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Laser & Optoelectronics Progress, Volume. 62, Issue 13, 1300008(2025)

Research Progress of Wearable Temperature Sensors Based on Fluorescence Thermometric Technology

Yuhang Wen1, Tianxu Hao1,2, Xuerui Mei1, Long Huang1, Tianhong He1, Li Niu3, Jun Xu1,2,4、*, and Cheng Zhang2,4、**
Author Affiliations
  • 1School of Textile Science and Engineering, Tiangong University, Tianjin 300387, China
  • 2Tianjin Key Laboratory of Photoelectric Detection Technology and System, Tiangong University, Tianjin 300387, China
  • 3Key Laboratory of Intelligent Textile and Apparel Flexible Devices in Textile Industry, Soochow University, Suzhou 215123, Jiangsu , China
  • 4School of Electronics and Information Engineering, Tiangong University, Tianjin 300387, China
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    AbstractGet PDF(in Chinese)
    Figures&Tables (7)
    Equations (0)
    References (59)
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    Figures & Tables(7)
    Principle of fluorescence and phosphorescence generation[12]

    Fig. 1. Principle of fluorescence and phosphorescence generation[12]

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    Principle of fluorescence intensity temperature measurement

    Fig. 2. Principle of fluorescence intensity temperature measurement

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    Principle of fluorescence intensity ratio temperature measurement

    Fig. 3. Principle of fluorescence intensity ratio temperature measurement

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    Principle of fluorescence lifetime temperature measurement

    Fig. 4. Principle of fluorescence lifetime temperature measurement

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    Common wearable thermometric devices[2,30,52,54-57,59]

    Fig. 5. Common wearable thermometric devices[2,30,52,54-57,59]

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    • Table 1. Comparison of fluorescence intensity ratio temperature measurement

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      Table 1. Comparison of fluorescence intensity ratio temperature measurement

      Preparation methodMatrixRare earth ionThermometric range /K(℃)Relative sensitivity /(%·K-1Absolute sensitivity /K-1Emission wavelength /nmReference
      High-temperature solid-phase reaction methodSrIn2(P2O72Tm3+, Dy3+, Eu3+298‒523(25‒250)0.3500.0079457,578,61324
      LaB3O6Bi3+Eu3+298‒548(25‒275)0.5790.008029
      CaNb2O6Bi3+Ln3+(Ln=Eu/Sm/Dy/Tb)298‒448(25‒175)3.7930.1220460,6149
      NaLaTi2O6Yb3+/Er3+253‒373(-20‒100)1.2400.0033478,653,695,80130
      Ba3Yb(PO43Tm3+/Er3+/Ho3+303‒603(30‒330)0.6504
      NaYTiO4Yb3+/Tm3+303‒823(30‒520)0.6000.0003478,653,695,80131
      K3YSi2O7Bi3+/Sm3+303‒663(30‒390)0.7050.064032
      Solvothermal methodNaYF4Yb3+/Tm3+284‒344(11‒71)1.0800.0067345,475,646,70025
      NaYF4Yb3+/Tm3+295‒495(22‒222)2.1900.1179345,361,450,475,646,70020
      β-NaYF4Yb3+/Tm3+300‒500(27‒227)0.0027475,530,650,70033
      NaYF4Yb3+/Tm3+285‒495(12‒222)0.8800.0084362,475,646,70034
      Hydrothermal methodNaYF4Yb3+/Tm3+304‒574(31‒301)1.1010.1350476,541,64626
      NaYF4Yb3+/Tm3+345‒495(72‒222)1.9500.0877646,70035

    • Table 2. Comparison of fluorescence lifetime temperature measurement

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      Table 2. Comparison of fluorescence lifetime temperature measurement

      Preparation methodMatrixRare earth ionThermometric range /K(℃)Relative sensitivity /(%·K-1Absolute sensitivity /(%·K-1Emission wavelength /nmReference

      method

      High-temperature solid-phase reaction

      		Ca2MgWO6Er3+/Yb3+303‒573(30‒300)0.11012.600531,549,66138
      Sr8MgLa(PO47Eu3+/Tb3+298‒573(25‒300)0.700544,61623
      PIN-PMN-PTPr3+300‒480(27‒207)1.25064940
      Li2TiO3Mn4+273‒373(0‒100)6.67041
      CaGdMgSbO6Mn4+/Sm3+298‒573(25‒300)1.2300.32042
      Lu2MoO6Er3+/Yb3+253‒423(-20‒150)1.7001.50043
      Ca8ZnLa(PO47Tb3+/Eu3+298‒498(25‒225)0.3400.53044
      SrGa2B2O7Bi3+/Eu3+303‒473(30‒200)0.5384.66037
      Solvothermal methodMIPr(PO34 PolyphosphatePr3+298‒363(25‒90)0.59245

      method

      Sol-gel

      		Ba2GdV3O11Ho3+/Nd3+,Er3+/Yb3+298‒573(25‒300)0.1460.47055546
      Bi2Ti2O7Yb3+/Er3+298‒538(25‒265)1.53047
      Hydrothermal methodNaYF4Yb3+/Tm3+304‒574(31‒300)1.1010.13525
      NaYF4Yb3+/Tm3+345‒495(72‒223)1.9500.08835
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    Yuhang Wen, Tianxu Hao, Xuerui Mei, Long Huang, Tianhong He, Li Niu, Jun Xu, Cheng Zhang. Research Progress of Wearable Temperature Sensors Based on Fluorescence Thermometric Technology[J]. Laser & Optoelectronics Progress, 2025, 62(13): 1300008

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    Paper Information

    Category: Reviews

    Received: Nov. 15, 2024

    Accepted: Jan. 13, 2025

    Published Online: Jun. 25, 2025

    The Author Email: Jun Xu (xujun@tiangong.edu.cn), Cheng Zhang (zhangcheng@tiangong.edu.cn)

    DOI:10.3788/LOP242263

    CSTR:32186.14.LOP242263

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology