Multi‐Mode Optical Manometry Based on Li4SrCa(SiO4)2:Eu2+ Phosphors

Su, Ke; Mei, Lefu; Guo, Qingfeng; Shuai, Pengfei; Wang, Yujia; Liu, Yukun; Jiang, Yang; Peng, Zhijian; Zou, Bo; Liao, Libing

doi:10.1002/adfm.202305359

Adv Funct Materials

2023

DOI: 10.1002/adfm.202305359

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Multi‐Mode Optical Manometry Based on Li₄SrCa(SiO₄)₂:Eu²⁺ Phosphors

Ke Su

Lefu Mei

Qingfeng Guo

et al.

Abstract: Optical manometry is a highly promising method for measuring pressure. However, its wider application is limited by the lower sensitivity and influenced by environmental factors. Herein, multi‐mode optical pressure sensors based on Eu2+‐doped Li4SrCa(SiO4)2 phosphors suitable for a variety of complex pressure‐measuring environments are designed. The phosphors contain two separate luminescence centers at 443 nm (EuSr) and 584 nm (EuCa), respectively. In the lower pressure range, the emission peak undergoes a ma… Show more

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2024

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Cited by 19 publications

References 46 publications

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Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Liu,

Li,

Qin

et al. 2024

Advanced Materials

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The quest for artificial light sources that mimic sunlight's spectral characteristics has been a long‐standing endeavor, particularly for applications in anticounterfeiting, agriculture, and color hue detection. Conventional sunlight simulators, such as xenon lamps, are often cost‐prohibitive and bulky, limiting their adoption. In this regard, the development of a series of single‐phase phosphors Ca9LiMg1‐xAl2x/3(PO4)7:0.1Eu2+ (x = 0‐0.75) with sunlight‐like emission described in this work holds immense promise as a compact and economical light source alternative. The phosphors have been obtained by an original heterovalent substitution method and emit a broad spectrum that encompasses the entire visible region, spanning from violet to deep red. Notably, the phosphor with x = 0.5 exhibits an impressive full width at half maximum of 330 nm. A synergistic interplay of experimental investigations and density‐functional theory calculations unveils the underlying mechanism behind sunlight‐like emission. It is attributed to the local structural perturbations introduced by the heterovalent substitution of Al3+ for Mg2+, leading to a varied distribution of Eu2+ within the lattice. Subsequent characterization of a series of organic dyes combining absorption spectroscopy with convolutional neural network analysis convincingly demonstrates the potential of this phosphor in portable photodetection devices. Broad‐spectrum light source testing empowers our model to precisely differentiate dye patterns. This points to the phosphor being ideal for mimicking sunlight. And beyond this demonstrated application, we envision the phosphor's utility in other relevant domains, including visible light communication and smart agriculture. These findings not only enrich our understanding of luminescent materials design but also pave the way for advancements in various application areas.This article is protected by copyright. All rights reserved

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Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Liu,

Li,

Qin

et al. 2024

Advanced Materials

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Tailoring Ultra‐Wide Visible‐NIR Luminescence by Ce³⁺/Cr³⁺/Yb³⁺‐alloying Sc‐Based Oxides for Multifunctional Optical Applications

Zhang,

Dang,

Wan

et al. 2024

Advanced Optical Materials

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Visible‐to‐near‐infrared (VIS‐NIR) luminescent materials are in great demand in the field of non‐destructive testing such as component determination and hyperspectral imaging. Although Cr3+‐activated phosphors are widely reported, controllable tailoring ultra‐wide VIS‐NIR luminescence excited by blue light is still a challenge. The strategies of cationic substitution and energy transfers are effective for adjusting the luminescence of Cr3+‐activated phosphors. In this work, a series of Cr3+‐doped Sc‐based solid solution phosphors (Ba3‐mSrmSc4O9:Cr3+) are reported. Under the excitation of blue light, these phosphors exhibit broadband emission due to the different luminescence centers induced by Cr3+ occupying different cationic sites. Because of the weaker crystal field strength, Cr3+ realizes a broadband emission with a longer peak position (λem = 820 nm) and broader full width at half maximum (FWHM≈182 nm) in Ba2SrSc4O9. Furthermore, Ce3+/Yb3+ ions are introduced into Ba2SrSc4O9:Cr3+, achieving an ultra‐wide VIS‐NIR luminescence (460–1200 nm) by the Ce3+→Cr3+→Yb3+ multiple energy transfers. Designing energy transfers is beneficial to improve the quantum efficiency and weaken the thermal quenching. Finally, the NIR phosphor‐converted light‐emitting diode (pc‐LED) fabricated by Ba2SrSc4O9:Cr3+ demonstrates great potential in night‐vision and water component detection. This work provides an effective design idea for controllable tailoring ultra‐wide VIS‐NIR luminescence by chemical substitution and energy transfer.

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Super‐Sensitive Multi‐Modal Optical Manometer Based on Huge Pressure‐Induced Spectral Red‐Shift and Broadening of Mn²⁺ Emission Band in Green‐Emitting Zn₂GeO₄ Phosphors

Xue,

Runowski,

Soler‐Carracedo

et al. 2024

Advanced Optical Materials

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To overcome the small sensitivities of luminescent manometers, Mn2+‐activated Zn2GeO4 green‐emitting phosphors with admirable manometric characteristics are synthesized. The structural stability of the studied samples is theoretically and experimentally investigated. Moreover, as pressure elevates, a huge spectral red‐shift and a broadening of the emission band are observed in studied samples, contributing to color‐tunable luminescence, i.e., from green to yellow, and ultimately to orange–red. Specifically, when pressure increases to 6.76 GPa, the emission band centroid shifts from 535.9 to 634.9 nm, leading to a superior sensitivity of dλ/dp = 21.3 nm/GPa. Whereas, in the same operating pressure range, the full width at half maximum (FWHM) of the emission band rises from 32.3 to 102.9 nm, resulting in unprecedentedly high sensitivity of dFWHM/dp = 17.0 nm/GPa. Furthermore, through analyzing the pressure‐dependent color coordinates, a maximum sensitivity of 29.43% GPa−1 is achieved, when x‐coordinate is adopted. Additionally, the applicability of the developed manometer is confirmed by a simple uniaxial pressure experiments to showcase its practical use in industrial and daily‐life purposes. Notably, the designed sensor exhibits the highest pressure sensitivities reported to date in different modes, namely, emission band centroid, FWHM and color coordinate, making supersensitive multimodal optical manometry a reality.

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Multi‐Mode Optical Manometry Based on Li₄SrCa(SiO₄)₂:Eu²⁺ Phosphors

Cited by 19 publications

References 46 publications

Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Tailoring Ultra‐Wide Visible‐NIR Luminescence by Ce³⁺/Cr³⁺/Yb³⁺‐alloying Sc‐Based Oxides for Multifunctional Optical Applications

Super‐Sensitive Multi‐Modal Optical Manometer Based on Huge Pressure‐Induced Spectral Red‐Shift and Broadening of Mn²⁺ Emission Band in Green‐Emitting Zn₂GeO₄ Phosphors

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Multi‐Mode Optical Manometry Based on Li4SrCa(SiO4)2:Eu2+ Phosphors

Cited by 19 publications

References 46 publications

Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Achieving Ultra‐Broadband Sunlight‐Like Emission in Single‐Phase Phosphors: The Interplay of Structure and Luminescence

Tailoring Ultra‐Wide Visible‐NIR Luminescence by Ce3+/Cr3+/Yb3+‐alloying Sc‐Based Oxides for Multifunctional Optical Applications

Super‐Sensitive Multi‐Modal Optical Manometer Based on Huge Pressure‐Induced Spectral Red‐Shift and Broadening of Mn2+ Emission Band in Green‐Emitting Zn2GeO4 Phosphors

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Product

Resources

About

Multi‐Mode Optical Manometry Based on Li₄SrCa(SiO₄)₂:Eu²⁺ Phosphors

Tailoring Ultra‐Wide Visible‐NIR Luminescence by Ce³⁺/Cr³⁺/Yb³⁺‐alloying Sc‐Based Oxides for Multifunctional Optical Applications

Super‐Sensitive Multi‐Modal Optical Manometer Based on Huge Pressure‐Induced Spectral Red‐Shift and Broadening of Mn²⁺ Emission Band in Green‐Emitting Zn₂GeO₄ Phosphors