Photonic crystal fibers for sensing applications

Photonic crystal fibers are a kind of fiber optics that present a diversity of new and improved features beyond what conventional optical fibers can offer. Due to their unique geometric structure, photonic crystal fibers present special properties and capabilities that lead to an outstanding potential forsensing applications. A review of photonic crystal fiber sensors is presented. Two different groups of sensors are detailed separately: physical and biochemical sensors, based on the sensor measured parameter. Several sensors have been reported until the date, and more are expected to be developed due to the remarkable characteristics such fibers can offer.The authors are grateful to the Spanish Government project TEC2010-20224-C02-01

Understanding the Radiation Effects on Fiber Optic Sensors

In this dissertation, the effects of radiation (gamma, neutron or mixed gamma and neutron) on optical fiber sensors are studied and new techniques for real-time measurement of radiation-induced macroscopic changes in optical fibers are presented. It is crucial among the research and development efforts in the nuclear energy field to conduct experiments in Advanced Test Reactor (ATR) to support lifetime extension, novel fuels and materials development, better fuel management, and enhanced safety of existing as well as future nuclear power plants (NPP). Due to their unparalleled and unique advantages over traditional sensors, optical fiber sensors are deemed potential candidates for their use in nuclear environments. However, optical fibers are susceptible to high levels of ionizing radiation emitted by fission reactors which are characterized by the highest levels of gamma dose, high flux of neutrons and potentially high temperatures depending on location in a reactor core. It is essential to accurately determine the information related to physical parameters such as temperature, pressure, and strain in nuclear environments for the safety of the existing and future NPPs. This dissertation starts with inverting a transmission mode long period grating (LPG) to reflection mode using a novel and cost-effective metal coating method since transmission mode LPG limits it applications in tight spaces or in nuclear fields. To understand the metal coating and metal coverage effects on the reflection spectrum of LPG, modeling work was performed, and it was validated by experimental work. We have shown that the sensitivity of LPGs to physical parameters in both transmission and reflection modes are almost the same. Next, we have modeled the radiation effects on different fiber optic sensors, proposed empirical models, and performed numerical analysis to understand the effects of nuclear environments on fiber optic sensors. We analyzed the real-time data from fiber Bragg gratings (FBGs) exposed to high neutron fluence and high temperature environments within the ATR at Idaho National Laboratory (INL). We have found that incoming radiation significantly drifts the characteristic signal of FBGs, leading to a temperature measurement error when FBGs are dedicated to temperature sensing. It is well known that neutron and gamma irradiation compacts silica optical fibers, resulting in a macroscopic change in the refractive index (RI) and geometric structure. The change in RI and linear compaction in a radiation environment is caused by three well-known mechanisms: (1) radiation induced attenuation (RIA), (2) radiation induced compaction (RIC), and (3) radiation induced emission (RIE). While RIA degrades the signal strength by creating different types of color centers in the silica fiber, RIC alters the density, and hence RI by displacing the host material atoms. However, Kramers-Kronig relation states that absorption, and hence the RIA, also modifies the RI of the silica fiber. Apart from RIA and RIC, other phenomena such as temperature, dose rate, stress relaxation, and dopant compositions exchange may change the RI. To overcome these problems, we have proposed an effective technique to measure the change in RI and compaction of optical fiber due to any specific phenomena the fiber is subjected to, including RIC, RIA, dopant diffusion, temperatures, dose, dose rate, etc. By knowing the individual contribution of RI and fiber length to the signal drift, it is possible to reduce the radiation induced signal drift in optical fiber sensors and provide accurate information regarding the temperature inside a radiation environment. Fission gas detection in nuclear environments is another important aspect that needs to be focused on. Pressure induced by fission gases during irradiation may lead to loss of coolant accident (LOCA), which can cause severe damage to the NPPs. We have modeled and fabricated optical fiber-based sensors to enable real-time monitoring of fission gases, which allows understanding the implications of fission gas release during an accident, important for safe and high performance

Dispersion tailoring in both integrated photonics and fiber-optic based devices

Tesis por compendio[EN] This Thesis focuses on the study, implementation and characterization of chromatic dispersion tailoring employing both optical fiber and photonic integrated waveguides. Chromatic dispersion causes that the different spectral components of an optical pulse travel at different velocities. This effect can be separated into two different fundamental contributions, material dispersion and waveguide dispersion. Chromatic dispersion can be tailored through the design of the structural parameters of the device in order to obtain specific characteristics in the resulting dispersion profile such as low values of dispersion and/or zero dispersion at a desired wavelength, for example. This approach is very useful in dispersion-dependent applications. In this PhD, we investigate chromatic dispersion tailoring in two different transmission mediums, photonic integrated waveguides and optical fiber. In the first case, two different geometries of Silicon-on-Insulator (SOI) integrated waveguides, strip and slot, are considered. By varying structural parameters such as the cross-section, aspect ratio or fill factor, different chromatic dispersion profiles are obtained. In addition, the influence of the slot location is evaluated. This study is carried out using simulation software in order to obtain the effective refractive index profile as a function of wavelength, which is later differentiated to obtain the final dispersion values. Besides, chromatic dispersion in both waveguide geometries is experimentally measured using an interferometer technique. In the second case, the chromatic dispersion present in a tapered fiber is studied. A tapered fiber consists of a narrow waist located between two transition regions and it allows the modification of the conventional propagation conditions due to the interference between the modes propagating through the waist. This interference between modes creates a transmission pattern which depends on the waist length and the effective refractive indexes of the modes travelling through the waist. By applying stress to the tapered fiber its interference pattern can be modified. Chromatic dispersion profile of tapered fibers is obtained, tailored and compared with the dispersion profile of conventional single-mode fibers.[ES] Esta Tesis se centra en el estudio, implementación y caracterización del control de la dispersión cromática empleando tanto fibra óptica como guías integradas fotónicas. La dispersión cromática provoca que las distintas componentes espectrales asociadas con el pulso óptico viajen a diferentes velocidades. Este efecto puede ser dividido en sus dos contribuciones fundamentales, la dispersión del material y la dispersión de la guía. La dispersión cromática puede ser controlada a través del diseño de los parámetros estructurales del dispositivo para poder obtener así determinadas características en el perfil de dispersión resultante como por ejemplo bajos valores o localización de la longitud de onda de dispersión cero en una longitud de onda deseada. Este método es muy útil en aplicaciones dependientes de la dispersión. En esta Tesis, investigamos el control de la dispersión cromática en dos medios de transmisión diferentes, las guías fotónicas integradas y la fibra óptica. En el primer caso, se consideran dos geometrías diferentes de guías integradas en silicio, las guías convencionales y las guías ranuradas. Mediante la modificación de los parámetros estructurales como la sección transversal de la guía, su relación de aspecto o el factor de llenado, se obtienen diferentes perfiles de dispersión cromática. Además, se evalúa la influencia de la situación de la ranura. Mediante software de simulación, se obtiene el perfil de índice de refracción efectivo en función de la longitud de onda, que posteriormente se deriva y se obtiene el valor de la dispersión. Asimismo, se mide experimentalmente la dispersión en ambas geometrías utilizando una técnica interferométrica. En el segundo caso, se analiza la dispersión cromática que presenta una fibra de tipo taper. Esta geometría consiste en una cintura estrecha situada entre dos regiones de transición y permite la modificación de las condiciones de propagación convencionales debido a la interferencia entre los modos que se propagan por la cintura, que crea un patrón de transmisión dependiente de la longitud de la cintura y de los índices efectivos de los modos. Aplicando tensión sobre la fibra, su patrón de interferencia puede ser modificado. La dispersión cromática de las fibras taper se obtiene, se modifica y se compara con el perfil de dispersión de una fibra convencional.[CA] La tesi a exposar se centra en l'estudi, implementació i caracterització del control de la dispersió cromàtica empleant la fibra òptica i les guies integrades fotòniques. La dispersió cromàtica provoca que els distints components espectrals associats amb la pols òptica viatgen a diferents velocitats. Aquest pot dividir-se en les dos contribucions fonamentals corresponents: la dispersió del material i la dispersió de la guia. La dispersió cromàtica pot controlar-se a través del disseny dels paràmetres estructurals del dispositiu per poder obtindre aixi determinades característiques en el perfil de dispersió resultant, com per exemple, baixos valors o localizació de la longitud d'ona de dispersió zero a una longitud d'ona desitjada. No obstant això, aquest mètode és molt útil en aplicacions depenents de la dispersió. A més a més, investiguem el control de dispersió cromàtica en dos mitjans de transmissió diferents, les guies fotòniques integrades i la fibra òptica. D'una banda, es consideren dos geometries diferents de guies integrades en silici, les guies convencionals i les ranurades. Mitjançant la modificació dels paràmetres estructurals com la secció transversal de la guia, la relació d'apecte o el factor d'ompliment, obtenim diferents perfils de dispersió cromàtica. Fins i tot, s'avalua la influència de la situació de la ranura. Mitjançant el programari de simulació, obtenim el perfil d'índex de refracció efectiu en funció de la longitud d'ona, que posteriorment es derivarà i s'obrindrà el valor de la dispersió. Tanmateix, es mesura experimentalment la dispersió en les dos geometries utilitzant una tècnica interferomètrica. D'altra banda, analitzam la dispersió cromàtica que presenta una fibra de tipus taper. Aquesta consisteix en una cintura estreta situada entre dos regions de transició que, ens permet la modificació de les condicions de propagació convencional com a causa d'una interferència entre els modes que es propaguen per la cintura i els índex efectius dels modes. Si apliquem tensió sobre la fibra, el seu patró d'interferència podria ser modificat. La dispersió d'una fibra cromàtica de les fibres taper s'obté, es modific i es compara amb el perfil de dispersió d'una fibra convencional.Mas Gómez, SM. (2015). Dispersion tailoring in both integrated photonics and fiber-optic based devices [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/54113TESISCompendi

Design of photonic sensors based on cavities and new interrogation techniques

[ES] Los sensores ópticos son dispositivos fotónicos sensibles a determinadas magnitudes que se usan precisamente para medir, ya sea de forma absoluta o relativa, esas magnitudes. Medir la temperatura, la presión, la tensión, la humedad o la presencia de un determinado gas son algunas de las funcionalidades que llevan a cabo estos sensores. A lo largo de las últimas décadas multitud de sensores y técnicas de interrogación han sido desarrolladas, lo que ha tenido un increíble impacto en multitud de áreas. Uno de los ejemplos más claro es la arquitectura civil, donde los sensores fotónicos juegan un papel fundamental en la monitorización del estado de las estructuras. A pesar de los buenos resultados conseguidos por los sensores ópticos hasta la fecha, las técnicas de interrogación desarrolladas hasta ahora muestran algunas desventajas. Tiempos de medida altos, baja resolución o una gran complejidad son algunas de ellas. En esta tesis doctoral se presenta el diseño y caracterización de diversos sensores fotónicos basados en las ya conocidas redes de difracción de Bragg así como la implementación de nuevas técnicas de interrogación de dichos sensores para intentar eliminar o reducir esas desventajas. Las técnicas de interrogación desarrolladas en este trabajo se basan en la fotónica de microondas, donde la interacción entre las señales ópticas y eléctricas se usa para detectar en este caso los cambios en una determinada magnitud. Las técnicas desarrolladas en este trabajo buscan ser lo más versátiles y escalables posibles para así poder adaptarse a los requerimientos de diferentes escenarios. Encontramos así técnicas que permiten interrogar a miles de sensores con una gran resolución y sensibilidad así como también técnicas de interrogación de sensores puntuales con una enorme sensibilidad y simplicidad tanto en la interrogación como en el sistema usado para ello. También están presentes los resultados obtenidos mediante la colaboración con el instituto de investigación sueco ACREO para el desarrollo de un sensor de campo eléctrico basado en fibras polarizadas donde se han fabricado varias redes de difracción de Bragg.[CA] Els sensors òptics son dispositius fotònics sensibles a determinades magnituds que s'usen precisament per a mesurar, ja siga de forma absoluta o relativa, aquestes magnituds. Mesurar la temperatura, la pressió, la tensió, la humitat o la presència d'un determinat gas són algunes de les funcionalitats que realitzen aquestos sensors. Al llarg de les últimes dècades multitud de sensors i tècniques d'interrogació han sigut desenvolupades, i això ha tingut un impacte increïble a multitud d'àrees. Un dels exemples més clar es l'arquitectura civil, on aquestos sensors juguen un paper fonamental en la monitoratge de l'estat de les estructures. Encara que els resultats aconseguits han sigut bons, les tècniques d'interrogació desenvolupades fins ara mostren alguns desavantatges. Temps de mesurament alt, baixa resolució o una gran complexitat són algun d'ells. A aquesta tesi doctoral es presenta el disseny i caracterització de diversos sensors fotònics basats en les ja conegudes xarxes de difracció de Bragg així com l'implementació de noves tècniques d'interrogació per a intentar eliminar o reduir aquestos inconvenients. Les tècniques d'interrogació desenvolupades en aquest treball es basen en la fotònica de microones, on l'interacció entre les senyals òptiques i elèctriques s'usa per a detectar en aquest cas els canvis en una determinada magnitud. Les tècniques desenvolupades en aquest treball busquen ser el més versàtils i escalables possibles per a poder adaptar-se als requeriments dels diferents escenaris. Trobem així tècniques que permeten interrogar milers de sensors amb una gran resolució i sensitivitat però també tècniques que permeten interrogar sensors puntuals amb una increïble sensitivitat mostrant una gran simplicitat en el seu disseny. També estan presents els resultats obtinguts mitjançant la col¿laboració amb l'institut d'investigació suec ACREO per al desenvolupament d'un sensor de camp eléctric basat en FBGs i en fibres polaritzades.[EN] Optical sensors are photonic devices sensitive to different magnitudes that are used precisely to measure, in an absolute or a relative way, these magnitudes. These optical sensors are nowadays used to measure temperature, pressure, strain, humidity or the presence of a particular gas. In the past few decades a multitude of photonic sensors and different interrogation techniques have been developed, which had a great impact in dozens of different fields. One of the best examples is civil architecture, in which photonic sensors play a fundamental role in order to monitor the condition of the structures. Despite of the good results showed by photonic sensors, the interrogation techniques used show different drawbacks. A large measurement time, low resolution or great complexity are some of them. In this doctoral thesis the design and characterization of a set of different photonic sensors based on the already known fiber Bragg gratings, along with the implementation of new interrogation techniques, are used in order to eliminate or at least reduce these problems. The interrogation techniques developed in this work are based on Microwave Photonics techniques, in which the interaction between optical and electrical signals is used to detect in this case the changes in a particular magnitude. The techniques showed in this work have been designed in order to be as versatile and scalable as possible to have the opportunity to adapt to any requirement in different scenarios. In this work techniques that are able to interrogate hundreds or even thousands of sensors with great sensitivity and resolution can be found in addition to techniques that are developed to interrogate individual sensors with an enormous sensitivity. The work carried out in collaboration with the Swedish research institute ACREO, based on the development of an electric field sensor based on poled fibers together with FBGs is also present.Hervás Peralta, J. (2019). Design of photonic sensors based on cavities and new interrogation techniques [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/119754TESI

Multiplexed optical fibre sensors for civil engineering applications

Fibre-optic sensors have been the focus of a lot of research, but their associated high cost has stifled their transferral from the laboratory to real world applications. This thesis addresses the issue of multiplexing, a technology that would lower the cost per unit sensor of a sensor system dramatically. An overview of the current state of research of, and the principles behind, multiplexed sensor networks is given. A new scheme of multiplexing, designated W*DM, is developed and implemented for a fibre Bragg grating (FBG) optical fibre sensor network. Using harmonic analysis, multiplexing is performed in the domain dual to that of the wavelength domain of a sensor. This scheme for multiplexing is compatible with the most commonly used existing schemes of WDM and TDM and thus offers an expansion over, and a resultant cost decrease from, the sensor systems currently in use. This research covered a theoretical development of the scheme, a proof of principle, simulated and experimental analysis of the performance of the multiplexed system, investigation into sensor design requirements and related issues, fabrication of the sensors according to the requirements of the scheme and the successful multiplexing of eight devices (thus offering an eightfold increase over current network capacities) using this scheme. Extensions of this scheme to other fibre sensors such as Long Period Gratings (LPGs) and blazed gratings were also investigated. Two LPGs having a moiré structure were successfully multiplexed and it was shown that a blazed Fabry Perot grating could be used as a tuneable dual strain/refractive index sensor. In performing these tests, it was discovered that moiré LPGs exhibited a unique thermal switching behaviour, hereto unseen. Finally the application of fibre sensors to the civil engineering field was investigated. The skill of embedding optical fibre in concrete was painstakingly developed and the thermal properties of concrete were investigated using these sensors. Field tests for the structural health monitoring of a road bridge made from a novel concrete material were performed. The phenomenon of shrinkage, creep and cracking in concrete was investigated showing the potential for optical fibre sensors to be used as a viable research tool for the civil engineer

Design and Development of an Optical Chip Interferometer For High Precision On-Line Surface Measurement

Advances in manufacturing and with the demand of achieving faster throughput at a lower cost in any industrial setting have put forward the need for embedded metrology. Embedded metrology is the provision of metrology on the manufacturing platform, enabling measurement without the removal of the workpiece. Providing closer integration of metrology upon the manufacturing platform will improve material processing and reliability of manufacture for high added value products in ultra-high-precision engineering. Currently, almost all available metrology instrumentation is either too bulky, slow, destructive in terms of damaging the surfaces with a contacting stylus or is carried out off-line. One technology that holds promise for improving the current state-of-the-art in the online measurement of surfaces is hybrid photonic integration. This technique provides for the integration of individual optoelectronic components onto silicon daughter boards which are then incorporated on a silica motherboard containing waveguides to produce a complete photonic circuit. This thesis presents first of its kind a novel chip interferometer sensor based on hybrid integration technology for online surface and dimensional metrology applications. The complete metrology sensor system is structured into two parts; hybrid photonic chip and optical probe. The hybrid photonic chip interferometer is based on a silica-on-silicon etched integrated-optic motherboard containing waveguide structures and evanescent couplers. Upon the motherboard, electro-optic components such as photodiodes and a semiconductor gain block are mounted and bonded to provide the required functionality. Optical probe is a separate entity attached to the integrated optic module which serves as optical stylus for surface scanning in two measurement modes a) A single-point for measuring distance and thus form/surface topography through movement of the device or workpiece, b) Profiling (lateral scanning where assessment of 2D surface parameters may be determined in a single shot. Wavelength scanning and phase shifting inteferometry implemented for the retrival of phase information eventually providing the surface height measurement. The signal analysis methodology for the two measurement modes is described as well as a theoretical and experimental appraisal of the metrology capabilities in terms of range and resolution. The incremetal development of various hybrid photonic modules such as wavelength encoder unit, signal detection unit etc. of the chip interferometer are presented. Initial measurement results from various componets of metrology sensor and the surface measurement results in two measurement modes validate the applicability of the described sensor system as a potential metrology tool for online surface measurement applications

Optical Fiber High Temperature Sensor Instrumentation for Energy Intensive Industries

This report summarizes technical progress during the program “Optical Fiber High Temperature Sensor Instrumentation for Energy Intensive Industries”, performed by the Center for Photonics Technology of the Bradley Department of Electrical and Computer Engineering at Virginia Tech. The objective of this program was to use technology recently invented at Virginia Tech to develop and demonstrate the application of self-calibrating optical fiber temperature and pressure sensors to several key energy-intensive industries where conventional, commercially available sensors exhibit greatly abbreviated lifetimes due primarily to environmental degradation. A number of significant technologies were developed under this program, including • a laser bonded silica high temperature fiber sensor with a high temperature capability up to 700°C and a frequency response up to 150 kHz, • the world’s smallest fiber Fabry-Perot high temperature pressure sensor (125 x 20 μm) with 700°C capability, • UV-induced intrinsic Fabry-Perot interferometric sensors for distributed measurement, • a single crystal sapphire fiber-based sensor with a temperature capability up to 1600°C. These technologies have been well demonstrated and laboratory tested. Our work plan included conducting major field tests of these technologies at EPRI, Corning, Pratt & Whitney, and Global Energy; field validation of the technology is critical to ensuring its usefulness to U.S. industries. Unfortunately, due to budget cuts, DOE was unable to follow through with its funding commitment to support Energy Efficiency Science Initiative projects and this final phase was eliminated

Multimode fibre broadband access and self-referencing sensor networks

Future Internet Access technologies are supposed to bring us a very performing connection to the main door of our homes. At the same time, new services and devices and their increase use will require data transfers at speeds exceeding 1Gbps inside the building or home at the horizon 2012. Both drivers lead to the deployment of a high-quality, futureproof network inside buildings and homes. This environment may end up taking advantage of optical cabling solutions as an alternative to more traditional copper or pure wireless approaches. Related to this latter fact, the objectives of this work are: • The achievement of a full convergence scenario between optical networks from the telecommunication services providers to the end users underscores the necessity of accurate and realistic fibre models in assessing the performance of broadband access networks with the premises of high-capacity and total compatibility. Silicabased MMFs and PF GIPOFs are the most promising candidates for such a convergence within the in-building/home scenario. Contributions to a better understanding of the possibilities of signal transmission outside the baseband of such fibres are investigated, in order to extend their capabilities, together with the evaluation of current fibre frequency response theoretical models by means of an extensive set of measurements. • The achievement of a full convergence scenario between optical networks from the telecommunication services providers to the end users is also contingent on research and development in the field of optical fibre sensors, mainly driven by the growing demand of fully building/home and industry automation, leading to a reliable integration of the optical networks. Related to this, development of multiplexing and measurement techniques for fibre-optic intensity-based sensors are analyzed and experimentally investigated. In the sensor network topology proposed, by replacing the fibre delay line with an electronic delay in the reception stage, it is possible to avoid long fibre delay coils in the remote sensing points and achieving a compact, flexible and re-configurable self-referencing technique. Applications in both scenarios can be considered, on the one hand the in-building/home network and on the other hand the WDM-PON access network topology through which operators provision the different services. -----------------------------------------------------------------------------------------------------------------------------------------------------------------------------La demanda e incursión en la sociedad de nuevos servicios multimedia, tales como televisión por Internet (IPTV, Internet Protocol Television) o video-bajo-demanda (VoD, Video on Demand) junto con el incremento del tráfico de datos requerido para nuevas aplicaciones como la televisión por alta definición (HDTV, High-Definition Television) y transferencias P2P (Peer-to-Peer) exigen un aumento de la capacidad de las redes de datos desplegadas hoy en día. Para hacer frente a este aumento de la demanda de capacidad de las redes de acceso, los proveedores de estos servicios multimedia están reemplazando las infraestructuras de las redes de acceso basadas en cable coaxial, tales como xDSL (x- Digital Subscriber Line), por otras nuevas de mayor capacidad desplegadas en fibra óptica, permitiendo la interconexión de los nodos de red con los múltiples hogares y negocios de los abonados, constituyendo el núcleo de lo que es conocido como “fibra hasta el hogar/nodo/edificio” o redes FTTx. Tradicionalmente el despliegue de las redes ópticas se ha realizado mediante fibra óptica monomodo de sílice (SMF, Singlemode Fibre). Ello es debido a su gran ancho de banda que permite una gran capacidad de transporte de servicios y datos. Es por ello que en base a este tipo de fibra se ha realizado el despliegue de redes de distribución y metropolitanas y, de un tiempo a esta parte, incluso penetrando su instalación en las redes de acceso. Junto con lo anteriormente expuesto, existe una necesidad de convergencia de servicios e infraestructuras dentro de las redes de acceso. Actualmente, cables coaxiales, par trenzado de cobre e incluso señales inalámbricas se encuentran entremezcladas dentro del hogar proporcionando servicios diferentes con apenas cooperación entre ellos. Una infraestructura común dentro del hogar en el que una gran cantidad de servicios pudieran ser integrados y soportados por la misma sería un aspecto deseable. Y es más, frente a las desventajas de infraestructuras basadas en cable de cobre (cable coaxial y par trenzado) como son susceptibilidad a interferencias electromagnéticas, presencia de crosstalk y relativa baja capacidad de transporte de datos, las fibras ópticas (tanto en su versión monomodo como multimodo) presentan las ventajas de un menor volumen, mayor flexibilidad y menor peso junto con una capacidad mayor de transmisión de datos sobre distancias mayores. Es por esto que éstas últimas constituyen la base para las futuras redes de acceso en el hogar