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Ultra‐Efficient, Broadband‐Excitable NIR Emission in Lead‐Free Cs <sub>2</sub> NaYbCl <sub>6</sub> via Cl → Yb Charge Transfer and Cr <sup>3+</sup> Sensitization

Chunli Zhao, Chengjie Wang, Jia'an Song, Haolan Wang, Yu Zhao, Jiaqi Wang, Zixun Zhao, Xiuling Li, Jinli Liu, Kebin Lin, Zhiming Wang, Arup Neogi

2025Advanced Optical Materials5 citationsDOI

Abstract

Abstract Ytterbium ions (Yb 3+ ) are commonly employed to extend the luminescent properties of metal halide perovskites due to their characteristic narrow‐band near‐infrared (NIR) emission. However, Yb 3+ still suffers from weak emission in lead‐free halide double perovskite systems owing to the parity‐forbidden 4f‐4f transitions with intrinsically weak absorption. In this study, undoped Cs 2 NaYbCl 6 single crystals demonstrate an exceptional NIR photoluminescence quantum yield (PLQY) of 43.6%. Through strategic incorporation of 5% transition metal Cr 3+ ions, the system achieves an ultra‐broad excitation spectrum spanning UV, visible, and NIR regions while preserving the characteristic narrow‐band Yb 3+ emission. Theoretical investigations encompassing band structure analysis, Bader charge calculations, and electron localization function (ELF) reveal that the highly localized [YbCl 6 ] 3− octahedra facilitate efficient NIR emission through Cl − →Yb 3+ charge transfer (CT) transitions. Cr 3+ doping introduces impurity levels, disrupts the Cl − →Yb 3+ CT process, and induces sublattice distortion, thereby serving as sensitization channels for intrinsic Yb 3+ emission. Leveraging the broadened excitation spectrum, a NIR solid‐state lighting system excitable by UV/visible/NIR illumination is engineered. These findings provide novel design principles for photo‐sensitization processes and application scenarios in lanthanide‐based perovskites and coordination compounds.

Topics & Concepts

Materials scienceYtterbiumPerovskite (structure)PhotoluminescenceHalideDopingLuminescenceIonExcitationQuantum yieldCharge (physics)OctahedronChemical physicsImpurityOptoelectronicsElectron transferTransition metalMetalNear-infrared spectroscopyMolecular physicsYield (engineering)PhotochemistryAtomic physicsMetal ions in aqueous solutionPhotonElectronAtomic electron transitionSensitizationPerovskite Materials and ApplicationsLuminescence Properties of Advanced MaterialsOptical properties and cooling technologies in crystalline materials
Ultra‐Efficient, Broadband‐Excitable NIR Emission in Lead‐Free Cs <sub>2</sub> NaYbCl <sub>6</sub> via Cl → Yb Charge Transfer and Cr <sup>3+</sup> Sensitization | Litcius