A violet emission in ZnS:Mn,Eu: Luminescence and applications for radiation detection

Ma, Li; Jiang, Ke; Liu, Xiao Tang; Chen, Wei

doi:10.1063/1.4868221

Cited by 20 publications

(13 citation statements)

References 46 publications

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“…1A ,B). They are cost-effective, easy to synthesize, and readily embedded or coated onto glasses 7 8 9 . When illuminated by a UV light source, they convert UV light to narrow-band green or red light, or wide-spectrum white light ( Fig.…”

Section: Resultsmentioning

confidence: 99%

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Sahi

Peng

et al. 2016

Sci Rep

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We developed new optic devices – singly-doped luminescence glasses and nanoparticle-coated lenses that convert UV light to visible light – for improvement of visual system functions. Tb3+ or Eu3+ singly-doped borate glasses or CdS-quantum dot (CdS-QD) coated lenses efficiently convert UV light to 542 nm or 613 nm wavelength narrow-band green or red light, or wide-spectrum white light, and thereby provide extra visible light to the eye. In zebrafish (wild-type larvae and adult control animals, retinal degeneration mutants, and light-induced photoreceptor cell degeneration models), the use of Tb3+ or Eu3+ doped luminescence glass or CdS-QD coated glass lenses provide additional visible light to the rod and cone photoreceptor cells, and thereby improve the visual system functions. The data provide proof-of-concept for the future development of optic devices for improvement of visual system functions in patients who suffer from photoreceptor cell degeneration or related retinal diseases.

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Section: Resultsmentioning

confidence: 99%

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Sahi

Peng

et al. 2016

Sci Rep

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“…ZnS is an excellent luminescence host material and, frequently, transition and rare‐earth (RE) metal impurities are doped in the ZnS host to obtain impure luminescence. In recent years, however, it has been reported that doping of transition and RE metal impurities can greatly enhance the luminescence intensity of ZnS materials . For example, Yang et al reported that emission intensities increased by about five to six times in ZnS nanocrystallites after doping with Ce, Y, Nd, Er and Tb metal ions .…”

Section: Introductionmentioning

confidence: 99%

“…Sridevi et al reported that the fluorescence intensities of ZnS nanoparticles, doped with La, Mn, Co. and Ni metal ions, were five to six times that of pure ZnS . Importantly, it has been reported more recently that doping of Eu 2 + can increase the luminescence of ZnS materials . Ashwini et al reported that the luminescence intensity in ZnS:Eu 2 + nanoparticles was enhanced with increasing doping concentrations of Eu 2 + .…”

Section: Introductionmentioning

confidence: 99%

“…The reason for this increase is ascribed to an increase in defect sites and traps with the increasing number of Eu 2 + ions doped into ZnS nanoparticles . Ma et al reported that doping with Eu 2 + promoted the emission intensity of bulk ZnS phosphors by 7–30 times, explained as the formation of Eu 2 + ‐related defects . In short, luminescence enhancement in the Eu 2 + ‐doped ZnS materials is ascribed to the introduction of defects and traps .…”

Section: Introductionmentioning

confidence: 99%

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Eu²⁺‐induced enhancement of defect luminescence of ZnS

Zhang

Wei

2016

Luminescence

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The Eu -induced enhancement of defect luminescence of ZnS was studied in this work. While photoluminescence (PL) spectra exhibited 460 nm and 520 nm emissions in both ZnS and ZnS:Eu nanophosphors, different excitation characteristics were shown in their photoluminescence excitation (PLE) spectra. In ZnS nanophosphors, there was no excitation signal in the PLE spectra at the excitation wavelength λ > 337 nm (the bandgap energy 3.68 eV of ZnS); while in ZnS:Eu nanophosphors, two excitation bands appeared that were centered at 365 nm and 410 nm. Compared with ZnS nanophosphors, the 520 nm emission in the PL spectra was relatively enhanced in ZnS:Eu nanophosphors and, furthermore, in ZnS:Eu nanophosphors the 460 nm and 520 nm emissions increased more than 10 times in intensity. The reasons for these differences were analyzed. It is believed that the absorption of Eu intra-ion transition and subsequent energy transfer to sulfur vacancy, led to the relative enhancement of the 520 nm emission in ZnS:Eu nanophosphors. In addition, more importantly, Eu acceptor-bound excitons are formed in ZnS:Eu nanophosphors and their excited levels serve as the intermediate state of electronic relaxation, which decreases non-radiative electronic relaxation and thus increases the intensity of the 460 nm and 520 nm emission dramatically. In summary, the results in this work indicate a new mechanism for the enhancement of defect luminescence of ZnS in Eu -doped ZnS nanophosphors. Copyright © 2016 John Wiley & Sons, Ltd.

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“…Intense emission from ZnS layer not only is used for solid state lighting but also offers a very sensitive method for radiation detection [8]. Hence, the importance of excitation enhancement in PL layers is highlighted.…”

Section: Introductionmentioning

confidence: 99%

Absorption enhancement in thin-film photoluminescence layers with metal nanoparticles inter-coupling engineering

2015

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We analyze the enhancement in optical absorption of a photoluminescence ZnS layer with embedded spherical metal nanoparticles (MNPs). Using introduced optical model based on the boundary element method (BEM), the so-called scattering cross-section over absorption cross-section (SCS/ACS) ratio has been defined that represents the strength of re-absorption by scattering. According to the collective behavior of the interacting plasmonic nanoparticles in an array, an optimum SCS/ACS is obtained for inter-particle distance over the particle diameter. This parameter gives a hint for the nanoparticle density and size in practical applications and is consistent for all of the metallic nanoparticles.

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A violet emission in ZnS:Mn,Eu: Luminescence and applications for radiation detection

Cited by 20 publications

References 46 publications

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Eu²⁺‐induced enhancement of defect luminescence of ZnS

Absorption enhancement in thin-film photoluminescence layers with metal nanoparticles inter-coupling engineering

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A violet emission in ZnS:Mn,Eu: Luminescence and applications for radiation detection

Cited by 20 publications

References 46 publications

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Luminescence- and nanoparticle-mediated increase of light absorption by photoreceptor cells: Converting UV light to visible light

Eu2+‐induced enhancement of defect luminescence of ZnS

Absorption enhancement in thin-film photoluminescence layers with metal nanoparticles inter-coupling engineering

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Eu²⁺‐induced enhancement of defect luminescence of ZnS