Swelling-Based Chemical Sensing With Unmodified Optical Fibers

Alin Jderu; Dorel Dorobantu; Dominik Ziegler; Marius Enachescu

doi:10.1007/s13320-021-0637-2

Photonic Sensors ›› 2021, Vol. 12 ›› Issue (2) : 99 -104. DOI: 10.1007/s13320-021-0637-2

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Swelling-Based Chemical Sensing With Unmodified Optical Fibers

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Abstract

We use distributed fiber optic strain sensing to examine swelling of the fiber’s polymer coating. The distributed sensing technique that uses unmodified low-cost telecom fibers opens a new dimension of applications that include leak detection, monitoring of water quality, and waste systems. On a short-range length scale, the technology enables “lab-on-a-fiber” applications for food processing, medicine, and biosensing for instance. The chemical sensing is realized with unmodified low-cost telecom optical fibers, namely, by using swelling in the coating material of the fiber to detect specific chemicals. Although generic and able to work in various areas such as environmental monitoring, food analysis, agriculture or security, the proposed chemical sensors can be targeted for water quality monitoring, or medical diagnostics where they present the most groundbreaking nature. Moreover, the technique is without restrictions applicable to longer range installations.

Keywords

Chemical sensing / distributed fiber optic strain / short range sensing / Brillouin optical time domain analysis

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Alin Jderu, Dorel Dorobantu, Dominik Ziegler, Marius Enachescu. Swelling-Based Chemical Sensing With Unmodified Optical Fibers. Photonic Sensors, 2021, 12(2): 99-104 DOI:10.1007/s13320-021-0637-2

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References

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[1]	Lee B. Review of the present status of optical fiber sensors. Optical Fiber Technology, 2003, 9(2): 57-79.

[2]	Bao X, Chen L. Recent progress in distributed fiber optic sensors. Sensors, 2012, 12(7): 8601-8639.

[3]	Jderu A, Enachescu M, Ziegler D. Mass flow monitoring by distributed fiber optical temperature sensing. Sensors, 2019, 19(19): 4151.

[4]	Rivero P, Goicoechea J, Arregui F. Optical fiber sensors based on polymeric sensitive coatings. Polymers, 2018, 10(3): 280.

[5]	Yin M, Gu B, An Q F, Yang C, Guan Y L, Yong K T. Recent development of fiber-optic chemical sensors and biosensors mechanisms, materials, micro/nano-fabrications and applications. Coordination Chemistry Reviews, 2018, 376, 348-392.

[6]	Horiguchi T, Tateda M. Opticalfiber-attenuation investigation using stimulated Brillouin scattering between a pulse and a continuous wave. Optics Letters, 1989, 14(8): 408-410.

[7]	Kurashima T, Horiguchi T, Tateda M. Distributed-temperature sensing using stimulated Brillouin scattering in optical silica fibers. Optics Letters, 1990, 15(18): 1038-1040.

[8]	Bao X, Dhliwayo J, Heron N, Webb D J, Jackson D A. Experimental and theoretical studies on a distributed temperature sensor based on Brillouin scattering. Journal of Lightwave Technology, 1995, 13(7): 1340-1348.

[9]	S. T. Kreger, D. K. Gifford, M. E. Froggatt, B. J. Soller, and M. S. Wolfe, “High resolution distributed strain or temperature measurements in single- and multi-mode fiber using swept-wavelength interferometry,” Optical Fiber Sensors 2006, Cancun, Mexico, October 23–27, 2006.

[10]	Gifford D K, Kreger S T, Sang A K, Froggatt M E, Duncan R G, Wolfe M S, . Swept-wavelength interferometric interrogation of fiber Rayleigh scatter for distributed sensing application. Fiber Optic Sensors and Applications V. SPIE, 2007, 6770, 6770F.