Photon Quantization in Sm<sup>3+</sup> Doped Red Glass Phosphors for Laser‐Induced Illumination

Zhang, Yuhang; Li, Desheng; Zhao, Xin; Pun, Edwin Yue‐Bun; Lin, Hai

doi:10.1002/pssa.201700903

Cited by 9 publications

(2 citation statements)

References 56 publications

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“…As shown in the inset plot of Figure 6d, the average lifetimes of Sm 3þ -doped KSN phosphors reduced from 1.37 to 1.04 ms with the enhancement of Sm 3þ doping concentration, which could be explained that the possibility of energy migration to the luminescent killer sites enhanced with the increase of Sm 3þ concentration, and enhanced the probabilities of the nonradiative energy transfer and cross-relaxation. [39][40][41] Further analysis about the structural modulation of luminescent properties was carried out about the environment around Sm 3þ in KSN lattice. Based on the selection rule, magnetic doublet (MD) transitions will be allowed when the difference of angular momentum ΔJ ¼ AE1 and 0.…”

Section: Luminescent Propertiesmentioning

confidence: 99%

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Cao

Feng

Chen

et al. 2022

Physica Status Solidi (a)

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Recently, photochromic ceramics with luminescence modulation behavior gradually developed into a hot point in inorganic materials, and the coupling between photochromic and luminescent properties will enhance the readout rate of information and convenience. [1,2] Mainstream photochromic systems include (K 0.5 Na 0.5 )NbO 3 (KNN), [3] Na 0.5 Bi 2.5 Nb 2 O 9 (NBN), [4] Na 0.5 Bi 0.5 TiO 3 (NBT), [5] SrSnO 4 (SS), [6] BaMgSiO 4 (BMS), [7] PbWO 4 (PWO), [8] and their compounds. [9,10] Due to the stable and excellent luminescence properties of rare-earth ions dopants, [11][12][13] most of the inorganic photochromic compounds relied on the introduction of rare-earth activator to obtain luminescence properties, and realized the luminescence modulation by the resonance energy transfer from luminescent center to photochromic center. [3][4][5][6][7][8][9] KSr 2 Nb 5 O 15 (KSN) lead-free ferroelectric materials exhibit excellent multifunctional features, including dielectric, ferroelectric, thermoelectric, electro-optic, photocatalytic, and photoluminescent, photochromic areas. [14][15][16][17] Due to the typically tetragonal tungsten bronze (TTB) structure, doping modification of KSN can be flexibly executed, and there are abundant sites available for occupying with alkali, alkali-earth, and rare-earth cations. [18] The photochromic effects of KSN ceramics were reported in our previous work in 2019. [17] The absorbance (and reflectivity) of KSN ceramics could be reversibly changed by alternating the light irradiation (395 nm) and thermal treatment, which exhibit various potential applications in optical information storage and recording, optical antifake, and sensors. [7,19,20] For tungsten bronze type host, the luminescent properties of Eu 3þ -doped NaSr 2 Nb 5 O 15 , [21] Dy 3þ -doped KBa 2 Nb 5 O 15 , [22] and RE 3þ (RE ¼ La, Pr, Nd)-doped KSr 2 Nb 5 O 15 [16] have been reported, and these systems exhibited the predominance in the charge transfer transition between rare-earth activator and hosts, and good luminescent emission properties. Moreover, compared with other systems, the KSN-based materials possess the TTB type structure and significant anisotropy on the optical properties, including photochromic, luminescent, and luminescence modulation properties. [23] Based on these features, the KSNbased textured ceramics with obvious grain orientation have

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Section: Luminescent Propertiesmentioning

confidence: 99%

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Cao

Feng

Chen

et al. 2022

Physica Status Solidi (a)

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“…12,16,18,[33][34][35][36][37][38] In the transmittance aspect, the highest transmittance of our work can reach 88%, higher than almost all the PIG method luminescent glass. In the QY aspect, recently reported no matter whether quantum dot NC 31,37 glass or other systems are lower than 32%, [39][40][41] Sample A of this work can reach a better performance at 36.02%. In addition, the CRI is 71.2.…”

Section: F I G U R Ementioning

confidence: 99%

Improving white light emission and quantum yield of Ce@Eu co‐doped silicate glass by reducing Eu³⁺ to Eu²⁺ with Si₃N₄

Huang

Yuan

et al. 2022

J Am Ceram Soc.

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Rare-earth-doped transparent glass shows great potential in white light-emitting diodes (wLEDs) application due to its excellent optical and luminous properties. Currently reported commercial wLEDs have a drawback in red emission missing, which leads to a relatively low color rendering index (CRI) and a relatively high correlated color temperature (CCT). In this work, Ce@Eu Sr-Si-O glass is fabricated using a high-temperature quenching method. The white light is available when the ratio of Ce 3+ /Eu 3+ equals 1, and the emitting color can be adjusted from blue to red by controlling the ratio of Ce 3+ /Eu 3+ . To further optimize the white light, Eu 3+ ions can be reduced to Eu 2+ according to the reaction of 6Eu 3+ + 2N 3− → 6Eu 2+ + N 2 ↑ by introducing Si 3 N 4 . As a result, the standard white light emission can be achieved in the Ce@Eu silicate glass contributed by the blue light from Ce 3+ , red light from Eu 3+ , and yellow-green light from Eu 2+ (two elements, three emission). This glass shows excellent luminous properties, such as a color coordinate is (0.3651, 0.3269) in CIE 1931 color coordinate diagram, a CRI is over 70, a high quantum yield of 36.02%, and a CCT of 4117 K.

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Effect of doping concentration and annealing temperature on the luminescence of novel orange red emitting CePO4:Sm3+ nanocrystals

Sisira

Jacob

Thomas

et al. 2019

Journal of Luminescence

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Photon Quantization in Sm³⁺ Doped Red Glass Phosphors for Laser‐Induced Illumination

Cited by 9 publications

References 56 publications

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Improving white light emission and quantum yield of Ce@Eu co‐doped silicate glass by reducing Eu³⁺ to Eu²⁺ with Si₃N₄

Effect of doping concentration and annealing temperature on the luminescence of novel orange red emitting CePO4:Sm3+ nanocrystals

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Photon Quantization in Sm3+ Doped Red Glass Phosphors for Laser‐Induced Illumination

Cited by 9 publications

References 56 publications

Microstructures and Luminescent Properties of Sm3+‐Doped KSr2Nb5O15 Prepared by Molten Salt Synthesis Method

Microstructures and Luminescent Properties of Sm3+‐Doped KSr2Nb5O15 Prepared by Molten Salt Synthesis Method

Improving white light emission and quantum yield of Ce@Eu co‐doped silicate glass by reducing Eu3+ to Eu2+ with Si3N4

Effect of doping concentration and annealing temperature on the luminescence of novel orange red emitting CePO4:Sm3+ nanocrystals

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Photon Quantization in Sm³⁺ Doped Red Glass Phosphors for Laser‐Induced Illumination

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Microstructures and Luminescent Properties of Sm³⁺‐Doped KSr₂Nb₅O₁₅ Prepared by Molten Salt Synthesis Method

Improving white light emission and quantum yield of Ce@Eu co‐doped silicate glass by reducing Eu³⁺ to Eu²⁺ with Si₃N₄