Abstract
Polymer microtips are 3D microstructures manufactured on the end face of an optical fiber by using the photopolymerization process. Such micro-optic elements made on a multi-mode optical fiber were previously tested as a transducer of refractive index sensor. These studies were an inspiration to investigate the possibility of using this type of transducer to measure the presence of volatile organic compounds in the air. The experimental results of microtips polymerized with UV and VIS were reported. It was possible to detect the presence of five different volatile compounds in the air due to the sensitivity of the transducer to the refractive indices changes. These changes were induced by the vapors condensed on the microtip surface. The measured time responses have shown that the return loss decreases rapidly as the microtip is inserted inside a glass vial filled with the tested compound. Moreover, correlations between calculated dynamic ranges and refractive indices and volumes of the volatile compounds inside the vials were negligible. Therefore, this type of sensor can be categorized as a condensed material threshold sensor. This sensor can be used in warning systems for monitoring leakages of pipelines carrying volatile chemicals.
Highlights
In recent years, optical fiber sensor technology has attracted considerable interest.This is due to its many unique properties, such as high sensitivity, fast response, compact size immunity to electromagnetic interference, and corrosion resistance [1]
Taking into consideration the results presented above, the dynamic range obtained for trimethyl phosphate (TMP) vapors is lower than for the liquid material
The polymer microtips from mixtures cured with UV and VIS light were produced, technological parameters of fabrication process were corrected, and five selected volatile compounds were tested
Summary
Optical fiber sensor technology has attracted considerable interest This is due to its many unique properties, such as high sensitivity, fast response, compact size immunity to electromagnetic interference, and corrosion resistance [1]. Most of these advantages allow this technology to be used in various research fields. Sensors based on long-period gratings [2,3,4], Bragg gratings [5,6,7], tapered fiber [8,9], and interferometers [10,11] are commonly used This technology is still evolving, new systems and configurations are being implemented. Labon-tip platforms include functional materials integrated at the optical fiber end face [13]
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