or sensitization, such as Ce 5 Si 3 O 12 N:Tb 3+ , 43 Ba 2 LiSi 7 AlN 12 :Eu 2+ , 44 RbLi(Li 3 SiO 4 ) 2 :Eu 2+ , 45 CaY 2 HfGa(AlO 4 ) 3 :Ce 3+ , 46 and CaY 2 ZrScAl 3 O 12 :Ce 3+ . 47 In comparison, s-g-C 3 N 4 -Ph is not only rare-earth-free but also metal-free, which makes it a cheap quasi-green phosphor for LEDs.…”

A graphitic-C₃N₄ derivative containing heptazines merged with phenyls: synthesis, purification and application as a high-efficiency metal-free quasi-green phosphor for white LEDs

“…Though s-g-C 3 N 4 -Ph is a yellowish-green-emitting material, the results of its application in white LEDs suggest that it can provide a high-quality green light component for white light. Most of the reported green phosphors usually use rare-earth ions for green emission or sensitization, such as Ce 5 Si 3 O 12 N:Tb 3+ , 43 Ba 2 LiSi 7 AlN 12 :Eu 2+ , 44 RbLi(Li 3 SiO 4 ) 2 :Eu 2+ , 45 CaY 2 HfGa(AlO 4 ) 3 :Ce 3+ , 46 and CaY 2 ZrScAl 3 O 12 :Ce 3+ . 47 In comparison, s-g-C 3 N 4 -Ph is not only rare-earth-free but also metal-free, which makes it a cheap quasi-green phosphor for LEDs.…”

A graphitic-C₃N₄ derivative containing heptazines merged with phenyls: synthesis, purification and application as a high-efficiency metal-free quasi-green phosphor for white LEDs

“…Such a red-shift for Ce 3+ is frequently seen, such as in the cases of BaLu 2 Si 3 O 10 : x Ce 3+ , 11 Ca 0.75−1.5 z Li 0.15 Al 0.75 Si 1.25 N 2.9 O 0.1 : z Ce 3+ , 27 Ca 1−2 x Ce x Li x AlSiN 3 , 28 LiY 9 (SiO 4 ) 6 O 2 :Ce 3+ , 29 NaSrY(BO 3 ) 2 :Ce 3+ , 30 and CaY 2 HfGa(AlO 4 ) 3 : Ce 3+ . 7 There is also Ce 3+ -to-Y 3+ replacement in the latter three cases. In the literature, this red-shift was usually explained using the following equation: , where Z is the anion charge, e is the electron charge, r is the radius of the d wave function, and R is the bond length between the central cation and its ligands.…”

“…Nowadays, the research interest in Ce 3+ -based phosphors remains high because Ce 3+ usually exhibits high-brightness and tunable emission (ranging from UV to red in different hosts). [7][8][9] The ground and excitation configurations are 4f 1 5d 0 and 4f 0 5d 1 , which result in intense absorption and emission bands due to the spin-and parity-allowed 4f-5d transition. In fact, the energy level of the 5d electron is susceptible to the surrounding crystal field, 7 thus the emission color could be tuned by modifying the coordination environment by applying chemical substitution or even physical pressure directly.…”

“…[7][8][9] The ground and excitation configurations are 4f 1 5d 0 and 4f 0 5d 1 , which result in intense absorption and emission bands due to the spin-and parity-allowed 4f-5d transition. In fact, the energy level of the 5d electron is susceptible to the surrounding crystal field, 7 thus the emission color could be tuned by modifying the coordination environment by applying chemical substitution or even physical pressure directly. Moreover, Ce 3+ is a frequently used sensitizer, transmitting partial excitation energy to co-activators.…”

Pressure-sensitive Ce³⁺ photoluminescence in LiCaY₅(BO₃)₆: high internal quantum yields and energy transfer to Tb³⁺

“…Ion-doped phosphor materials have been extensively employed in illumination and sensing, 3D displays, and biomedical fields in recent years. [1][2][3][4][5][6] Many phosphors, on the other hand, are severely limited in their applicability due to their inherent thermal quenching limitations. White light-emitting diodes (WLEDs) made of phosphors are currently extensively utilized in our everyday lives owing to their high longevity and green energy efficiency.…”

Tuning of the thermal quenching performance of Bi³⁺-doped scheelite Ca(Mo/W)O₄ solid solution phosphors