Improving Photoelectron Localization to Significantly Enhanced Broadband Orange‐Light Emission in Hybrid Antimony Halides with Sb─Cl Secondary Bonding

Yuan, Jiantao; Qi, Zhikai; Zhang, Jian; Zhang, Nan; Zhang, Xian‐Ming

doi:10.1002/lpor.202301264

Laser & Photonics Reviews

2024

DOI: 10.1002/lpor.202301264

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Improving Photoelectron Localization to Significantly Enhanced Broadband Orange‐Light Emission in Hybrid Antimony Halides with Sb─Cl Secondary Bonding

Jiantao Yuan,

Zhikai Qi,

Jian Zhang

et al.

Abstract: Hybrid ns2 metal halides have attracted extensive attention due to the unique photophysical behavior. However, the reasonable improvement of photoluminescence efficiency by accurate structural modulation remains a great challenge. Herein, two kind of antimony halides with formulae as (S)/(R)‐[C6H16N2]3[SbCl5]2·2Cl ((S)/(R)‐1·2Cl) and (S)/(R)‐[C6H16N2]2[SbCl5]2 ((S)/(R)‐2) ([C6H16N2]2+ = 1,2‐Diaminocyclohexane) are developed, in which 0D [Sb4Cl20]8− clusters and 1D infinite [SbCl5]n2n− polyanion chains are adop… Show more

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High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

Tang,

Wang,

Bai

et al. 2024

Advanced Optical Materials

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Low‐dimensional lead‐free metal halide perovskites have attracted considerable attention for the development of multifunctional optoelectronic materials owing to their extensive structural diversity and adjustable optical properties. However, organic cation‐based low‐dimensional metal halides often exhibit limited thermal stability, while inorganic cations‐based ones have a poor solution processability. To address these challenges, this study proposes a hybrid organic–inorganic cation approach by utilizing both 4,4‐difluoropiperidine (DFPD) and cesium (Cs+) to prepare low‐dimensional metal halides: (DFPD)2CsInCl6. Two isostructural metal halides are developed: α‐(DFPD)2CsInCl6 and β‐(DFPD)2CsInCl6, which exhibit different space group symmetries. This strategy ensures both thermal stability and introduces structural diversity. Doping (DFPD)2CsInCl6 with antimony (Sb3+) enhances its PLQY from 0% to 100%. The emission centers of both materials exhibit temperature‐insensitive behavior and maintain efficient and stable PL emission even at high temperatures (up to 400 K), making them excellent candidates as thermally stable phosphor materials for solid‐state lighting applications. This work thus expands the scope of developing multifunctional low‐dimensional metal halides.

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High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

Tang,

Wang,

Bai

et al. 2024

Advanced Optical Materials

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Gradient Luminescence Enhancement in Organic Metal Halide Perovskites via the Suppression of [SbCl_n]^3–n Unit Distortion

Zeng,

Zhang,

Wang

et al. 2024

Inorg. Chem.

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Intrinsic stereochemical activity of the 5s 2 electron configuration in Sb 3+ leads to structural distortion within [SbCl n ] 3−n units, which, while stabilizing the material, paradoxically diminishes luminescence intensity due to induced asymmetry. To address this issue, a strategy, which encompasses increasing the structural dimensions and introducing In 3+ doping, was developed to mitigate the geometrical distortion in the [SbCl n ] 3−n units within the metal−organic perovskite (DABCO) 2 Sb 2 Cl 10 •H 2 O and (DABCO) 2 SbCdCl 9 • 2H 2 O (DABCO = triethylenediamine). This dimensional augmentation confines lattice distortion effectively, and the In 3+ doping modifies the 5s 2 electron configuration of Sb 3+ , thereby reducing the distortion at its origin. The unique suitability of indium-based halides as a matrix for Sb 3+ doping is underscored by our approach, which capitalizes on their ability to regulate the electron configuration of Sb 3+ . This strategy has been validated through crystallographic data from single-crystal X-ray diffraction. By effectively reducing the adverse effects of geometric distortion, several hundred-fold enhancements in the luminescent intensity of the material have been achieved by our methodology, leading to potential applications in white-light LEDs. This advancement not only highlights the pivotal role of structural symmetry in the optical properties of materials but also exemplifies the power of material engineering to optimize the optical performance.

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Optical activity levels of metal centers controlling multi-mode emissions in low-dimensional hybrid metal halides for anti-counterfeiting and information encryption

Ren,

Zhou,

Mao

et al. 2024

Chem. Sci.

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Improving Photoelectron Localization to Significantly Enhanced Broadband Orange‐Light Emission in Hybrid Antimony Halides with Sb─Cl Secondary Bonding

Cited by 3 publications

References 78 publications

High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

Gradient Luminescence Enhancement in Organic Metal Halide Perovskites via the Suppression of [SbCl_n]^3–n Unit Distortion

Optical activity levels of metal centers controlling multi-mode emissions in low-dimensional hybrid metal halides for anti-counterfeiting and information encryption

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Improving Photoelectron Localization to Significantly Enhanced Broadband Orange‐Light Emission in Hybrid Antimony Halides with Sb─Cl Secondary Bonding

Cited by 3 publications

References 78 publications

High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

High‐Efficiency Luminescence and Robust Thermal Quenching Resistance in Organic–Inorganic Hybrid Indium‐Based Metal Halides

Gradient Luminescence Enhancement in Organic Metal Halide Perovskites via the Suppression of [SbCln]3–n Unit Distortion

Optical activity levels of metal centers controlling multi-mode emissions in low-dimensional hybrid metal halides for anti-counterfeiting and information encryption

Contact Info

Product

Resources

About

Gradient Luminescence Enhancement in Organic Metal Halide Perovskites via the Suppression of [SbCl_n]^3–n Unit Distortion