Probing the structure, morphology and multifold blue absorption of a new red-emitting nanophosphor for LEDs

TL;DR

This paper introduces a new Gd2CaZnO5:Eu3+ nanophosphor with strong blue absorption and red emission, potentially enhancing the performance of white LEDs by addressing limitations of conventional phosphors.

Contribution

A novel nanophosphor system with enhanced blue absorption and red emission for improved LED applications is developed and characterized.

Findings

Exhibits strong absorption at ~465 nm and red emission at ~611 nm.

Nanocrystalline with elongated morphology confirmed by microscopy.

Eu3+ ions successfully substituted Gd3+ in the host lattice.

Abstract

There has been a stringent demand for blue (~450-470 nm) absorbing and red (~611 nm) emitting material system in phosphor converted white light emitting diodes (WLEDs) available in the market. Conventionally used red-emitting Y2O3:Eu3+phosphor has negligible absorption for blue light produced by GaInN based LED chip. To address this issue, a new red-emitting Gd2CaZnO5:Eu3+ (GCZO:Eu3+) nanophosphor system having exceptionally strong absorption for blue (~465 nm) and significant red (~611 nm) photoluminescence (PL) is presented. This is attributed to a dominant f-f transition (5D0\rightarrow7F2) of Eu3+ ions, aroused due to an efficient energy transfer from the Gd3+ sites of the host lattice to Eu3+ ions. X-ray diffraction and microscopy observations revealed the nanocrystalline nature and a bit elongated morphology of the sample respectively. While the energy dispersive x-ray analysis identified the chemical constituents of the GCZO:Eu3+ nanophosphor, the color overlay imaging confirmed the substitution of Eu3+ for Gd3+ ions. It is highly anticipated that the multifold absorption at ~465 nm would certainly improve the color rendering properties of existing WLEDs.