Thermally tunable polarization by nanoparticle plasmonic resonance in photonic crystal fibers

A photonic crystal fiber selectively filled with silver nanoparticles dispersed in polydimethylsiloxane has been numerically studied via finite elements analysis. These nanoparticles possess a localized surface plasmon resonance in the visible region which depends on the refractive index of the surrounding medium. The refractive index of polydimethylsiloxane can be thermally tuned leading to the design of polarization tunable filters. Filters found with this setup show anisotropic attenuation of the x-polarization fundamental mode around ?x = 1200dB/cm remarkably higher than the y-polarization mode. Moreover, high fiber birefringence and birefringence reversal is observed in the spectral region of the plasmon

Recent advances in plasmonic sensor-based fiber optic probes for biological applications

Funding: This research was funded by National Natural Science Foundation of China (NSFC), grant number [61675008]. Acknowledgments: KN wishes to thank The Royal Society Kan Tong Po International Fellowship 2018 for the travel fund to visit Hong Kong Polytechnic University and Shenzhen Science and Technology Innovation Commission (Project GJHZ20180411185015272).Peer reviewedPublisher PD

Surface Plasmon Resonance-Based Temperature Sensor with Outer Surface Metal Coating on Multi-core Photonic Crystal Fibre

Peer reviewedPublisher PD

Development of Photonic Crystal Fiber Based Gas/ Chemical Sensors

The development of highly-sensitive and miniaturized sensors that capable of real-time analytes detection is highly desirable. Nowadays, toxic or colorless gas detection, air pollution monitoring, harmful chemical, pressure, strain, humidity, and temperature sensors based on photonic crystal fiber (PCF) are increasing rapidly due to its compact structure, fast response and efficient light controlling capabilities. The propagating light through the PCF can be controlled by varying the structural parameters and core-cladding materials, as a result, evanescent field can be enhanced significantly which is the main component of the PCF based gas/chemical sensors. The aim of this chapter is to (1) describe the principle operation of PCF based gas/ chemical sensors, (2) discuss the important PCF properties for optical sensors, (3) extensively discuss the different types of microstructured optical fiber based gas/ chemical sensors, (4) study the effects of different core-cladding shapes, and fiber background materials on sensing performance, and (5) highlight the main challenges of PCF based gas/ chemical sensors and possible solutions

A numerical approach into new designs for SPR sensors in D-type optical fibers

This thesis investigates how to improve the performance of current designs of optical fiber sensors based on Surface Plasmon Resonance, and how to use a better understanding of the physical and sensing principles behind them to propose new sensing concepts and ideas. We adopt a methodology based on numerical simulations because they provide a better insight onto the operation of these sensors and because they allow an easy and quick way of testing new designs and concepts without the need to fabricate the sensors. We also show that these simulations have a good agreement with experimental results. We adopt a systematic approach to investigate the various parameters that influence the sensor performance, and present different sensors designs, where we study the localization, optical properties, shape and size of the metal components, combined with different type of fibers, resulting in the coupling between the plasmon and optical modes. Furthermore, we verify that choosing the optical modes used in sensing in multimode fibers can also have advantages. We investigate the use of modern artificial materials, such as metamaterials, as well as the inclusion of multiple wires in the fiber to enhance the performance of the SPR sensor. At a more fundamental level, we show that the control of the coupling between multiple plasmon modes in metal components and the optical modes in the fiber constitutes a new way to improve the performance of the sensor and can be inclusively used to develop a new type of SPR sensors capable of measuring simultaneously two variables, such as the external refractive index and temperatureEsta tese investiga como é possível melhorar o desempenho das estruturas atuais dos sensores de fibra ótica baseados em Ressonância Plasmónica de Superfície (SPR), bem como compreender melhor os princípios físicos e de sensorização na base do seu funcionamento, permitindo propor novos conceitos de sensores. Foi utilizada uma metodologia baseada em simulações numéricas, pois proporcionam um melhor entendimento do funcionamento desses sensores, constituindo uma maneira simples e rápida de testar novas estruturas e conceitos, sem a necessidade de fabricar os sensores. Mostra-se também que essas simulações têm uma boa concordância com os resultados experimentais. Foi adotada uma abordagem em que se investiga sistematicamente os diversos parâmetros que influenciam o desempenho do sensor e se apresentam diferentes estruturas de sensores onde foram estudadas a localização, propriedades óticas, forma e tamanho dos componentes metálicos, combinados com diferentes tipos de fibras, resultando no acoplamento entre os modos plasmónicos e os modos óticos. Também foi verificado que a escolha dos modos óticos utilizados na deteção em fibras multimodo pode apresentar vantagens. Foi investigado ainda o uso de materiais artificiais recentemente desenvolvidos, de que são exemplo os metamateriais, bem como, a inclusão de múltiplos fios metálicos na fibra, de forma a melhorar o desempenho dos sensores SPR. A um nível mais fundamental, foi demonstrado que o controlo do acoplamento entre os múltiplos modos plasmónicos gerados nos componentes metálicos e os modos óticos propagados na fibra constitui uma nova forma de melhorar o desempenho do sensor. Tal pode ser inclusivamente utilizado para desenvolver um novo tipo de sensores SPR capazes de medir simultaneamente duas variáveis, como por exemplo o índice de refração externo e a temperatura

Dual-polarized highly sensitive plasmonic sensor in the visible to near-IR spectrum

We propose and numerically characterize the optical characteristics of a novel photonic crystal fiber (PCF) based surface plasmon resonance (SPR) sensor in the visible to near infrared (500–2000 nm) region for refractive index (RI) sensing. The finite element method (FEM) is used to design and study the influence of different geometric parameters on the sensing performance of the sensor. The chemically stable plasmonic material gold (Au) is used to produce excitation between the core and plasmonic mode. On a pure silica (SiO2) substrate, a rectangular structured core is used to facilitate the coupling strength between the core and the surface plasmon polariton (SPP) mode and thus improves the sensing performance. By tuning the geometric parameters, simulation results show a maximum wavelength sensitivity of 58000 nm/RIU (Refractive Index Unit) for the x polarization and 62000 nm/RIU for the y polarization for analyte refractive indices ranging from 1.33 to 1.43. Moreover, we characterize the amplitude sensitivity of the sensor that shows a maximum sensitivity of 1415 RIU−1 and 1293 RIU−1 for the x and y polarizations, respectively. To our knowledge, this is the highest sensitivity for an SPR in published literature, and facilitates future development of sensors for accurate and precise analyte measurement. The sensor also attains a maximum figure of merit (FOM) of 1140 and fine RI resolution of 1.6 × 10−6. Owing to strong coupling strength, high sensitivity, high FOM and improved sensing resolution, the proposed sensor is suited for real-time, inexpensive and accurate detection of biomedical and biological analytes, biomolecules, and organic chemicals.This work is supported by Australian Research Council (grant no. DP170104984). We gratefully acknowledge their support

A Simple Optical Fiber Spr Sensor with Ultra-High Sensitivity for Dual-Parameter Measurement

This work reports a simple optical fiber Surface Plasmon Resonance (SPR) sensor with ultra-high sensitivity for simultaneous measurement of the dual-parameter. The sensor is based on a D-shaped fiber with a nanolayer coating of Silver (Ag) and Hematite (α-Fe2O3). The Ag/α-Fe2O3 layer is deposited on the longitudinal surface of residual cladding, and a Fiber Bragg Grating (FBG) is inscribed on the single-mode fiber (SMF) for temperature compensation. The α-Fe2O3 layer protects the Ag layer from oxidation and effectively enhances the surface plasmon wave while interacting with free electrons. Finite Element Method (FEM) modeling is employed to investigate the refractive index (RI) and temperature response of the SPR sensor. The SPR sensor exhibits an ultra-high RI sensitivity of 8,518 nm/RIU (refractive index unit) in the RI range of 1.33 to 1.40, and a temperature sensitivity of-52 pm/°C in the temperature range of 20 °C to 60 °C. The SPR performance suggests that it is a potential candidate for various applications of dual-parameter sensing

Novel Specialty Optical Fibers and Applications

Novel Specialty Optical Fibers and Applications focuses on the latest developments in specialty fiber technology and its applications. The aim of this reprint is to provide an overview of specialty optical fibers in terms of their technological developments and applications. Contributions include:1. Specialty fibers composed of special materials for new functionalities and applications in new spectral windows.2. Hollow-core fiber-based applications.3. Functionalized fibers.4. Structurally engineered fibers.5. Specialty fibers for distributed fiber sensors.6. Specialty fibers for communications

Dual-polarized highly sensitive plasmonic sensor in the visible to near-IR spectrum

We propose and numerically characterize the optical characteristics of a novel photonic crystal fiber (PCF) based surface plasmon resonance (SPR) sensor in the visible to near infrared (500–2000 nm) region for refractive index (RI) sensing. The finite element method (FEM) is used to design and study the influence of different geometric parameters on the sensing performance of the sensor. The chemically stable plasmonic material gold (Au) is used to produce excitation between the core and plasmonic mode. On a pure silica (SiO2) substrate, a rectangular structured core is used to facilitate the coupling strength between the core and the surface plasmon polariton (SPP) mode and thus improves the sensing performance. By tuning the geometric parameters, simulation results show a maximum wavelength sensitivity of 58000 nm/RIU (Refractive Index Unit) for the x polarization and 62000 nm/RIU for the y polarization for analyte refractive indices ranging from 1.33 to 1.43. Moreover, we characterize the amplitude sensitivity of the sensor that shows a maximum sensitivity of 1415 RIU−1 and 1293 RIU−1 for the x and y polarizations, respectively. To our knowledge, this is the highest sensitivity for an SPR in published literature, and facilitates future development of sensors for accurate and precise analyte measurement. The sensor also attains a maximum figure of merit (FOM) of 1140 and fine RI resolution of 1.6 × 10−6. Owing to strong coupling strength, high sensitivity, high FOM and improved sensing resolution, the proposed sensor is suited for real-time, inexpensive and accurate detection of biomedical and biological analytes, biomolecules, and organic chemicals.Md. Saiful Islam, Jakeya Sultana, Ahmmed. A. Rifat, Rajib Ahmed, Alex Dinovitser, Brian W.-H. Ng, Heike Ebendorff-Heidepriem and Derek Abbot