Abstract
We demonstrate optical fiber sensors based on highly coupled multicore fibers operating with the optical Vernier effect. The sensors are constructed using a simple device incorporating single-mode fibers (SMFs) and a segment of a multicore fiber. In particular, we evaluated the performance of a sensor based on a seven-core fiber (SCF) spliced at both ends to conventional SMFs, yielding a versatile arrangement for realizing Vernier-based fiber sensors. The SMF–SCF–SMF device can be fabricated using standard splicing procedures and serve as a “building block” for both, reflection and transmission sensing configurations. As demonstrated with our experimental results, the Vernier arrangements can yield a ten-fold increase in sensitivity for temperature measurements compared to a conventional single SMF–SCF–SMF device, thereby confirming the enhanced sensitivity that can be attained with this optical effect. Furthermore, through theoretical analysis, we obtain the relevant parameters that must be optimized in order to achieve an optimal sensitivity for a specific application. Our findings thus provide the necessary guidelines for constructing Vernier-based sensors with all-fiber devices based on highly coupled multicore optical fibers, which constitutes an ideal framework to develop highly sensitive fiber sensors for different applications.
Highlights
We demonstrate optical fiber sensors based on highly coupled multicore fibers operating with the optical Vernier effect
We have demonstrated that optical fiber sensors based on this effect can be realized by means of a simple device based on single-mode fibers (SMFs) and a segment of a multicore fiber
We evaluated the performance of a sensor based on an seven-core fiber (SCF) spliced at both ends to conventional SMFs, yielding a versatile device for realizing Vernier-based fiber sensors
Summary
We demonstrate optical fiber sensors based on highly coupled multicore fibers operating with the optical Vernier effect. Thanks to the inherent advantages of fiber optics, the Vernier effect has been successfully used in temperature6–29, pressure[30,31,32,33,34,35], refractive index36–44, strain45–52, curvature53,54, displacement[55], and humidity[56] FOS Mature technologies such as focused ion bean and femtosecond laser micromachining[35,48], photonic crystal fibers[7,36], and fiber tapering[4,43,46] have been effectively used in the construction of highly-sensitive Vernier devices, demonstrating the versatility of Vernier-based sensor schemes. As shown our proposal results in a simple method to fabricate highly sensitive fiber sensors without the need for sophisticated and/or expensive fabrication approaches
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