Design of a hybrid fiber-capillary optofluidic coupler with multiple dispersion turning points for ultra-sensitive refractive index sensing

•Multiple dispersion turning point was discovered: Our study indicates that when the diameter of the hybrid fiber-capillary oftofluidic coupler sensor is optimized, three dispersion turning points can be obtained for enhanced sensing.•Ultra-highly sensitivity: An ultra-high sensitivity of −110015.1 ...

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Bibliographic Details
Published in:Optical fiber technology 2025-03, Vol.90, p.104127, Article 104127
Main Authors: Fan, Jianhua, Zhang, Taihao, Wang, Zhe, Qian, Zhihui, Zhou, Wenchao, Li, Kaiwei, Ren, Lei
Format: Article
Language:English
Subjects:
Optical fiber coupler
Optical fiber sensor
Optofluidic sensor
Refractive index sensor
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Summary:•Multiple dispersion turning point was discovered: Our study indicates that when the diameter of the hybrid fiber-capillary oftofluidic coupler sensor is optimized, three dispersion turning points can be obtained for enhanced sensing.•Ultra-highly sensitivity: An ultra-high sensitivity of −110015.1 nm/RIU was finally achieved, showing potential for use in lab-in-a-fiber applications and tunable fiber optic devices.•Good manufacturing error tolerance: The plateau intervals between the second and third DTPs demonstrate a relatively stable high sensitivity value. This range allows for the simultaneous achievement of high sensitivity and good manufacturing error tolerance. Optofluidics, which combines optics and microfluidics, is emerging as a powerful technique for biochemical sensing. Here, we propose and demonstrate a hybrid fiber-capillary optofluidic coupler sensor with three dispersion turning points for ultrasensitive refractive index (RI) sensing. The device comprises a tapered microfiber and a tapered microcapillary fused in parallel. The microfiber acts as a light guide, while the microcapillary acts as both a light guide and a fluidic channel for the liquid sample. We systematically investigated the effective RI, the power occupancy ratio within the microchannel, the RI sensitivity, and the spectral responses to internal RIs of optofluidic couplers with different parameters. An ultra-high sensitivity of −110015.1 nm/RIU was finally achieved. The proposed sensor shows potential for use in lab-in-a-fiber applications and tunable fiber optic devices.
ISSN:1068-5200
DOI:10.1016/j.yofte.2025.104127