A novel Eu<sup>2+</sup>/Tb<sup>3+</sup> co‐doped phosphor with pyroxene structure applied for cryogenic thermometric sensing

Su, Ke; Guo, Qingfeng; Shuai, Pengfei; Liu, Ning; Mei, Lefu; Liao, Libing

doi:10.1111/jace.18275

Cited by 10 publications

(11 citation statements)

References 47 publications

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“…Due to the unique dual emission, Ba 0.99 Ga 2 O 4 :0.01Bi creates favorable conditions for temperature sensing. Figure 5A shows the PL emission intensities of the Bi1 (500 nm) and Bi2 (610 nm) groups with the temperature increase from 323 to 473 K. To evaluate the temperature‐sensing performance of Ba 0.99 Ga 2 O 4 :0.01Bi phosphor, the FIR value can be calculated by the following equation 38 :

\begin{equation}FIR\; = \frac{{{I_{500{\rm{\;nm}}}}}}{{{I_{610{\rm{\;nm}}}}}}\; = \;A{\rm{exp}}\left[ {\frac{{ - {{\Delta}}E}}{{kT}}} \right] + B\end{equation}

where I 500 and I 610 represent the PL intensity at 500 and 610 nm, T represents the temperature, k is Boltzmann's constant, Δ E represents the energy required to transition among different energy levels, A and B are the constant. The calculated FIR values can be fitted by the red curve in Figure S14.…”

Section: Resultsmentioning

confidence: 99%

“…We further calculated the absolute temperature sensitivity ( S a ) as well as the relative temperature sensitivity ( S r ) to accurately evaluate the temperature sensitivity of the material by using the following equations 38 :

\begin{equation}{\rm{\;}}{S_a} = \;FIR\frac{{ - {{\Delta}}E}}{{k{T^2}}}\end{equation}

\begin{equation}{\rm{\;}}{S_r} = \frac{{ - {{\Delta}}E}}{{k{T^2}}}\;\end{equation}

…”

Section: Resultsmentioning

confidence: 99%

“…Due to the unique dual emission, Ba 0.99 Ga 2 O 4 :0.01Bi creates favorable conditions for temperature sensing. Figure 5A shows the PL emission intensities of the Bi1 (500 nm) and Bi2 (610 nm) groups with the temperature increase from 323 to 473 K. To evaluate the temperature-sensing performance of Ba 0.99 Ga 2 O 4 :0.01Bi phosphor, the FIR value can be calculated by the following equation 38 :…”

Section: Applications In Temperature Sensing and Anti-counterfeitingmentioning

confidence: 99%

“…We further calculated the absolute temperature sensitivity (S a ) as well as the relative temperature sensitivity (S r ) to accurately evaluate the temperature sensitivity of the material by using the following equations 38 :…”

Section: Applications In Temperature Sensing and Anti-counterfeitingmentioning

confidence: 99%

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A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

et al. 2022

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The charge carrier capture phosphors for multifunctional integrated applications are gaining popularity these days. The realization of multiple optical properties often requires complex modulation processes, such as multiple ions doping and matrix substitution. Herein, we designed a single-doped Ba 0.99 Ga 2 O 4 :0.01Bi phosphor with two emission peaks of 500 and 610 nm, both of which have different responses when changing temperatures (298-473 K). Theoretical calculations combined with experimental studies imply that the dopant Bi 3+ ions occupy regular Ba sites and the vacancy-surrounded Ba sites, which act as luminescence centers. Meanwhile, doping-induced 𝑉 ′′′ Ga and Bi ⋅ Ba defects can operate as traps to store carriers that could be released and migrate toward specific luminescent centers under thermal disturbance. This phosphor shows excellent absolute sensitivity toward optical temperature sensing (S a = 3.4% K −1 ). We also offered a quadruple anti-counterfeiting application show based on the multicolor emission behavior of Ba 0.99 Ga 2 O 4 :0.01Bi with photostimulated luminescence at room temperature, different photoluminescent colors at room and high temperatures, as well as afterglow colors from yellow to green. This work stimulates the exploration of modulating the luminescence centers and trap levels to construct multifunctional fluorescent materials.

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\begin{equation}FIR\; = \frac{{{I_{500{\rm{\;nm}}}}}}{{{I_{610{\rm{\;nm}}}}}}\; = \;A{\rm{exp}}\left[ {\frac{{ - {{\Delta}}E}}{{kT}}} \right] + B\end{equation}

Section: Resultsmentioning

confidence: 99%

\begin{equation}{\rm{\;}}{S_a} = \;FIR\frac{{ - {{\Delta}}E}}{{k{T^2}}}\end{equation}

\begin{equation}{\rm{\;}}{S_r} = \frac{{ - {{\Delta}}E}}{{k{T^2}}}\;\end{equation}

…”

Section: Resultsmentioning

confidence: 99%

“…Due to the unique dual emission, Ba 0.99 Ga 2 O 4 :0.01Bi creates favorable conditions for temperature sensing. Figure 5A shows the PL emission intensities of the Bi1 (500 nm) and Bi2 (610 nm) groups with the temperature increase from 323 to 473 K. To evaluate the temperature-sensing performance of Ba 0.99 Ga 2 O 4 :0.01Bi phosphor, the FIR value can be calculated by the following equation 38 :…”

Section: Applications In Temperature Sensing and Anti-counterfeitingmentioning

confidence: 99%

“…We further calculated the absolute temperature sensitivity (S a ) as well as the relative temperature sensitivity (S r ) to accurately evaluate the temperature sensitivity of the material by using the following equations 38 :…”

Section: Applications In Temperature Sensing and Anti-counterfeitingmentioning

confidence: 99%

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A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

et al. 2022

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“…[ 14 ] Su K described CaScAlSiO 6 :Tb 3+ /Sm 3+ ceramics with excellent cryogenic optical thermometry performance [ 15 ] and the Eu 2+ /Tb 3+ co‐doped phosphor has potential applications in cryogenic thermometric sensing. [ 16 ] Furthermore, Liu H developed a new strategy for realizing ratiometric optical thermometry via efficient Tb 3+ –Mn 2+ energy transfer in the phosphor Ca 9 Tb(PO 4 ) 5 (SiO 4 )F 2 . [ 17 ] Back in 2018, Kai Cheng et al .…”

Section: Introductionmentioning

confidence: 99%

Synthesis and photoluminescence properties of a novel green‐emitting LiYGeO₄:Tb³⁺ long afterglow phosphor

Song

Gong

et al. 2022

Luminescence

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A new green luminescent phosphor, Li(Y 1-x Tb x )GeO 4 , was prepared using a hightemperature solid-phase method. The X-ray diffraction (XRD) measured spectrum agreed well with the standard card JCPDS No. 02-3479, indicating that it is a quaternary compound belonging to the space group of Pnma( 62) with an orthogonal crystalline phase; the excitation and emission spectra measured using the phosphor spectrometer showed that it can be effectively excited by near-ultraviolet light at 378 nm and blue light at 482 nm, and produced excellent strong emission of green light at 550 nm. The afterglow test results show that the sample had a good long afterglow effect at lower doping concentrations; the thermal stability test results showed that its thermal burst activation energy ΔE ≈ 0.37 eV had its excellent thermal stability. The rare earth Tb 3+ -doped green phosphor, LiYGeO 4 :Tb 3+ , has potential applications in household lighting, medical therapy, and optical storage.

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

Mei

Guo

et al. 2023

Adv Funct Materials

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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 massive redshift of 5.19 nm GPa−1 of EuCa, which is 14× better than commercially available ruby sensors. In order to improve the pressure response range and the accuracy of pressure measurement, for the first time, a new approach in the pressure readout method in which single Eu2+ ions doping based on fluorescence intensity ratio (FIR) pressure measurement is realized in designed materials. Meanwhile, the measured full width at half maximum (FWHM) as an indicator of pressure sensor performance also reveals that the sensing performance is d FWHM/d P ≈ 1.23 nm GPa−1 and d FWHM/d P ≈ 0.84 nm GPa−1 for EuSr and EuCa positions, respectively. Additionally, the structural stability of the phosphor is confirmed by in situ Raman spectrum. The above results indicate that the Li4SrCa(SiO4)2:0.04Eu2+ phosphor is a good candidate for multi‐mode optical pressure sensors.

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A novel Eu²⁺/Tb³⁺ co‐doped phosphor with pyroxene structure applied for cryogenic thermometric sensing

Cited by 10 publications

References 47 publications

A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

Synthesis and photoluminescence properties of a novel green‐emitting LiYGeO₄:Tb³⁺ long afterglow phosphor

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

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A novel Eu2+/Tb3+ co‐doped phosphor with pyroxene structure applied for cryogenic thermometric sensing

Cited by 10 publications

References 47 publications

A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

A multicolor‐emitted phosphor for temperature sensing and multimode dynamic anti‐counterfeiting

Synthesis and photoluminescence properties of a novel green‐emitting LiYGeO4:Tb3+ long afterglow phosphor

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

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Product

Resources

About

A novel Eu²⁺/Tb³⁺ co‐doped phosphor with pyroxene structure applied for cryogenic thermometric sensing

Synthesis and photoluminescence properties of a novel green‐emitting LiYGeO₄:Tb³⁺ long afterglow phosphor

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