Conference Paper
Year 2023,
Volume: 22, 127 - 134, 01.09.2023
Abstract
References
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- Krohn, D.A., MacDougall., & Mendez, A. (2014). Fiber optic sensors: Fundamentals and applications (4th ed.). USA: SPIE.
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- Ribeiro, L. A., Rosolem, J. B., Dini, D. C., Floridia, C., Bezerra, E. W., Cezar, F. A., ... & Durelli, A. S. (2012, May). Optical fiber sensor for pressure measurement based on elastomeric membrane and macrobending loss. In Optical Sensing and Detection II (Vol. 8439, pp. 110-118). SPIE.
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- Tan, A. J.Y., Ng, S.M., Stoddart, P.R., & Chua, H.S. (2021). Trends and application of u-shaped fiber optic sensors: A review. IEEE Sensors Journal, 21(1), 120-131.
- Tiwari, S.K., Bhat, S., & Mahato, K.K. (2020). Design and fabrication of low-cost microfluidics channel for biomedical application. Scientific Reports.10, 9215
- Tregubov, A.V.,Svetukhin,V.V., Novikov, S.G., Berintsev, A.V., & Prikhodko, V.V. (2016). A novel fiber optic distributed temperature and strain sensor for building application. Results in Physics, 6, 131-132.
- Ward, K., & Fan, H. Z. (2015). Mixing in microfluidic devices and enhancement methods. Journal of Micromechanics and Microengineering, 25(9).
A Study of U-Shaped Optical Fiber Sensor for Sensing Different Concentrations of Glucose and Ion liquid (HgCl2) and a Fabrication of Microfluidics System
Abstract
In this study, we demonstrate the sensitivity of U-shaped with the different resolutions of Glucose and Mercury Chloride (HgCl2). We also indicate the process of fabricating a Microfluidics system by using CO2 laser with Poly Methyl Methacrylate (PMMA) as material. According to the experiments, the sensor can be used to evaluate the concentrations of Glucose and HgCl2. While the shift of resonance wavelength raised with the increase of Glucose Concentration from 5% to 50% with R2=0.95, there is a fluctuation in the shift of resonance wavelength with HgCl2 Concentration from 5 ppm to 50 ppm. Especially with transmission loss, Glucose, and HgCl2 witness the same phenomenon when the transmission loss goes up simultaneously with the increase of concentration, with R2=0.86 for Glucose and R2=0.78 for HgCl2. Finally, we manufacture successfully the Microfluidics system with the dimensions including depth: 0.3 mm and width: 0.2 mm. By mixing Glucose 0% and 50%, it leads to the conclusion that the Microfluidics system works appropriately.
References
- Castillo Leon, J., &.Svendsen, W.E. (2015). Lab-on-a-chip devices and micro-total analysis system. Cham: Springer.
- Krohn, D.A., MacDougall., & Mendez, A. (2014). Fiber optic sensors: Fundamentals and applications (4th ed.). USA: SPIE.
- Miller, S.E., Chynoweth, A.G., & Kami, I. P. (1979). Optical fiber telecommunication (1 st ed). Frederick, USA: Academic Press.
- Park, S.J., Ta, C.L., Baek, H.G., Kim, Y.H., Eom, J.B., Lee, Y.T., & Lee, B.H. (2013). Optical fiber sensor for refractive index measurement based on localized surface plasmon resonance. Conference on Lasers and Electro-Optics Pacific Rim. Kyoto Japan
- Renner, H. (1992). Bending losses of coated single-mode fibers: A simple approach. Journal of Lightwave Technology, 10(5), 544-551.
- Ribeiro, L. A., Rosolem, J. B., Dini, D. C., Floridia, C., Bezerra, E. W., Cezar, F. A., ... & Durelli, A. S. (2012, May). Optical fiber sensor for pressure measurement based on elastomeric membrane and macrobending loss. In Optical Sensing and Detection II (Vol. 8439, pp. 110-118). SPIE.
- Roriz, P. Silva, S., Frazao, O., & Novais, S. (2020). Optical fiber temperature sensor and their biomedical application. Sensors,20(7),2113.
- Tan, A. J.Y., Ng, S.M., Stoddart, P.R., & Chua, H.S. (2021). Trends and application of u-shaped fiber optic sensors: A review. IEEE Sensors Journal, 21(1), 120-131.
- Tiwari, S.K., Bhat, S., & Mahato, K.K. (2020). Design and fabrication of low-cost microfluidics channel for biomedical application. Scientific Reports.10, 9215
- Tregubov, A.V.,Svetukhin,V.V., Novikov, S.G., Berintsev, A.V., & Prikhodko, V.V. (2016). A novel fiber optic distributed temperature and strain sensor for building application. Results in Physics, 6, 131-132.
- Ward, K., & Fan, H. Z. (2015). Mixing in microfluidic devices and enhancement methods. Journal of Micromechanics and Microengineering, 25(9).
There are 11 citations in total.
Details
| Primary Language | English |
|---|---|
| Subjects | Chemical Engineering Design |
| Journal Section | Articles |
| Authors | |
| Early Pub Date | August 6, 2023 |
| Publication Date | September 1, 2023 |
| Published in Issue | Year 2023Volume: 22 |
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