Surface plasmon resonance sensor composed of microstructured optical fibers for monitoring of external and internal environments in biological and environmental sensing

To achieve simultaneous detection of analytes with different states in internal and external environments, A microstructured optical fibers (MOFs) biochemical sensor based on surface plasmon resonance (SPR) is proposed. The micro-polished dual-open-loop structure with anti-corrosive gold as the sensing layer is designed, which greatly improves the phase matching between fundamental mode and plasmonic mode to further stimulate SPR effect. Numerical simulation by the full-vector finite element method (FEM) reveals that the even mode for ypolarized state has better sensing properties due to the more eminent electric field distribution and shift of the confinement loss peak. In order to better evaluate and analyze the output characteristics of this sensor, the wavelength modulation and amplitude interrogation methods are adopted. The results manifest that the maximum wavelength sensitivity (WS) of 20,000 nm/RIU and amplitude sensitivity (AS) of 208.21 RIU-1 with resolution (R) of 10-6 order can be acquired in operable infrared region (900-2,750 nm). Furthermore, this sensor has realized a broad range of detection for gas and liquid analytes with RIs from 1.00 to 1.38. On account of its simple structure, low cost, and industrial compatibility, this sensor has large potential in environmental and biological applications such as atmospheric monitoring, sewage treatment, food safety, humoral regulation, and medical diagnosis.

Automated summary

A microstructured optical fibers (MOFs) biochemical sensor based on surface plasmon resonance (SPR) is proposed for simultaneous detection of analytes with different states in internal and external environments. The sensor utilizes a micro-polished dual-open-loop structure with anti-corrosive gold as the sensing layer to enhance the phase matching between fundamental mode and plasmonic mode for SPR effect. Numerical simulations reveal the better sensing properties of the even mode for ypolarized state. The sensor demonstrates high wavelength sensitivity and amplitude sensitivity in the operable infrared region, with the capability of detecting a wide range of gas and liquid analytes.