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Realizing cool and warm white-LEDs based on color controllable (Sr,Ba)<sub>2</sub>Al<sub>3</sub>O<sub>6</sub>F:Eu<sup>2+</sup> phosphors obtained <i>via</i> a microwave-assisted diffusion method

P.G. Ranjith, S. Sreevalsa, Pritha Patra, Sudipta Som, Ammu Menon, K. Jayanthi, K. Annapurna, N. M. Anoop Krishnan, Amarnath R. Allu, Subrata Das

2021Physical Chemistry Chemical Physics20 citationsDOI

Abstract

Globally, phosphor converted white-LEDs (W-LEDs) are among the most suitable sources to reduce energy consumption. Nevertheless, modernization of efficient broadband emitting phosphors is most crucial to improve the W-LED performance. Herein, we synthesized a series of novel broadband emitting Sr2-xAl3O6F:xEu2+ phosphors via a new microwave-assisted diffusion method. Rietveld refinement of the obtained X-ray diffraction results was performed to recognize the exact crystal phase and the various cationic sites. Oxygen vacancies (VO) formed under synthetic reducing conditions enabled Sr2Al3O6F to demonstrate bright self-activated bluish emission. Doping of Eu2+ ions unlocked the energy transfer process from the host to the activator ions, owing to which, the self-activated emission diminished and the Eu2+-doped sample showed amplified bluish-green emission. The gradual increase in Eu2+ concentrations regulated the controllable emissions from the bluish (0.34, 0.42) to the greenish (0.38, 0.43) zone under UV excitation. Because of the different absorption preferences of Eu2+ ions located at the different Sr2+ sites, Sr2-xAl3O6F:xEu2+ exhibited bluish-white emission under blue irradiation. A further enhancement in PL intensity had been observed by the cation substitution of Ba2+ for Sr2+ sites in the optimum Sr1.95Al3O6F:0.05Eu2+ phosphor. The as-fabricated W-LEDs utilizing the optimized Sr1.75Ba0.2Al3O6F:0.05Eu2+ phosphor exhibited a cool-white light emission along with a 372 nm NUV-LED and a 420 nm blue-LED with a moderate CRI of 70 and a CCT above 6000 K. Such cool white emission was controlled to natural white with the CCT close to 5000 K, and the CRI above 80 via utilizing a suitable red emitting phosphor. The W-LED performances of the optimized phosphor justified its applicability to produce white light for lighting applications.

Topics & Concepts

PhosphorLight-emitting diodeWhite lightAnalytical Chemistry (journal)LuminescenceMaterials sciencePhysicsChemistryOptoelectronicsChromatographyLuminescence Properties of Advanced Materials