Site Preference Induced Dual‐Wavelength Mn2+ Upconversion in K2NaScF6:Yb3+, Mn2+ and Its Application in Temperature Sensing

Liu, Dongxi; Zeng, Chuanyu; Wang, Juan; Liang, Anxian; Zhao, Jialong; Zou, Bingsuo; Han, Xinxin

doi:10.1002/adom.202302819

Advanced Optical Materials

2024

DOI: 10.1002/adom.202302819

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Site Preference Induced Dual‐Wavelength Mn²⁺ Upconversion in K₂NaScF₆:Yb³⁺, Mn²⁺ and Its Application in Temperature Sensing

Dongxi Liu,

Chuanyu Zeng,

Juan Wang

et al.

Abstract: The realization of dual‐wavelength Mn2+ upconversion (UC) luminescence that exhibits different thermal responsive behaviors is promising for non‐invasive optical temperature sensing applications. However, it remains challenging to achieve such luminescence of Mn2+ ions. Herein, due to the site preference characteristics of Mn2+, color tunable and dual‐wavelength Mn2+ UC luminescence is achieved in K2NaScF6:Yb3+, Mn2+ by simply adjusting the Mn2+ doping concentration. Structural and spectral analysis as well as… Show more

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Cited by 6 publications

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High‐Stability Hybrid Antimony Halides for Thermometry in Power System Component or Circuit Monitoring

Liu,

Hou,

Lin

et al. 2024

Adv Funct Materials

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Organic–inorganic metal halides (OIMHs) possess low preparation costs and high photoluminescence quantum yield. Within a specific range, the temperature‐dependent nature of OIMHs' luminescent lifetime facilitates temperature sensing and thermal imaging functionalities. In this study, a non‐toxic (C10H22N)6SbBr9·H2O ([C10H22N]+ is 4‐(tert‐buty)cyclohexanamine cation) with a 0D structure crystallized in the Pbcn space group is obtained. Under blue light excitation at room temperature, it demonstrates intense broad emission centered at 635 nm. Further investigation into the correlation between temperature and photoluminescence lifetime has unveiled exceptional temperature sensing precision. The relative sensitivities within the range of power system temperature alert 30–70 °C lie between 2.5% and 4.5% K−1. This matches the typical high‐temperature warning threshold for power systems. Moreover, after immersion in water and alcohol, the compound maintains remarkable stability, with multiple heating/cooling cycles confirming its reliability under test temperatures. Additionally, a composite thin‐film device composed of (C10H22N)6SbBr9·H2O, showcasing its potential as a stable and durable thermal imaging temperature sensing device is fabricated.

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High‐Stability Hybrid Antimony Halides for Thermometry in Power System Component or Circuit Monitoring

Liu,

Hou,

Lin

et al. 2024

Adv Funct Materials

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A Thermo‐Responsive MOFs for X‐Ray Scintillator

Li,

Zhang

et al. 2024

Advanced Materials

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Thermo‐responsive smart materials have aroused extensive interest due to the particular significance of temperature sensing. Although various photoluminescent materials are explored in thermal detection, it is not applicable enough in X‐ray radiation environment where the accuracy and reliability will be influenced. Here, a strategy is proposed by introducing the concept of radio‐luminescent functional building units (RBUs) to construct thermo‐responsive lanthanide metal‐organic frameworks (Ln‐MOFs) scintillators for self‐calibrating thermometry. The rational designs of RBUs (including organic ligand and Tb3+/Eu3+) with appropriate energy levels lead to high‐performance radio‐luminescence. Ln‐MOFs scintillators exhibit perfect linear response to X‐ray, presenting low dose rate detection limit (min ≈156.1 nGyairs‐1). Self‐calibrating detection based on ratiometric XEL intensities is achieved with good absolute and relative sensitivities of 6.74 and 8.1%K‐1, respectively. High relative light yield (max ≈39000 photons MeV−1), imaging spatial resolution (max ≈18 lp mm‐1), irradiation stability (intensity ≈100% at 368 K in total dose up to 215 Gyair), and giant color transformation visualization benefit the applications, especially the in situ thermo‐responsive X‐ray imaging. Such strategy provides a promising way to develop the novel smart photonic materials with excellent scintillator performances.

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Tunable Multicolor Emission and High Thermal Stability in Single‐Matrix Luminescent Crystals Based on Calcium Perovskites for Advanced Solid‐State Lighting Applications

Wang,

Pan,

Ding

et al. 2024

Advanced Optical Materials

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The development of environmentally friendly full‐inorganic luminescent materials with tunable emission properties and exceptional thermal stability is of paramount importance for applications in optoelectronic devices, solid‐state lighting, and anti‐counterfeiting technologies. In this study, a novel luminescent crystal based on calcium perovskites Cs2CaCl4·2H2O (CCCH) are explored using a hydrothermal method. Simultaneous co‐doping of CCCH with Sn2+ and Mn2+ yields the s‐p transition‐induced cyan light from Sn2+ and d‐d transition‐induced yellow light from Mn2+. It demonstrates effective energy transfer from self‐trapped exciton (STE) of matrix CCCH and s‐p transition of Sn2+ to Mn2+, synergizing composite white lights with tunable colors. Furthermore, the incorporation of Sn2+ into CCCH introduces a red shift from blue to cyan emission with a remarkable enhancement in luminescent intensity by a factor of 12 times. The crystal orbital Hamiltonian populations (─COHP) calculations revealed the crucial role of Mn2+ in lattice stability, as evidenced by the decomposition temperature exceeding 305 °C for CCCH:Sn2+,Mn2+ whereas 210 °C for undoped CCCH matrix. This research provides a comprehensive investigation of the luminescent properties of CCCH:Sn2+,Mn2+ crystal, holding significant promise for practical technological advancements in lighting and anti‐counterfeiting technologies.

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Site Preference Induced Dual‐Wavelength Mn²⁺ Upconversion in K₂NaScF₆:Yb³⁺, Mn²⁺ and Its Application in Temperature Sensing

Cited by 6 publications

References 45 publications

High‐Stability Hybrid Antimony Halides for Thermometry in Power System Component or Circuit Monitoring

High‐Stability Hybrid Antimony Halides for Thermometry in Power System Component or Circuit Monitoring

A Thermo‐Responsive MOFs for X‐Ray Scintillator

Tunable Multicolor Emission and High Thermal Stability in Single‐Matrix Luminescent Crystals Based on Calcium Perovskites for Advanced Solid‐State Lighting Applications

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