Modelling and simulation of surface plasmonic resonance in photonic crystal fiber / Rifat Ahmmed Aoni
Surface Plasmon Resonance (SPR) refers to the coupling between the electromagnetic wave and the surface plasmonic wave (SPW) on the surface between a metal and a dielectric medium. Since last decade, the SPR behavior is widely applied in prism based SPR sensor, which is bulky and not suitable for...
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| Format: | Thesis |
| Published: |
2015
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| Subjects: | |
| Online Access: | http://studentsrepo.um.edu.my/8794/4/KGA130045_MODELLING_AND_SIMULATION_OF_SURFACE_PLASMONIC_RESONANCE_IN_PHOTONIC_CRYSTAL_FIBER.pdf http://studentsrepo.um.edu.my/8794/ |
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| Institution: | Universiti Malaya |
| Summary: | Surface Plasmon Resonance (SPR) refers to the coupling between the electromagnetic
wave and the surface plasmonic wave (SPW) on the surface between a metal and a
dielectric medium. Since last decade, the SPR behavior is widely applied in prism based
SPR sensor, which is bulky and not suitable for remote monitoring applications. To
overcome this limitation, photonic crystal fiber (PCF) based SPR sensor had attained
great attention with the advantages of easily launching light through the fiber, small-size
and design flexibility. To establish the SPR phenomena, metal deposition is necessary.
Nowadays, in most of the PCF-SPR sensors, metal is selectively deposited inside the airholes
with numerous selective metallic and liquid channels, which made fabrication of
such sensors impractical or very challenging.
In this dissertation, four different PCF-SPR sensors are introduced with relatively high
or comparable sensing performance. The proposed sensors are numerically investigated
using the commercial Multiphysics COMSOL software. First study presents the PCFSPR
sensor with only one graphene-silver deposited channel and two high refractive
index (RI) liquid channels. It shows the amplitude sensitivity as high as 418 RIU-1 and
the wavelength interrogation sensitivity of 3000 nm/RIU. In the second study, focusing
on the metal deposition problem, a flat structure PCF-SPR sensor is developed where, the
metal layer is deposited outside the fiber structure and the sensor will perform the external
sensing scheme to detect the analytes. The proposed flat SPR sensor enhances the
evanescent field resulting the amplitude sensitivity as high as 820 RIU-1 and the
remarkable wavelength interrogation sensitivity of 23,000 nm/RIU. In the third study, a
practically simple PCF SPR sensor is proposed. The metallic layer and sensing layer are
placed outside the fiber structure which makes the sensor configuration simple and the
analyte detection process easier. The proposed sensor shows the amplitude and
wavelength interrogation sensitivity of 320 RIU-1 and 4000 nm/RIU, respectively. In the
last work, copper is utilized in PCF SPR sensor for the first time due to its long-term
stable sensing performance; and graphene is used to prevent copper oxidation and
enhance the sensor performance. Similar to the third design, here the metallic layer and
sensing layer are positioned outside the fiber structure resulting easy detection
mechanism. It shows the wavelength interrogation sensitivity of 2000 nm/RIU with the
sensor resolution of 5×10-5 RIU. Due to the promising sensitivity, the proposed sensors
would be potential candidates for chemical, bio-chemical, organic chemical and organic
molecule analytes detection with realizable structure. |
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