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Unveiling Local Electronic Structure of Lanthanide‐Doped Cs<sub>2</sub>NaInCl<sub>6</sub> Double Perovskites for Realizing Efficient Near‐Infrared Luminescence

Siyuan Han, Datao Tu, Zhi Xie, Yunqin Zhang, Jiayao Li, Yifan Pei, Jin Xu, Zhongliang Gong, Xueyuan Chen

2022Advanced Science112 citationsDOIOpen Access PDF

Abstract

Abstract Lanthanide ion (Ln 3+ )‐doped halide double perovskites (DPs) have evoked tremendous interest due to their unique optical properties. However, Ln 3+ ions in these DPs still suffer from weak emissions due to their parity‐forbidden 4f–4f electronic transitions. Herein, the local electronic structure of Ln 3+ ‐doped Cs 2 NaInCl 6 DPs is unveiled. Benefiting from the localized electrons of [YbCl 6 ] 3− octahedron in Cs 2 NaInCl 6 DPs, an efficient strategy of Cl − ‐Yb 3+ charge transfer sensitization is proposed to obtain intense near‐infrared (NIR) luminescence of Ln 3+ . NIR photoluminescence (PL) quantum yield (QY) up to 39.4% of Yb 3+ in Cs 2 NaInCl 6 is achieved, which is more than three orders of magnitude higher than that (0.1%) in the well‐established Cs 2 AgInCl 6 via conventional self‐trapped excitons sensitization. Density functional theory calculation and Bader charge analysis indicate that the [YbCl 6 ] 3− octahedron is strongly localized in Cs 2 NaInCl 6 :Yb 3+ , which facilitates the Cl − ‐Yb 3+ charge transfer process. The Cl − ‐Yb 3+ charge transfer sensitization mechanism in Cs 2 NaInCl 6 :Yb 3+ is further verified by temperature‐dependent steady‐state and transient PL spectra. Furthermore, efficient NIR emission of Er 3+ with the NIR PLQY of 7.9% via the Cl − ‐Yb 3+ charge transfer sensitization is realized. These findings provide fundamental insights into the optical manipulation of Ln 3+ ‐doped halide DPs, thus laying a foundation for the future design of efficient NIR‐emitting DPs.

Topics & Concepts

LanthanideLuminescenceDopingInfraredMaterials scienceNanotechnologyOptoelectronicsInorganic chemistryChemistryIonPhysicsOpticsOrganic chemistryPerovskite Materials and ApplicationsLuminescence Properties of Advanced MaterialsOptical properties and cooling technologies in crystalline materials