\begin{document}${\text{VO}}_4^{3 - }$\end{document} and the 1D23H4 transition of Pr3+, respectively. The relationship between the luminescence of the sample and the concentration of Pr3+ is studied. It is found that the optimal doping concentration of Pr3+ is 0.5%, and a higher doping concentration will cause concentration to be quenched. The reason for quenching concentration is the electric dipole-quadrupole interaction. The luminescence peak position of the temperature-dependent spectrum of YVO4:0.5%Pr3+ is consistent with that at room temperature. As the temperature increases, the total luminescence intensity gradually decreases, which is caused by thermal quenching, and the mechanism of thermal quenching is analyzed. Since the temperature-dependent behaviors of luminescence of \begin{document}${\text{VO}}_4^{3 - }$\end{document} and Pr3+ are significantly different from each other, a new fluorescence intensity ratio thermometry strategy is realized. Temperatures range is 303–353 K, and the maximum absolute sensitivity and relative sensitivity are 0.651 K–1 and 3.112×10–2 K–1 at 353 K, respectively, much higher than the traditional thermally coupled level thermometry strategy. In addition, there is no obvious overlap between the emission peaks of \begin{document}${\text{VO}}_4^{3 - }$\end{document} and Pr3+, which provides a good discrimination capability for signal detection. The above results show that this work provides a promising path for designing self-reference optical thermometry materials with excellent temperature sensitivity and signal discrimination."> Novel high-sensitivity optical thermometry based on fluorescence intensity ratio of <inline-formula><tex-math id="Z-20240425115725">\begin{document}${\text{VO}}_4^{3 - } $\end{document}</tex-math><alternatives><graphic specific-use="online" xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="9-20240012_Z-20240425115725.jpg"/><graphic specific-use="print" xmlns:xlink="http://www.w3.org/1999/xlink" xlink:href="9-20240012_Z-20240425115725.png"/></alternatives></inline-formula> to Pr<sup>3+</sup> - 必威体育下载

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    Novel high-sensitivity optical thermometry based on fluorescence intensity ratio of ${\text{VO}}_4^{3 - } $ to Pr3+

    Yan Yong-Biao, Li Shuang, Ding Shuang-Shuang, Zhang Bing-Xue, Sun Hao, Ju Quan-Hao, Yao Lu
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    • Abstract views:1083
    • PDF Downloads:55
    • Cited By:0
    Publishing process
    • Received Date:03 January 2024
    • Accepted Date:27 January 2024
    • Available Online:08 March 2024
    • Published Online:05 May 2024

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