Bending hollow-core negative-curvature fiber for refractive index sensing based on surface plasmon resonance effect

Abstract

We numerically investigated a novel refractive index (RI) sensor based on a liquid-filled and Au-coated hollow-core negative-curvature fiber (HC-NCF). In the design, the cladding area of the HC-NCF was composed of only one ring of six silica tubes, all the air holes in the fiber were filled with analytic liquids. The fiber bent in either the x or y-axis direction and Au-coated inside the single cladding tube in the corresponding bending direction. The influences of Au-coated HC-NCF structure parameters on the propagation characteristics under different bending directions were investigated using the finite element method (FEM). Moreover, the sensing performances in the RI range of 1.30–1.35 were evaluated through analyzing the position of the confinement loss peak. The simulation results showed that the HC-NCF RI sensor in the y-axis bending direction showed higher sensitivity, and the maximum sensitivity was 6.974 µm/RIU. The sensor shows high sensitivity and provides an effective method for measuring the RI of liquids.