Sensitivity-optimized strongly coupled multicore fiber-based thermometer

[EN] In this paper, we report on a multicore fiber-based (MCF) temperature sensor that operates in a wide thermal range and that is robustly packaged to withstand harsh environments. To develop the sensor, the fundamentals concerning the effect of temperature on such fibers have been analyzed in det...

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Bibliographic Details
Authors: Amorebieta Herrero, Josu, Ortega Gómez, Ángel, Fernández Bello, Rubén, Antonio López, José Enrique, Schülzgen, Axel, Zubia Zaballa, Joseba Andoni, Amezcua Correa, Rodrigo, Durana Apaolaza, Gaizka, Villatoro Bernardo, Agustín Joel
Format: article
Publication Date:2022
Country:España
Institution:Universidad del País Vasco
Repository:Addi. Archivo Digital para la Docencia y la Investigación
OAI Identifier:oai:addi.ehu.eus:10810/55118
Online Access:http://hdl.handle.net/10810/55118
Access Level:Open access
Keyword:thin-film thermocouple
high-temperature
optical fiber
sensor
interferometer
coefficient
gratings
silicon
design
Description
Summary:[EN] In this paper, we report on a multicore fiber-based (MCF) temperature sensor that operates in a wide thermal range and that is robustly packaged to withstand harsh environments. To develop the sensor, the fundamentals concerning the effect of temperature on such fibers have been analyzed in detail to predict the most temperature sensitive MCF geometry. Thanks to it, the device, which operates in reflection mode and consists of a short segment of strongly coupled MCF fusion spliced to a standard single mode fiber, shows higher sensitivity than other devices with identical configuration. Regarding its packaging, it consists of an inner ceramic and two outer metallic tubes to provide rigidity and protection against impacts or dirt. The device was calibrated for a thermal range from -25 degrees C to 900 degrees C and a K-type thermocouple was used as reference. Our results suggest that the manufactured optical thermometer is as accurate as the electronic one, reaching a sensitivity up to 29.426 pm/degrees C with the advantage of being passive, compact and easy to fabricate and interrogate. Therefore, we believe this device is appealing for industrial applications that require highly sensitive temperature sensing in very demanding environments, and that the analysis included in this work could be analogously applied to develop sensitivity-optimized devices for other parameters of interest.