Litcius/Paper detail

Stable and Highly Efficient Near‐Infrared Emission Achieved in Spinel Blocks

Xi‐Bao Zhang, Liang Zhou, Hongpeng You

2025Advanced Materials38 citationsDOI

Abstract

Abstract Developing efficient and stable near‐infrared emitters related to Cr 3+ ‐pairs for advanced optoelectronic devices remains a challenge due to concentration quenching effects and unclear luminescence mechanisms. In this study, Cr 3+ ions are incorporated into a matrix structure consisting of ZnAl₂O₄ spinel units separated by 11.312 Å, effectively restricting energy transfer between luminescent centers and alleviating quenching effects. Computational analysis identifies the lattice positions of isolated Cr 3+ ions and Cr 3+ ‐pairs at different doping levels, providing insights into their spatial distribution and local structural environments. Photoluminescence measurements reveals a Cr 3+ ‐concentration‐dependent emission broadening, with a Cr 3+ ‐pair emission band peak at 750 nm, while detailed spectral analysis further clarified the energy level structure of Cr 3+ ‐pairs for the first time. Enhanced material performance is achieved through flux‐assisted synthesis, reaching a high external quantum efficiency of 58.3%. Consequently, the assembled pc‐LEDs exhibit minimal efficiency roll‐off and achieve a high output of 183 mW at 650 mA, demonstrating their potential in near‐infrared light sources and night vision technology application.

Topics & Concepts

Materials scienceSpinelPhotoluminescenceLuminescenceInfraredIonQuenching (fluorescence)Quantum efficiencyOptoelectronicsDopingLight-emitting diodePhotochemistryFluorescenceOpticsChemistryPhysicsOrganic chemistryMetallurgyLuminescence Properties of Advanced MaterialsLuminescence and Fluorescent MaterialsPerovskite Materials and Applications