Litcius/Paper detail

Distributed refractive index sensing based on bending-induced multimodal interference and Rayleigh backscattering spectrum

Pengbai Xu, Xinfeng Yu, Zeji Chen, Liwen Sheng, Jiaqing Liu, Shuai Zhou, Kunhua Wen, Ou Xu, Xinyong Dong, Jun Yang, Yuwen Qin

2021Optics Express26 citationsDOIOpen Access PDF

Abstract

A distributed refractive index (RI) sensor based on high-performance optical frequency domain reflectometry was developed by bending a piece of standard single-mode fiber to excite sets of higher-order modes that penetrate the surrounding medium. External variations in RI modifies the profiles of the sets of excited higher-order modes, which are then partially coupled back into the fiber core and interfere with the fundamental mode. Accordingly, the fundamental mode carries the outer varied RI information, and RI sensing can be achieved by monitoring the wavelength shift of the local Rayleigh backscattered spectra. In the experiment, an RI sensitivity of 39.08 nm/RIU was achieved by bending a single-mode fiber to a radius of 4 mm. Additionally, the proposed sensor maintains its buffer coating intact, which boosts its practicability and application adaptability.

Topics & Concepts

OpticsReflectometryBend radiusRefractive indexRayleigh scatteringMaterials scienceFiber optic sensorOptical fiberBendingSingle-mode optical fiberInterference (communication)WavelengthGraded-index fiberPhysicsTime domainChannel (broadcasting)TelecommunicationsComputer scienceComposite materialComputer visionAdvanced Fiber Optic SensorsPhotonic and Optical DevicesSemiconductor Lasers and Optical Devices
Distributed refractive index sensing based on bending-induced multimodal interference and Rayleigh backscattering spectrum | Litcius