Structural and spectroscopic characterizations of a new near-UV-converting cyan-emitting RbBaScSi3O9:Eu2+ phosphor with robust thermal performance

To facilitate the next generation of White Light Emitting Diodes (WLEDs) with higher color rendering and warm lighting, the development of inorganic phosphor for efficient conversion of photons from blue/near-UV light to other visible wavelengths is essential. In this regard, we demonstrate a system...

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Bibliographic Details
Published in:Journal of alloys and compounds 2017-08, Vol.713, p.138-147
Main Authors: Ray, Sudeshna, Tadge, Prachi, Dhoble, S.J., Nair, Govind B., Singh, Akash, Singh, Abhishek Kumar, Rai, Monika, Chen, Teng Ming, Rajput, Vinita
Format: Article
Language:English
Subjects:
Conversion
Emission analysis
Emission spectroscopy
LED
Light emitting diodes
Measurement
Mineral inspired
Organic light emitting diodes
PGMS
Photoluminescence
Photons
Quantum efficiency
Quenching
Rietveld refinement
Scandium
Solid state physics
Thermal stability
Ultraviolet radiation
White light
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Summary:To facilitate the next generation of White Light Emitting Diodes (WLEDs) with higher color rendering and warm lighting, the development of inorganic phosphor for efficient conversion of photons from blue/near-UV light to other visible wavelengths is essential. In this regard, we demonstrate a systematic, cost effective, solution-processable, easily scalable and fully controllable synthesis of a series of RbBaScSi3O9:xEu2+ (x = 0.2, 0.5, 2, 5, 7), a new cyan emitting scandium silicate based phosphor with 79% internal quantum efficiency under n-UV excitation with robust thermal performance. The concept as well as the methodology of using a “Mineral Inspired Approach” emerges as a new blueprint for the rational design of novel phosphor for phosphor converted WLEDs. The structural refinement, electronic structural calculation using “Density Functional Theory”, characteristic photoluminescence study, lifetime measurement as well as the thermal quenching properties of the phosphor has been investigated in detail. Owing to the highly efficient cyan emission at λmax ∼492 nm a full-width at half-maximum of 63 cm−1 that shows only very low thermal quenching (89.28% relative to the PL intensity at 150 °C with respect to that of measured at room temperature), reflects the great potential for the industrial application of this particular phosphor. [Display omitted] •“Amorphous Metal Complex Method” adopted for synthesis.•Rietveld refinement and Electronic Structural Calculation by Density Functional Theory reported.•365 nm, 400 nm and 425 nm LED chips can be used for the excitation.•The phosphor retains 89.28% of its room temperature PL intensity at 150 °C.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2017.03.366