Sensitivity improvement of photonic crystal refractive index sensor using porous silicon nano rods
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Date
2023
Journal Title
Journal ISSN
Volume Title
Publisher
Elsevier Ltd
Abstract
This work proposes a photonic crystal refractive-index sensor for detecting volatile organic compounds (VOC). Two sensor designs are analyzed with Y-splitter photonic crystal waveguide using the finite-difference time-domain (FDTD) method. Also, simultaneous monitoring of two different analytes is possible across the arms of the Y-splitter. The porous silicon (p-Si) rods with a porosity of 25% are used to create a variable refractive index sensing region, which induces a relative shift in the resonant wavelength of the traveling mode. The response at the output ports is monitored in terms of transmittance power versus wavelength plot. The numerical simulations confirm ∼195.83 nm/RIU sensitivity and ∼24.482 RIU−1 figure-of-merit in the presence of hazardous alcohols. © 2023 Elsevier Ltd
Description
Keywords
Energy gap, Finite difference time domain method, Nanorods, Photonic band gap, Refractive index, Volatile organic compounds, Analytes, Crystal waveguides, Nano-rods, Photonic bandgap (PBG), Refractive index sensor, Sensitivity improvements, Sensor designs, Silicon rods, Simultaneous monitoring, Y splitter, Porous silicon
Citation
Materials Science in Semiconductor Processing, 2023, 165, , pp. -