Sensing using Specialty Optical Fibers

Fiber optic based sensing is a growing field with many applications in civil and aerospace engineering, oil and gas industries, and particularly in harsh environments where electronics are not able to function. Optical fibers can be easily integrated into structures, are immune to electromagnetic interference, can be interrogated from remote distances, and can be multiplexed for distributed measurements. Because of these properties, specialty fiber designs and devices are being explored for sensing temperature, strain, pressure, curvature, refractive index, and more. Here we show a detailed analysis of a multicore fiber (MCF) for sensing, including its design and optimization in simulation, as well as experimental operation when used as sensor. The multicore fiber sensor\u27s performance as a function of temperature, strain, bending, and acoustic waves are all explored. The MCF sensors are shown to be able to withstand temperatures up to 1000°C, making them suitable to be harsh environment sensors. Additionally, a simple method for increasing the sensitivity of the MCF to longitudinal force is shown to multiple the sensitivity of the MCF sensor by a factor of seven. Also, a configuration for decoupling force and temperature will be presented. Finally, a developing all-fiber device, a photonic lantern, will be shown in conjunction with the MCF in order to increase sensitivity, add directional sensitivity, and lower the cost of the sensor interrogation for bending measurements. In addition to the multicore fiber, an analysis of anti-resonant hollow core fiber (ARHCF) is also presented. The fibers\u27 design-dependent propagation losses are explored, as well as their higher order mode content. Also, a potential application of an ARHCF for an in-fiber Raman air sensor is introduced, and the design optimization in simulation is shown

Observation of split evanescent field distributions in tapered multicore fibers for multiline nanoparticle trapping and microsensing

The optical attractive force in tapered single-mode fibers (SMFs) is usually uniformly distributed around the tapered section and has been found to be important for trapping and manipulating targeted atoms and nanoparticles. In contrast, a peculiar phenomenon of the evanescent field splitting along the azimuth axis can be experimentally observed by tapering a weakly-coupled MCF into a strongly-coupled MCF to generate supermode interference. Moreover, the supermode interference produces a hexagonally distributed evanescent field and its six vertices give rise to the multiline optical attractive force. For such spectral resonances, the optimum extinction ratio for the transmission dips is given by 47.4 dB, this being determined using an index liquid to cover the tapered MCF. The resonant dips move to a greater extent at longer wavelengths, with the optimum tuning efficiency of 392 nm/RIU for index sensing. The split evanescent fields respectively attract the excited upconversion nanoparticles in the liquid to be linearly aligned and running down the tapered region over the fiber surface, emitting green light with 60° symmetry. The charged nanoparticles were periodically self-organized, with a period of around 1.53 µm. The parallel lines, with 60° rotational symmetry, can be useful for (1) indicating the exact locations of the side-cores or orientations of the tapered MCF; (2) as precision alignment keys for micro-optical manipulation; and (3) enhancing the upconversion light, or for use in lasers, coupling back to the MCF. The split evanescent fields can be promising for developing new evanescent field-based active and passive fiber components with nano-structures

High Sensitivity Optical Fiber Interferometric Sensors

Optical fiber interferometers have been widely employed and investigated for monitoring the changes in both physical and chemical parameters, with the advantages of compact size, light weight, immunity to electromagnetic interference, high sensitivity, capability to work in harsh environments and remote operation capabilities. Among the different kinds of fiber sensors based on interferometry, singlemode-multimode-singlemode (SMS) structures has attracted considerable interest due to their inherent advantages of high sensitivity, ease of fabrication and interconnection to other fiber systems and low cost. However, the challenge is that the sensitivity of the traditional SMS based fiber structure is not sufficient in some cases, for example in bio-chemical applications, where detection of a very small variation in a bio-chemicals’ concentration is required. There is thus a need to investigate how to modify or enhance an SMS structure to achieve ultrahigh sensitivity. This thesis presents research and its applications concerning approaches to improve the sensitivity and detection accuracy of a traditional SMS fiber structure based sensor. The key achievements of this thesis include: Traditional SMS fiber structure for breathing state monitoring A bend SMS structure is investigated as a breathing sensor by attaching it to a thin plastic film in an oxygen mask. Breath rate can be monitored using this sensor by detecting power variations due to the macro bending applied to the SMS section during each inhalation and exhalation cycles. Different types of breathing conditions including regular and irregular breath patterns can be distinguished. The proposed sensor is capable of working in a strong electromagnetic field and radioactive environment. Tapered small core singlemode fiber (SCSMF) for the detection of refractive index (RI), ammonia, and volatile organic compounds (VOCs) A modified SMS structure based on a tapered SCSMF is proposed and investigated with significantly improved RI sensitivity. It is found that the sample with a smaller waist diameter gives higher sensitivity. In the experiment, a maximum sensitivity of 19212.5 nm/RIU (RI unit) in the RI range from 1.4304 to 1.4320 has been demonstrated when the waist diameter of the SCSMF is tapered down to 12.5 μm. The best corresponding theoretical resolution of the proposed sensor is 5.025 × 10-7 RIU which is over 10 times higher than that of many previous reported optical fiber based RI sensors. The proposed structure is capable of monitoring relative humidity level change even without coating of the fiber sensor’s surface with a layer of hygroscopic material. A silica sol-gel based coating has been used as a sensitive material to ammonia for the first time, by applying it to the surface of the tapered SCSMF for the detection of ammonia in water. The proposed sensor shows an ultra-high sensitivity of 2.47 nm/ppm with short response and recovery time of less than 2 and 5 minutes respectively. The corresponding theoretical detection limit of ammonia in water is calculated to be 4 ppb, which is 3 orders of magnitude improvement compared to the previous reported interferometry based ammonia sensor. In addition, the sensor has good performance in terms of repeatability of measurement and selectivity for sensing ammonia compared to that of other common ions and organic molecules in water. VOCs sensors are also demonstrated by coating a mixture of sol-gel silica and Nile red on the surface of two different types of tapered fiber sensors (tapered SCSMF) and a microfiber coupler (MFC)). The MFC based sensor shows better sensitivities to ethanol and methanol than that based on a tapered SCSMF due to its smaller waist diameter. The detectable gas concentration changes of the MFC based sensor are calculated to be ~77 ppb and ~281 ppb for ethanol and methanol respectively which are over one order of magnitude improvement than many other reports. The sensors also show fast response times of less than 5 minutes and recovery times varied from 7 to 12 minutes. Simultaneous measurement of ethanol and methanol is achieved by utilizing two different coating recipes. Hollow core fiber (HCF) structure for high temperature and twist sensing. A modified SMS structure with much improved spectral quality factor (Q) is investigated both theoretically and experimentally. The modified structure is based on a HCF. It is found that periodic transmission dips with high spectral extinction ratio and high Q factor are excited because of the multiple beam interferences introduced by the cladding of the HCF. The HCF structure can be used as a high sensitivity (up to 33.4 pm/°C) temperature sensor in a wide working temperature range (from room temperature to 1000 °C). By coating a thin layer of silver (~ 6.7 nm) on one side of the HCF surface, a twist sensor with a maximum sensitivity of 0.717 dB/°has been achieved, which is the highest twist sensitivity reported for intensity modulation based fiber sensors, with excellent measurement repeatability. Further theoretical and experimental investigation attributes this high twist sensitivity to the polarization dependent reflection coefficient at the outer HCF surface associated with the partial silver coating

Mode Coupling in Space-division Multiplexed Systems

Even though fiber-optic communication systems have been engineered to nearly approach the Shannon capacity limit, they still cannot meet the exponentially-growing bandwidth demand of the Internet. Space-division multiplexing (SDM) has attracted considerable attention in recent years due to its potential to address this capacity crunch. In SDM, the transmission channels support more than one spatial mode, each of which can provide the same capacity as a single-mode fiber. To make SDM practical, crosstalk among modes must be effectively managed. This dissertation presents three techniques for crosstalk management for SDM. In some cases such as intra-datacenter interconnects, even though mode crosstalk cannot be completely avoided, crosstalk among mode groups can be suppressed in properly-designed few-mode fibers to support mode group-multiplexed transmission. However, in most cases, mode coupling is unavoidable. In free-space optical (FSO) communication, mode coupling due to turbulence manifests as wavefront distortions. Since there is almost no modal dispersion in FSO, we demonstrate the use of few-mode pre-amplified receivers to mitigate the effect of turbulence without using adaptive optics. In fiber-optic communication, multi-mode fibers or long-haul few-mode fibers not only suffer from mode crosstalk but also large modal dispersion, which can only be compensated electronically using multiple-input-multiple-output (MIMO) digital signal processing (DSP). In this case, we take the counterintuitive approach of introducing strong mode coupling to reduce modal group delay and DSP complexity

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

The Photonic Lantern

Photonic lanterns are made by adiabatically merging several single-mode cores into one multimode core. They provide low-loss interfaces between single-mode and multimode systems where the precise optical mapping between cores and individual modes is unimportant.Comment: 45 pages; article unchanged, accepted for publication in Advances in Optics and Photonic

Advanced photonic sensors for industrial applications

380 p.En esta tesis se han desarrollado diversos sensores basados en fibra óptica cuya finalidad es ofrecer una alternativa o solución a las necesidades particulares de la industria. En este contexto, las fibras ópticas y la fotónica en general son especialmente atractivas gracias a características intrínsecas que poseen, como su pequeño tamaño y alta sensibilidad, por ejemplo, lo que ha aumentado el interés por parte del sector industrial en esta tecnología.En la primera parte de la tesis, se describe el proceso llevado a cabo para el diseño y fabricación de sensores ópticos para la medida sin contacto del parámetro llamado Tip Clearance (TC) en motores aeronáuticos. El TC consiste en medir la distancia (del orden de micrómetros) entre los álabes que están girando a altas revoluciones y la carcasa del motor, y, por tanto, es un parámetro de suma importancia para la industria aeronáutica tanto a nivel de seguridad como de eficiencia del motor. Dichos sensores fueron puestos a pruebas en el túnel de viento del Centro de Tecnologías Aeronáutcas (Zamudio, Bizkaia) con buenos resultados.En la segunda parte de la tesis se han diseñado y fabricado sensores basados en fibra multinúcleo particularizados específicamente para la medida de diversos parámetros como la temperatura,vibraciones, curvatura, bending, etc. que son de interés para la industria. Dichos sensores mostraron una alta sensibilidad, lo que unido a su simplicidad y pequeño tamaño los convierte en una alternativa interesante tanto para su integración en cadenas de producción como para su uso en test de validación

Hybridly Integrated Diode Lasers for Emerging Applications: Design, Fabrication, and Characterization

The emerging applications of LiDAR, microresonator based frequency comb, and photon pair generation in photonic integrated circuits (PICs) have attracted lots of research interests recently. The single frequency, high power, narrow-linewidth, tunable semiconductor lasers are highly desired for the implementation of these emerging applications in future PICs. In this dissertation, we use the hybrid integration via edge coupling to obtain the integrated diode lasers for future PICs, since the active chip and the passive chip can be fabricated and optimized independently. We demonstrate hybridly integrated narrow-linewidth, tunable diode lasers in the Indium Phosphide/Gallium Arsenide-silicon nitride (InP/GaAs-Si3N4) platform. Silicon nitride photonic integrated circuits, instead of silicon waveguides that suffer from high optical loss near 1 µm, are chosen to build a tunable external cavity for both InP and GaAs gain chips at the same time. Single frequency lasing at 1.55 µm and 1 µm is simultaneously obtained on a single chip with spectral linewidths of 18-kHz and 70-kHz, a side mode suppression ratio of 52 dB and 46 dB, and tuning range of 46 nm and 38 nm, respectively. The resulting dual-band narrow-linewidth diode lasers have potential for use in a variety of novel applications such as integrated difference-frequency generation, quantum photonics, and nonlinear optics. We also demonstrate one potential application of the dual-band diode laser in beam steering. The dual-band diode laser combined with a waveguide surface grating can provide the beam steering by tuning the wavelength of the light signal. However, the output power of the hybridly integrated diode lasers is still limited. Integrated coherent beam combining (CBC) is a promising solution to overcome this limitation. In this dissertation, coherently combined, integrated diode laser systems are experimentally demonstrated through hybrid integration. A chip-scale coherently combined laser system is experimentally demonstrated in the InP-Si3N4 platform through the manipulation of optical feedbacks at different output ports of the coupled laser cavities. Coherent combining of two InP-based reflective semiconductor amplifiers is obtained by use of the cross-coupling provided by an adiabatic 3 dB coupler in silicon nitride, with a combining efficiency of ~92%. The novel system not only realizes the miniaturization of coherent laser beam combining but also provides a chip-scale platform to study the coherent coupling between coupled laser cavities. Besides, the emerging platforms (i.e., gain chips based on semiconductor quantum dots, silicon-carbide-on-insulator and lithium-niobate-on-insulator) have attracted intense interests in recent years. The hybridly integrated diode lasers through edge coupling are demonstrated in these emerging platforms. In addition, we study the Parity-Time (PT) symmetry in the chip-scale hybrid platform. PT symmetric coupled microresonators with judiciously modulated loss and gain have been widely studied to reveal many non-Hermitian features in optical systems. The phase transition at the exceptional points (EPs) is a unique feature of the PT symmetric non-Hermitian systems. In this dissertation, we propose and demonstrate an electrically pumped, hybridly integrated chip-scale non-Hermitian system, where the optical gain, loss and coupling are separately controlled to allow for the PT symmetry breaking and direct access of the EPs. We use the coupled Fabry-Perot resonators through the hybrid integration of two InP active chips with one Si3N4 passive chip to realize the versatile control of the gain and loss. We first demonstrate the PT symmetry breaking and access of the EPs by investigating the spectral and spatial transition processes of the hybrid system induced by the asymmetric gains in the InP active chips. We then control the loss distribution in the Si3N4 passive chip so that the system loss contrast exceeds the coupling coefficient, which leads to the PT symmetry breaking and coherent addition of the two coupled lasers. Our integrated non-Hermitian optical system in the chip-scale hybrid integration platform successfully bridges the non-Hermitian physics and photonic integrated circuits and is able to expand the practical applications of non-Hermitian optical systems to a whole new stage