High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers

High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers

A temperature sensor with high sensitivity based on ultracompact photonics crystal fibers is proposed and analyzed by the finite-element method. The temperature-sensitive materials are injected into one cladding air hole, which shows high confinement loss and works as a defect core. As the phase-mat...

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Main Authors: Hailiang Chen, Shuguang Li, Jianshe Li, Ying Han, Yidong Wu
Format: Article
Language:English
Published: IEEE 2014-01-01
Series:IEEE Photonics Journal
Subjects:
Photonics crystal fibers
Temperature sensor
Temperature sensitive materials
Online Access:https://ieeexplore.ieee.org/document/6942146/
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spelling doaj-9a72e2092ff74695a03a3950995b46312021-03-29T17:20:06ZengIEEEIEEE Photonics Journal1943-06552014-01-01661610.1109/JPHOT.2014.23661576942146High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal FibersHailiang Chen0Shuguang Li1Jianshe Li2Ying Han3Yidong Wu4State Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, ChinaState Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, ChinaState Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, ChinaState Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, ChinaState Key Lab. of Metastable Mater. Sci. & Technol., Yanshan Univ., Qinhuangdao, ChinaA temperature sensor with high sensitivity based on ultracompact photonics crystal fibers is proposed and analyzed by the finite-element method. The temperature-sensitive materials are injected into one cladding air hole, which shows high confinement loss and works as a defect core. As the phase-matched condition is satisfied, the power in the transferring core couples to the defect core. The temperature sensitivity and figure of merit reach to 2.82 nm/°C, 0.105/°C and 1.99 nm/°C, 0.048/°C, for the y-polarized and x-polarized directions, respectively, which are one to two orders of magnitude better than other reported sensors. The performance characteristics can be further improved by optimizing the structure parameters and infilling materials.https://ieeexplore.ieee.org/document/6942146/Photonics crystal fibersTemperature sensorTemperature sensitive materials
collection DOAJ
language English
format Article
sources DOAJ
author Hailiang Chen
Shuguang Li
Jianshe Li
Ying Han
Yidong Wu
spellingShingle Hailiang Chen
Shuguang Li
Jianshe Li
Ying Han
Yidong Wu
High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
IEEE Photonics Journal
Photonics crystal fibers
Temperature sensor
Temperature sensitive materials
author_facet Hailiang Chen
Shuguang Li
Jianshe Li
Ying Han
Yidong Wu
author_sort Hailiang Chen
title High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
title_short High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
title_full High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
title_fullStr High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
title_full_unstemmed High Sensitivity of Temperature Sensor Based on Ultracompact Photonics Crystal Fibers
title_sort high sensitivity of temperature sensor based on ultracompact photonics crystal fibers
publisher IEEE
series IEEE Photonics Journal
issn 1943-0655
publishDate 2014-01-01
description A temperature sensor with high sensitivity based on ultracompact photonics crystal fibers is proposed and analyzed by the finite-element method. The temperature-sensitive materials are injected into one cladding air hole, which shows high confinement loss and works as a defect core. As the phase-matched condition is satisfied, the power in the transferring core couples to the defect core. The temperature sensitivity and figure of merit reach to 2.82 nm/°C, 0.105/°C and 1.99 nm/°C, 0.048/°C, for the y-polarized and x-polarized directions, respectively, which are one to two orders of magnitude better than other reported sensors. The performance characteristics can be further improved by optimizing the structure parameters and infilling materials.
topic Photonics crystal fibers
Temperature sensor
Temperature sensitive materials
url https://ieeexplore.ieee.org/document/6942146/
work_keys_str_mv AT hailiangchen highsensitivityoftemperaturesensorbasedonultracompactphotonicscrystalfibers
AT shuguangli highsensitivityoftemperaturesensorbasedonultracompactphotonicscrystalfibers
AT jiansheli highsensitivityoftemperaturesensorbasedonultracompactphotonicscrystalfibers
AT yinghan highsensitivityoftemperaturesensorbasedonultracompactphotonicscrystalfibers
AT yidongwu highsensitivityoftemperaturesensorbasedonultracompactphotonicscrystalfibers
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