Startseite Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
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Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor

  • Iraj S. Amiri , Siti Anis Khairani Alwi , Sofiah Atirah Raya , Nur Aina’a Mardhiah Zainuddin , Nurul Syazwani Rohizat , M.S. Mani Rajan und Rozalina Zakaria ORCID logo EMAIL logo
Veröffentlicht/Copyright: 15. Mai 2019
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Journal of Optical Communications
Aus der Zeitschrift Journal of Optical Communications Band 44 Heft 1

Abstract

This research focuses on the side-polished Single-Mode Optical Fibers (SMOF) as refractive index (RI) sensor utilizing properties of Surface Plasmon Resonance. The SMOF with cladding stripped off shows a D-shaped optical fiber with high sensitivity functionalization. Here we show silver protected by graphene oxide (GO) as viable candidates. A few layers of GO on top of silver thin layer were applied as a material to overcome silver coating degradation process. This silver/GO sensor was characterized using various RIs of analyte likely deionized water and alcohol solutions. Sensor with GO has shown fast response and high sensitivity in respect of RI, where sensitivity increases in range from 1.30 to 1.34 RIU (refractive index unit). This device shows highest sensitivity of up to 833.33 nm/ RIU. The polishing process using SMOF stops at few microns above the core of the fiber with the drop of output power fixed to be 1 dB as an indication to standardize the amount of cladding been removed. The thickness of 30 nm Ag was deposited using electron beam evaporation method on D-shaped optical fiber with subsequent protected layer of GO in solutions form. The use of COMSOL Multiphysics has also been carried out to observe numerical findings. The response of the GO has shown a sensitivity improvement which proves new promising approaches for the newly developed sensors.

Keywords: surface plasmon resonance; graphene oxide; refractive index sensor; optical fiber

Acknowledgments

Dr Rozalina Zakaria would like to acknowledge grant support from FP034-2017A.

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Received: 2019-04-08
Accepted: 2019-04-30
Published Online: 2019-05-15
Published in Print: 2023-01-27

© 2019 Walter de Gruyter GmbH, Berlin/Boston

Artikel in diesem Heft

  1. Frontmatter
  2. Amplifiers
  3. Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
  4. Nonlinear Effects with Semiconductor Optical Amplifiers
  5. Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
  6. Devices
  7. An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
  8. Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
  9. Lasers
  10. Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
  11. Measurements
  12. Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
  13. Networks
  14. High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
  15. RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
  16. An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
  17. Systems
  18. Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
  19. Free Space Optical Communication System under Different Weather Conditions
  20. Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
  21. Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
  22. Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
  23. Theory
  24. Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
  25. Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
https://doi.org/10.1515/joc-2019-0094
Schlagwörter für diesen Artikel
surface plasmon resonance; graphene oxide; refractive index sensor; optical fiber

Artikel in diesem Heft

  1. Frontmatter
  2. Amplifiers
  3. Unified Formalism for Erbium-Doped Fiber Amplifiers and Lasers
  4. Nonlinear Effects with Semiconductor Optical Amplifiers
  5. Average Power Model of Optical Raman Amplifiers Based on Frequency Spacing and Amplifier Section Stage Optimization
  6. Devices
  7. An Optical Half Adder Using Nonlinear Ring Resonator Based on Photonic Crystal
  8. Implementation of Polarization-Encoded Quantum Fredkin Gate Using Kerr Effect
  9. Lasers
  10. Spatial Continuous Wave Laser and Spatiotemporal VCSEL for High-Speed Long Haul Optical Wireless Communication Channels
  11. Measurements
  12. Graphene Oxide Effect on Improvement of Silver Surface Plasmon Resonance D-Shaped Optical Fiber Sensor
  13. Networks
  14. High-Speed Light Sources in High-Speed Optical Passive Local Area Communication Networks
  15. RSVP-TE Bilateral-Recursive Region Re-Routing Crankback Mechanism for Large-Scale Optical Networks
  16. An Intelligent Vehicle Control System for Enhancing Road Safety Using Optimal Visible Light Communication Network
  17. Systems
  18. Design and Parameter Analysis of Underwater Wireless Optical Communication with Different Water Samples
  19. Free Space Optical Communication System under Different Weather Conditions
  20. Windowing Techniques for Reducing PAPR of OFDM in Li-Fi Systems
  21. Effects of Order Super Gaussian Pulses on the Performance of High Data Rate Optical Fiber Channel in the Presence of Self Phase Modulation
  22. Evaluation of Proposed Coherent Optical OFDM Link Using X-QAM with Polarization Division Multiplexing
  23. Theory
  24. Mathematical Model Analysis of Dispersion and Loss in Photonic Crystal Fibers
  25. Simulation of Optical ISL with 48 Transponders and Performance Analysis Using Ber and Q-Factor
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