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Unraveling the Eu<sup>2+</sup> → Mn<sup>2+</sup> Energy Transfer Mechanism in w-LED Phosphors

Atul D. Sontakke, Arnoldus J. van Bunningen, Freddy T. Rabouw, Sam Meijers, Andries Meijerink

2020The Journal of Physical Chemistry C70 citationsDOIOpen Access PDF

Abstract

Recent research on white light LED (w-LED) phosphors has focused on narrow-band green and red luminescent materials to improve the efficacy of w-LEDs and to widen the color gamut of w-LED-based displays. Mn2+ is a promising emitter capable of narrow-band emission, either green or red, depending on the local coordination. However, the extremely low absorption coefficients for the spin- and parity-forbidden d-d transitions in Mn2+ form a serious drawback and require addition of a sensitizer ion such as Ce3+ or Eu2+, with strong absorption in the blue. The performance of the codoped phosphor then critically depends on efficient energy transfer. Despite extensive research, a clear understanding of the Eu2+→ Mn2+ and Ce3+→ Mn2+ transfer mechanism is lacking. Typically, Dexter exchange interaction or electric dipole-quadrupole coupling are considered. Here we investigate Eu2+→ Mn2+ energy transfer in Ba2MgSi2O7 and show that the most probable mechanism is exchange interaction with fast (nanoseconds) energy transfer from Eu2+ to nearest-neighbor Mn2+ and much slower (&gt;100 ns) transfer to next-nearest neighbors, as expected for exchange interaction. We critically evaluate previous studies where the assignment of dipole-quadrupole interaction was erroneously based on CMn8/3 concentration dependence of energy transfer efficiencies. Preferential Eu2+-Mn2+ pair formation is suggested as a mechanism that enhances energy transfer efficiencies.

Topics & Concepts

PhosphorPhotoluminescenceQuadrupoleAbsorption (acoustics)Atomic physicsChemistryEnergy transferIonLuminescenceChemical physicsAnalytical Chemistry (journal)Materials scienceOptoelectronicsPhysicsOpticsOrganic chemistryChromatographyLuminescence Properties of Advanced MaterialsSolid-state spectroscopy and crystallographyAmmonia Synthesis and Nitrogen Reduction
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