Ultrasensitive temperature sensor based on cascading a polarization mode interferometer with a Fabry-Perot interferometer

•An ultrasensitive temperature sensor based on vernier effect is proposed.•The temperature-insensitive FPI is manufactured using HCPCF and is an ideal reference interferometer.•The sensing PMI is based on the UFPMF with a high birefringence coefficient, which reduces the length of the sensing fiber....

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Bibliographic Details
Published in:Optics and laser technology 2024-01, Vol.168, p.109910, Article 109910
Main Authors: Zuo, Cheng, Wu, Kaiyang, Shi, Jinhui, Guang, Dong, Wu, Xuqiang, Yu, Benli
Format: Article
Language:English
Subjects:
Fabry-Perot interferometer
Polarization mode interferometer
Temperature sensor
Ultra-fine polarization-maintaining fiber
Vernier effect
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Summary:•An ultrasensitive temperature sensor based on vernier effect is proposed.•The temperature-insensitive FPI is manufactured using HCPCF and is an ideal reference interferometer.•The sensing PMI is based on the UFPMF with a high birefringence coefficient, which reduces the length of the sensing fiber.•The temperature sensitivity reaches as high as 54.589 nm/℃ with the magnification factor of 47.84.•The sensitivity amplification factor can be easily adjusted by adjusting the length of the UFPMF in the sensing PMI. An ultrasensitive temperature sensor based on cascading a polarization mode interferometer (PMI) with a Fabry-Perot interferometer (FPI) is proposed and demonstrated. The sensing interferometer PMI is fabricated by splicing high-birefringence ultra-fine polarization-maintaining fiber (UFPMF) with a polarizer for temperature sensing. The FPI, made by splicing a section of hollow core photonic crystal fiber (HCPCF) between two single mode fibers (SMFs), is temperature-insensitive and is used as a reference interferometer. The free spectral ranges (FSRs) of PMI and FPI can be made close to each other by adjusting the length of the UFPMF, thus producing a vernier effect and achieving sensitivity enhancement. Experimental results show that the temperature sensitivity of the cascaded sensor is enhanced from −1.134 nm/°C for sensing PMI to 54.589 nm/°C, and its detection limit (DL) is degraded from 3.98 × 10−3 °C for sensing PMI to 5.13 × 10−3 °C, so that the appropriate sensor should be selected depending on the detection requirements in practical applications. The proposed sensor has high sensitivity, simple structure, easy manufacture, and low cost, and is suitable for application fields requiring high-sensitivity temperature measurement.
ISSN:0030-3992
1879-2545
DOI:10.1016/j.optlastec.2023.109910