[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.3807/COPP.2018.2.4.303

Ultraviolet Light Sensor Based on an Azobenzene-polymer-capped Optical-fiber End

Cho, Hee-Taek (Department of Photonic Engineering, Chosun University)
Seo, Gyeong-Seo (Department of Photonic Engineering, Chosun University)
Lim, Ok-Rak (Department of Photonic Engineering, Chosun University)
Shin, Woojin (Advanced Photonics Research Institute, Gwangju Institute of Science and Technology)
Jang, Hee-Jin (Department of Materials Science and Engineering, Chosun University)
Ahn, Tae-Jung (Department of Photonic Engineering, Chosun University)

Publication Information

Current Optics and Photonics / v.2, no.4, 2018 , pp. 303-307 More about this Journal

Abstract

We propose a simple ultraviolet (UV) sensor consisting of a conventional single-mode optical fiber capped with an azobenzene-moiety-containing polymer. The UV light changes the dimensions of the azobenzene polymer, as well as the refractive index of the material. Incident light with a wavelength of 1550 nm was reflected at the fiber/polymer and polymer/air interfaces, and interference of the reflected beams resulted in spectral interference that shifted the wavelength by 0.78 nm at a UV input power of $2.5mW/cm^2$ . The UV sensor's response to wavelength is nonlinear and stable. The response speed of the sensor is limited by detection noise, which can be improved by modifying the insertion loss of the UV sensor and the signal-to-noise ratio of the detection system. The proposed compact UV sensor is easy to fabricate, is not susceptible to electromagnetic interference, and only reacts to UV light.

Keywords

Ultraviolet; Optical sensor; Optical fiber sensor; Azobenzene;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	W. Y. Kim, C.-Y. Kim, H.-K. Kim, and T.-J. Ahn, "Improving the sensitivity of an ultraviolet optical sensor based on a fiber Bragg grating by coating with a photoresponsive material," Korean J. Opt. Photon. 26, 83-87 (2015). DOI
2	G.-S. Seo and T.-J. Ahn, "Protection method for diameter-downsized fiber Bragg gratings for highly sensitive ultraviolet light sensors," Curr. Opt. Photon. 2, 221-225 (2018).
3	A. Lendlein, H. Jiang, O. Jünger, and R. Langer, "Light-induced shape-memory polymers," Nature 434, 879-882 (2005). DOI
4	H.-K. Kim, X.-S. Wang, Y. Fujita, A. Sudo, H. Nishida, M. Fujii, and T. Endo, "A rapid photomechanical switching polymer blend system composed of azobenzene-carrying poly(vinylether) and poly(carbonate)," Polymer 46, 5879-5883 (2005). DOI
5	S. Tanaka, H.-K. Kim, A. Sudo, H. Nishida, and T. Endo, "Anisotropic photomechanical response of stretched blend film made of polycaprolactone-polyvinyl ether with azobenzene group as side chain," Macromol. Chem. Phys. 209, 2071-2077 (2008). DOI
6	S. O. Kasap, Optoelectronics and Photonics: Principles and Practices (Pearson, 2013).
7	A. R. Pauchard, D. Manic, A. Flanagan, P. A. Besse, and R. S. Popovic, "A method for spark rejection in ultraviolet flame detectors," IEEE Trans. Ind. Electron. 47, 168-174 (2000). DOI
8	K.-M. Shong, Y.-S. Kim, and S.-G. Kim, "Images detection and diagnosis of corona discharge on porcelain insulators at 22.9 kV D/L," in Proc. IEEE International Symposium on Diagnositics for Electric Machines (Poland, Sept. 2007), pp. 462-466.
9	M. A. Uman, The Lightning Discharge (Orlando, FL: Academic Press, 1987).
10	O. M. Nayfeh, S. Rao, A. Smith, J. Therrien, and M. H. Nayfeh, "Thin film silicon nanoparticle UV photodetector," IEEE Photon. Technol. Lett. 16, 1927-1929 (2004). DOI
11	M. K. W. Stranges, S. U. Haq, and D. G. Dunn, "Black-out test versus UV camera for corona inspection of HV motor stator endwindings," IEEE Trans. Ind. Appl. 50, 3125-3140 (2014).
12	K. T. Kim, N. I. Moon, and H.-K Kim, "A fiber-optic UV sensor based on a side-polished single mode fiber covered with azobenzene dye-doped polycarbonate," Sens. Actuators A 160, 19-21 (2010). DOI
13	S.-W. Jang, S.-J. Son, D.-E. Kim, D.-H. Kwon, S.-H. Kim, Y.-H. Lee, and S.-W. Kang, "UV-sensitive photofunctional device using evanescent field absorption between SU-8 polymer optical waveguide and photochromic dye," IEEE Photon. Technol. Lett. 18, 82-84 (2006). DOI
14	H.-K. Kim, W. Shin, and T.-J. Ahn, "UV sensor based on photomechanically functional polymer-coated FBG," IEEE Photon. Technol. Lett. 22, 1404-1406 (2010). DOI
15	D.-S. Choi, H.-K. Kim, and T.-J. Ahn, "The study of thermal effect suppression and wavelength dependence of azobenzene-coated FBG for UV sensing application," Korean J. Opt. Photon. 22, 67-71 (2011). DOI
16	R. T. Kashiwabuchi, F. R. S. Carvalho, Y. A. Khan, D. de Freitas, A. S. Foronda, F. E. Hirai, M. S. Campos, and P. J. McDonnell, "Assessing efficacy of combined riboflavin and UV-A light (365 nm) treatment of Acanthamoeba Trophozoites," Invest. Ophthalmol. Visual Sci. 52, 9333-9338 (2011). DOI
17	R. Zhou and X. Tian, "Design and simulation of UV LED light source for curing rotary printing ink," J. Control Eng. Technol. 3, 153-157 (2013).
18	R. Simpson, Lighting Control: Technology and Applications (Burlington, MA: Focal Press, 2003).
19	B. Srikanth, "Recent advancements in UV technology yield enhanced TOC reduction performance," Ultrapure Water 15, 40-46 (1998).
20	S. P. Pappas, UV Curing: Science and Technology, Vol. 2 (Technology Marketing Corporation, 1985).
21	Y. Hu and K. Liu, Inspection and Monitoring Technologies of Transmission Lines with Remote Sensing (San Diego, CA: Academic Press, 2017).