Compositional regulation of multi-component GYGAG:Ce scintillation ceramics: Self-sintering-aid effect and afterglow suppression

Zhu, Danyang; Wu, Lexiang; Beitlerova, Alena; Kucerkova, Romana; Chewpraditkul, Weerapong; Nikl, Martin; Li, Jiang

doi:10.26599/jac.2023.9220797

Cited by 7 publications

(2 citation statements)

References 47 publications

(45 reference statements)

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“…A slow component in the scintillation response of scintillating materials is very unfavorable for HEP experiments as it can cause the pile‐up effect. Co‐doping of Mg 2+ and Ca 2+ proved to be an effective strategy for accelerating scintillation decay and suppressing slow components, but these two similar divalent ions produce different practical effects 11–15 . Mg 2+ co‐doping may show an advantage in boosting light yield (LY), while Ca 2+ co‐doping is indisputable in a significant increase of the fast‐to‐total (F/T) ratio 16–18 .…”

Section: Introductionmentioning

confidence: 99%

“…Co-doping of Mg 2+ and Ca 2+ proved to be an effective strategy for accelerating scintillation decay and suppressing slow components, but these two similar divalent ions produce different practical effects. [11][12][13][14][15] Mg 2+ co-doping may show an advantage in boosting light yield (LY), while Ca 2+ co-doping is indisputable in a significant increase of the fast-to-total (F/T) ratio. [16][17][18] In 2020, in the results reported by Hu et al , 5 the F/T ratio (LY 0.2 µs /LY 3 µs ) of Ce,Mg:LuAG ceramics tops out at about 80%, while that of Ce,Ca:LuAG ceramics approaches 90%.…”

Section: Introductionmentioning

confidence: 99%

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Stoichiometric modulation and scintillation property characterization of Ce,Ca:LuAG ceramics

Zhu,

Cai,

Beitlerova

et al. 2024

J Am Ceram Soc.

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Due to the huge difference in the solubility‐product constants (Ksp) between the precipitates of Lu and Al, the synthesis of lutetium aluminum garnet (Lu3Al5O12, LuAG) nanopowders by coprecipitation method is prone to Lu loss, resulting in the creation of Al2O3 secondary phase. In this work, coprecipitated (Ce0.001Ca0.0015Lu(0.9975+x%))3Al5O12 (x = 0, 0.9, 1.2, 1.5) nanopowders with different starting stoichiometries are synthesized and combined with vacuum pre‐sintering and hot‐isostatic pressing to fabricate scintillating ceramics. The effect of compensated Lu content on the phase composition, microstructure, optical properties, and scintillation performance of ceramics is analyzed. The complete elimination of the secondary phase requires an additional compensation of 1.2% of Lu, which gives the best transmittance in ceramics. When x = 1.5, excessive Lu forms LuAl antisite defect, leading to the decrease of both light yield and intensity of the fast scintillation component.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stoichiometric modulation and scintillation property characterization of Ce,Ca:LuAG ceramics

Zhu,

Cai,

Beitlerova

et al. 2024

J Am Ceram Soc.

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Transparent Composite Ceramic@aluminum with Ultra‐High Thermal Conductivity for High‐Brightness Laser‐Driven Lighting

Xi,

Zhou,

et al. 2024

Adv Funct Materials

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Next‐generation high‐brightness lighting faces a big challenge in developing laser‐drivable color‐converting materials with effective thermal management. Herein, a new material architecture of Al2O3‐Y3Al5O12: Ce3+ (YAG: Ce) transparent composite ceramics coated with Al film (TCC@Al) is proposed. The as‐prepared material shows the highest thermal conductivity (29.3 W m−1 K−1) among YAG: Ce‐related transparent ceramics (TC) ever reported owing to the combination role of short‐range thermal conduction of Al2O3 microcrystals and long‐range thermal conduction of Al film. Temperature‐dependent photoluminescence (PL) spectra and femtosecond transient absorption (fs‐TA) spectra evidence the importance of thermal management, whereby the luminescent loss of TCC@Al is only 8.92% at 450 K and is far smaller than TC counterpart (15.86%). Importantly, no obvious luminescence saturation is detected upon 20 W mm−2 blue laser irradiation and the inhomogeneous angular color distribution is suppressed by the scatter of Al2O3 microcrystals, yielding uniform white light with ultra‐high luminous flux (LF) of 4294 lm@20 W mm−2 and luminous efficacy (LE) of 215 lm W−1. As a consequence, the present TCC@Al‐converted laser‐driven lighting prototype exhibits much better optical performance than the commercial TC‐based one.

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Removal of deep traps in Lu2O3:Tm phosphors via formation of continuous solid solutions with In2O3 enabling widely tailorable bandgap energy

Lu,

Shen,

Shi

et al. 2024

Advanced Powder Technology

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Compositional regulation of multi-component GYGAG:Ce scintillation ceramics: Self-sintering-aid effect and afterglow suppression

Cited by 7 publications

References 47 publications

Stoichiometric modulation and scintillation property characterization of Ce,Ca:LuAG ceramics

Stoichiometric modulation and scintillation property characterization of Ce,Ca:LuAG ceramics

Transparent Composite Ceramic@aluminum with Ultra‐High Thermal Conductivity for High‐Brightness Laser‐Driven Lighting

Removal of deep traps in Lu2O3:Tm phosphors via formation of continuous solid solutions with In2O3 enabling widely tailorable bandgap energy

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