Global ETD Search

21	LOW-LOSS, HIGH PERFORMANCE HYBRID PHOTONICS DEVICES ENABLED BY ION-EXCHANGED GLASS WAVEGUIDES Araci, Ismail E. January 2010 (has links) Robust ion-exchanged glass waveguides exhibit low optical losses in a broad spectral range and they allow integration of several devices on the same chip due to their planar structure. Consequently, they can be a low cost alternative to semiconductors for fabricating various integrated optical devices. Two high performance photonic devices were designed and realized, demonstrating the potential of glass waveguides. The well-controlled silver-film ion-exchange process allowed the fabrication of: i) a highly sensitive biosensor based on optical absorption and, ii) a low loss hybrid electro-optic (EO) polymer modulator with a narrow coplanar electrode gap. The single-mode, channel integrated optical ion-exchange waveguide on borosilicate glass (Corning 0211) is described for broad spectral band (400-650 nm) detection and analysis of heme-containing protein films at a glass/water interface. The evanescent wave interaction is improved significantly by fabricating ion-exchange waveguides with a step-like index profile. Silver nano-particle formation is reduced in order to achieve low loss in the Soret-band (~400 nm). Unlike other surface-specific techniques (e.g. SPR, interferometry) that probe local refractive-index changes and therefore are susceptible to temperature fluctuations, the integrated optical waveguide absorption technique probes molecular-specific transition bands and is expected to be less vulnerable to environmental perturbations. The hybrid integration of phosphate glass (IOG-1) and EO polymer is realized for the first time. The critical alignment steps which are typically required for hybrid optoelectronic devices are eliminated with a simple alignment-free fabrication technique. The low loss adiabatic transition from glass to EO polymer waveguide is enabled by gray scale patterning of the novel EO polymer, AJLY. Total insertion loss of 5 dB and electrode gap of 8 μm is obtained for an optimized device design. EO polymer poling at 135 ºC and 75 V/μm is enabled by the sol-gel buffer layer. electrooptic modulators evanescent wave sensors integrated optical devices ion-exchange waveguides nonlinear polymer devices sol-gel thin film
22	Ultrafast laser-induced modification of optical glasses : a spectroscopy insight into the microscopic mechanisms / Transformation photo-assistée de diélectriques pour l’optique par laser à impulsions ultra-brèves : études des mécanismes microscopiques Mishchik, Konstantin 12 July 2012 (has links) Le changement local de l'indice de réfraction (CLIR) est l’élément constitutif des fonctions optiques créées par laser dans des matériaux transparents. Selon le régime de l'interaction et en particulier en fonction de la dose d’énergie déposée, de la durée de l'impulsion laser et des conditions de focalisation on peut induire un CLIR isotrope et positif ou produire à l’échelle nanométrique des structures auto-arrangées présentant une biréfringence. Ce changement est essentiel pour les applications photoniques intégrées utilisant des matériaux comme la silice, ce qui été démontré dans la thèse par réalisation des composants optiques allant du simple guide canal enterré à des dispositifs sensibles à la polarisation. En parallèle au développement d’applications photoniques nous avons étudiés les mécanismes microscopiques à l’origine de la modification des propriétés optiques des diélectriques utilisés. Nous avons appliqué les techniques de micro photoluminescence et microspectroscopie Raman pour étudier la formation des défauts ponctuels et des chemins de réorganisation de la structure du verre. Ces modifications de structure de verres jouent un rôle important dans le changement des propriétés électroniques de la silice fondue et, par conséquent, de ses constantes optiques. L’ensemble de ces résultats spectroscopiques nous a permis de revisiter les schémas de densification dans la silice et de proposer un scénario de densification assistée par les défauts générés suite à la relaxation des excitons auto-piégés / Local refractive index changes (RIC) are the building blocks of laser-induced optical functions in bulk transparent materials, where the use of a fused silica as a target material plays a paramount role. Depending on the regime of laser interaction ultra-short pulses can induce positive isotropic refractive index changes (usually denoted as type I) or produce self-arranged nano-scale layered structures resulting in form birefringence (type II). In this thesis we have studied two objectives related to these material transformations. From the one side, we qualitatively determined the effects of the focused ultra-short laser pulses on the fused silica and borosilicate glasses. With the independent control of the energetic dose, pulse duration and focusing conditions, the isotropic type I and birefringent type II traces could be performed with the certain optical properties. Finally, complex polarization sensitive devices were designed and fabricated. From the other side, as these types of RIC have consequences in the functionality and the performances of 3D embedded optical devices, an investigation of the laser-induced structures is particularly useful. We applied photoluminescence and Raman microscopy (RM) to investigate defect formation and glass network reorganization paths. The proposed spectroscopy study distinguishes type I and type II regions by presence and distribution of silicon clusters and non-bridging oxygen hole centers (NBOHC). RM reveals signs of compaction of the glass network in the RIC regions. At the same time, zones with high concentration of NBOHC where no visible RIC and densification signs were detected. Assuming that these zones are precursors of permanent visible modification, we propose a scenario of cold defect-assisted densification realized in type I irradiation regime. This, thereby, revises the densification paths in fused silica Microstructuration Laser femtoseconde Silice Verre borosilicate Spectroscopie Dispositifs optiques Femtosecond laser Silica Borosilicate glass Spectroscopy Optical devices
23	The Analysis, Simulations, and Applications of the Structure of the Nonlinear Waveguide Lin, Jyh-Shiuan 10 July 2002 (has links) In this paper, we used the beam propagation method to analyze the characteristics of nonlinear optical waveguides. Refractive indexes of media in planar optical waveguides are changed with the electric field intensity called nonlinear planar optical waveguides. We use the modal theory to solve the three-layer planar optical waveguide with the guiding film is nonlinear. We not only obtained dispersion relation curves, but also observed the affections of the input power to field distributions. By the basic theory of this, we proposed a novel method to analyze multi-layer planar optical waveguides with nonlinear or localized nonlinear guiding films.By the theory and novel method we pointed out, on the other hand, we proposed an all-optical switch and analyze the all-optical device by the beam propagation method. Milti-branch Planar Optical Waveguides All-optical Devices Multi-layer Planar Optical Waveguides Nonlinear Optical Waveguide Beam Propagation Method
24	Ultrafast laser-induced modification of optical glasses : a spectroscopy insight into the microscopic mechanisms Mishchik, Konstantin 12 July 2012 (has links) (PDF) Local refractive index changes (RIC) are the building blocks of laser-induced optical functions in bulk transparent materials, where the use of a fused silica as a target material plays a paramount role. Depending on the regime of laser interaction ultra-short pulses can induce positive isotropic refractive index changes (usually denoted as type I) or produce self-arranged nano-scale layered structures resulting in form birefringence (type II). In this thesis we have studied two objectives related to these material transformations. From the one side, we qualitatively determined the effects of the focused ultra-short laser pulses on the fused silica and borosilicate glasses. With the independent control of the energetic dose, pulse duration and focusing conditions, the isotropic type I and birefringent type II traces could be performed with the certain optical properties. Finally, complex polarization sensitive devices were designed and fabricated. From the other side, as these types of RIC have consequences in the functionality and the performances of 3D embedded optical devices, an investigation of the laser-induced structures is particularly useful. We applied photoluminescence and Raman microscopy (RM) to investigate defect formation and glass network reorganization paths. The proposed spectroscopy study distinguishes type I and type II regions by presence and distribution of silicon clusters and non-bridging oxygen hole centers (NBOHC). RM reveals signs of compaction of the glass network in the RIC regions. At the same time, zones with high concentration of NBOHC where no visible RIC and densification signs were detected. Assuming that these zones are precursors of permanent visible modification, we propose a scenario of cold defect-assisted densification realized in type I irradiation regime. This, thereby, revises the densification paths in fused silica Femtosecond laser Silica Borosilicate glass Spectroscopy Optical devices
25	A Novel Approach to Label-Free Biosensors Based on Photonic Bandgap Structures García Castelló, Javier 07 February 2014 (has links) The necessity of using extremely high sensitivity biosensors in certain research areas has remarkably increased during the last two decades. Optical structures, where light is used to transduce biochemical interactions into optical signals, are a very interesting approach for the development of this type of biosensors. Within optical sensors, photonic integrated architectures are probably the most promising platform to develop novel lab-on-a-chip devices. Such planar structures exhibit an extremely high sensitivity, a significantly reduced footprint and a high multiplexing potential for sensing applications. Furthermore, their compatibility with CMOS processes and materials, such as silicon, opens the route to mass production, thus reducing drastically the cost of the final devices. Optical sensors achieve their specificity and label-free operation by means of a proper chemical functionalization of their surfaces. The selective attachment of the receptors allows the detection of the target analytes within a complex matrix. This PhD Thesis is focused on the development of label-free photonic integrated sensors in which the detection is based on the interaction of the target analytes with the evanescent field that travels along the structures. Herein, we studied several photonic structures for sensing purposes, such as photonic crystals and ring resonators. Photonic crystals, where their periodicity provokes the appearance of multiple back and forth reflections, exhibits the so-called slow-light phenomenon that allows an increase of the interaction between the light and the target matter. On the other hand, the circulating nature of the resonant modes in a ring resonator offers a multiple interaction with the matter near the structure, providing a longer effective length. We have also proposed a novel approach for the interrogation of photonic bandgap sensing structures where simply the output power needs to measured, contrary to current approaches based on the spectral interrogation of the photonic structures. This novel technique consists on measuring the overlap between a broadband source and the band edge from a SOI-based corrugated waveguide, so that we can determine indirectly its spectral position in real-time. Since there is no need to employ tunable equipment, we obtain a lighter, simpler and a cost-effective platform, as well as a real-time observation of the molecular interactions. The experimental demonstration with antibody detection measurements has shown the potential of this technique for sensing purposes / García Castelló, J. (2014). A Novel Approach to Label-Free Biosensors Based on Photonic Bandgap Structures [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/35398 / TESIS Biosensor Photonics Photonic crystal waveguides Ring resonators Corrugated waveguides Integrated optical devices Silico TEORIA DE LA SEÑAL Y COMUNICACIONES
26	Development of new photonic devices based on barium titanate in silicon Castera Molada, Pau 01 September 2017 (has links) Integration of complex optical functionalities with high performance will lead to a huge development in the field of nanophotonics for a broad range of applications. Silicon photonics is currently the leading technology for the implementation of low-cost photonic integrated devices. The great potential of this technology relies on its compatibility with the mature silicon integrated circuits manufacturing based on complementary metal-oxide semiconductor (CMOS) processes widely used in microelectronic industry and the availability of high quality silicon-on-insulator wafers, an ideal platform for creating planar waveguide circuits that offers strong optical confinement due to the high index contrast between silicon (n=3.45) and silicon dioxide (n=1.45). In order to keep improving the performance of photonic devices on silicon, the integration of CMOS compatible materials with unique properties shows up as an excellent opportunity to overcome the current limitations in silicon while offering unprecedented and novel capabilities to the silicon platform. In this way, barium titantate (BaTiO3) stands out as one of the most disruptive candidates. The work developed in this thesis is essentially focused on the design, fabrication and characterization of an electro-optic modulator based on a hybrid BaTiO3 on silicon structure for the implementation of high performance electro-optic functionalities with beyond state-of-the art performance that currently cannot be afforded in silicon photonics technology. / La integración de funcionalidades ópticas con alto rendimiento llevará a un gran desarrollo en el campo de la nanofotónica para un amplio abanico de aplicaciones. Actualmente, la fotónica de silicio es la tecnología líder para la implementación de dispositivos fotónicos integrados a bajo coste. El gran potencial de esta tecnología reside en su compatibilidad con las maduras técnicas de fabricación de circuitos integrados de silicio basadas en los procesos "complementary metal-oxide semiconductor" (CMOS) ampliamente utilizados en la industria microelectrónica y la disponibilidad de disponer de obleas de silicio sobre aislante de alta calidad, una plataforma ideal para crear circuitos de guía de ondas planas que ofrecen un fuerte confinamiento óptico debido al alto contraste índices entre el silicio (n=3,45) y el dióxido de silicio (n=1,45). Para poder mejorar el rendimiento de dispositivos fotónicos en silicio, la integración de materiales con propiedades excepcionales y compatibles con los procesos de fabricación CMOS surge como una excelente oportunidad para superar las actuales limitaciones de la tecnología de silicio al mismo tiempo que ofrece oportunidades novedosas y sin precedentes en la plataforma de silicio. En este sentido, el material titanato de bario (BaTiO3) se postula como uno de los candidatos más prometedores. El trabajo desarrollado en esta tesis está esencialmente enfocado en el diseño, fabricación y caracterización de un modulador electro-óptico basado en una estructura híbrida de BaTiO3 en silicio para la implementación de funcionalidades electro-ópticas de alto rendimiento más allá del estado del arte de las que no se puede disponer actualmente en la tecnología de fotónica de silicio. / La integració de funcionalitats òptiques amb alt rendiment portarà a un gran desenvolupament en el camp de la nanofotònica per a un ampli ventall d'aplicacions. Actualment, la fotònica de silici és la tecnologia capdavantera per a la implementació de dispositius fotònics integrats a baix cost. El gran potencial d'aquesta tecnologia resideix en la seva compatibilitat amb les madures tècniques de fabricació de circuits integrats de silici basades en els processos "complementary metal-oxide semiconductor" (CMOS) amplament utilitzats en la indústria microelectrònica i la disponibilitat de disposar d'hòsties de silici sobre aïllant d'alta qualitat, una plataforma ideal per crear circuits de guia d'ones planes que ofereixen un fort confinament òptic a causa de l'alt contrast d'índexs entre el silici (n=3,45) i el diòxid de silici (n=1,45). Per poder millorar el rendiment de dispositius fotònics en silici, la integració de materials amb propietats excepcionals i compatibles amb els processos de fabricació CMOS sorgeix com una excel·lent oportunitat per superar les actuals limitacions de la tecnologia de silici al mateix temps que ofereix oportunitats noves i sense precedents en la plataforma de silici. En aquest sentit, el material titanat de bari (BaTiO3) es postula com un dels candidats més prometedors. El treball desenvolupat en aquesta tesi està essencialment enfocat en el disseny, fabricació i caracterització d'un modulador electro-òptic basat en una estructura híbrida de BaTiO3 en silici per a la implementació de funcionalitats electro-òptiques d'alt rendiment més enllà de l'estat de l'art de les quals no es pot disposar actualment a la tecnologia de fotònica de silici. / Castera Molada, P. (2017). Development of new photonic devices based on barium titanate in silicon [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/86197 / TESIS Photonic integrated circuits Integrated optics devices Electro-optical devices Barium titanate Waveguide modulators Modulators, Ferroelectrics TEORIA DE LA SEÑAL Y COMUNICACIONES
27	Active Silicon Photonic Devices Based on Degenerate Band Edge Resonances Wood, Michael G. January 2016 (has links) No description available. Electrical Engineering Integrated optics Silicon photonics Optical resonators Electro-optical devices Photonic crystals Degenerate band edge resonators
28	Angle of Arrival Estimation Using Spectral Interferometry and a Photonic Link Andrew J Putlock (18436287) 29 April 2024 (has links) <p dir="ltr">Accurately locating a radio-frequency (RF) emitter is imperative in the defense sector, and passive direction finding systems are intriguing due to relatively low cost. This approach involves using the time difference between a signal’s impact at equispaced antennas to determine the location of the emitter, a particular challenge for wideband waveforms operating near the noise floor. Microwave photonic systems have been demonstrated for passive direction finding. These techniques possessed drawbacks, such as reliance on the incoming signal’s bandwidth, dependence on laser power, or the inability to recover an angle from wideband pulses. This thesis presents a novel approach to passive direction finding by translating the methods of spectral interferometry from the optical domain to RF. Spectral interferometry involves interfering a time-delayed reference pulse with a “signal” pulse that has passed through an unknown system. By removing the spectral phase of the reference pulse from the resulting interferogram, the spectral phase of the uncharacterized system is recovered. This enables direction-finding for many waveforms, including the wideband low peak power chirps frequently used in radar. Incorporating an analog optical delay line into both a hard-wired RF interferometer and a two-element antenna array demonstrated spectral interferometric processing of chirped signals with up to 1 GHz instantaneous bandwidth. The technique extracted accurate delays and angles to within 2$\degree$ throughout testing. This approach only requires the imposed delay be longer than the autocorrelation of the bandwidth limited pulses. With additional backend processing, this method could simultaneously determine the angle and classify the incoming signal.</p> Radio frequency engineering Photonics Spectral Interferometry Angle of Arrival Estimation RF Direction Finding
29	Modelagem de dispositivos ópticos em escala nanométrica / Modeling of optical devices in nano scale Diniz, Lorena Orsoni 06 October 2010 (has links) Dispositivos fotônicos têm estado continuamente no foco das pesquisas científicas, particularmente em aplicações para comunicações ópticas e sensoriamento. Por outro lado, as dimensões desses dispositivos são restringidas pelo limite de difração de Abbe. Esse limite tem se mostrado como o grande gargalo no desenvolvimento de novas tecnologias em microscopia óptica, litografia de projeção óptica, óptica integrada, e armazenamento óptico de dados, por limitar as dimensões e a capacidade de integração destes dispositivos. Felizmente, a \"plasmônica\" surgiu como um novo campo de estudo, possibilitando a superação dessa limitação por meio da propagação da luz em modos de plasmon-poláritons de superfície - SPP (Surface Plasmon Polariton). De maneira simplificada, SPPs são campos eletromagnéticos confinados em regiões menores que o comprimento de onda da luz. A geração de SPP ocorre por meio da excitação coletiva de elétrons na interface entre dois meios, metal-dielétrico, que se acoplam com a onda eletromagnética incidente. Pesquisadores logo perceberam que guias de onda baseados em SPP poderiam transportar a mesma banda de informação que um dispositivo fotônico convencional e serem tão localizados quanto dispositivos eletrônicos (elétrons têm maior capacidade de confinamento que fótons). Dessa maneira, alterando a estrutura da superfície de um metal, as propriedades dos SPPs - em particular sua interação com a luz - podem ser manipuladas, oferecendo potencial para o desenvolvimento de novos tipos de dispositivos fotônicos. Com isso, nanoestruturas capazes de guiar, dividir ou mesmo sintonizar a luz tornaram-se realidade. No presente trabalho, o fenômeno de geração de SPPs é estudado teoricamente e aplicado na modelagem de diversas estruturas de interesse científico e tecnológico, tais como filtros de cavidade ressonante e ressoadores em anel. O objetivo principal é a obtenção de estruturas capazes de filtrar ou sintonizar comprimentos de onda, minimizando as perdas ao máximo. Com isso, espera-se estender e explorar ainda mais o leque de possíveis aplicações. / Photonic devices have continuously been in the focus of scientific research, particularly for optical communications and sensing applications. On the other hand, the dimensions of these devices are well known to be limited by the Abbe\'s diffraction limit. This limit has been the major bottleneck in developing new technologies in optical microscopy, lithography projection optics, integrated optics, and optical data storage, as it limits the size and ability to integrate these devices. Fortunately, the field of \"Plasmonics\" has emerged and devices whose dimensions overcome the difraction limit have now become reality. This is possible with the propagation of light in the form of Surface Plasmon Polariton - SPP that, in a simplified way, is an electromagnetic field confined in regions smaller than the wavelength of light. SPP occurs via collective excitation of electrons at the interface between two media, metal-dielectric, as a result of the coupling with an incident electromagnetic wave. Researchers soon realized that waveguides based on SPP could carry the same band of information as that of a conventional photonic device and yet be as localized as electronic devices (electrons have a greater capacity for confinement than photons). Thus, changing the structure of the surface of a metal, the properties of SPPs - in particular its interaction with light - can be manipulated, offering potential for the development of new types of photonic devices. Thus, nanostructures capable of transferring, guiding, splitting, or even tuning the light have now become reality. In this work, the phenomenon of generation of SPPs is theoretically investigated and applied to various structures of scientific and technological interest, such as filters and cavity resonators. The main objective is to obtain structures that are able to filter or tune wavelengths, minimizing losses as much as possible. As a result, we expect to extend and explore even further the range of possible applications. Dispositivos ópticos Filter ring resonant Filtro de anel ressonante Filtro de cavidade ressonante Guia de onda Optical devices Plasmon poláriton de superfície Plasmon surface polariton Resonant cavity filter SPP SPP Waveguide
30	Polarímetro diferencial baseado na reflexão interna / Differential polarimeter based on internal reflection Oliveira, Anderson Roberto de 11 November 2016 (has links) Neste trabalho apresentamos uma nova técnica para a medida da rotação da polarização da luz por uma substância que possui atividade óptica. O sistema utiliza um LED, dois polarizadores, um prisma de vidro semicilíndrico, uma cubeta, uma CCD e um computador para análise de dados. Luz proveniente do LED passa pelo primeiro polarizador, cujo eixo de transmissão se encontra a 45°, e incide no prisma pelo lado semicilíndrico, ocorrendo reflexão na sua base, num ângulo próximo do ângulo crítico. Devido ao tamanho finito do feixe e o formato curvo da superfície do prisma, vários ângulos de incidência são observados na base da lente semicilíndrica. A luz refletida passa então pela cubeta e depois por um analisador, cujo eixo se encontra paralelo ao primeiro polarizador, e então o sinal é captado pela CCD. De forma alternativa, a cubeta pode ser posicionada após o primeiro polarizador, antes do prisma. Quando a cubeta é preenchida com água, observa-se na CCD uma interferência destrutiva exatamente no ângulo crítico caracterizado por um mínimo de intensidade nesse ângulo. Se uma substância opticamente ativa é utilizada para preencher a cubeta, a posição desse mínimo é alterada dependendo do ângulo de rotação da polarização imposto pela substância. Uma calibração é necessária e pode ser feita utilizando-se soluções de concentração conhecida de sacarose ou frutose, por exemplo. O aparato obtido foi utilizado para medir a rotação causada por uma amostra normal (0,26 g/ml) de soluções de sacarose e frutose e apresenta uma precisão de 0,04°. Equivalentemente, a precisão em concentração é de 0,001 g/ml ou aproximadamente 0,1% (m/m). Isso corresponde a uma precisão que é uma ordem de grandeza acima dos aparelhos comerciais e técnicas mais comuns utilizadas atualmente. Em contrapartida, o custo da montagem experimental é duas ordens de grandeza menor que os mesmos aparelhos comerciais. A produção de uma gama de ângulos de incidência devido à focalização na superfície cilíndrica do prisma substitui a necessidade de se produzir rotação no eixo de polarização do analisador após a passagem da luz pela amostra opticamente ativa, como ocorre em alguns aparelhos comercializados. Este dispositivo, por ser de baixo custo, compacto e de fácil manuseio, é de grande importância porque pode ser utilizado na indústria sucroalcooleira para a medida da quantidade de sacarose em cana e também na indústria farmacêutica para a identificação de substâncias opticamente ativas dextrogiras ou levógiras. / In this thesis we present a novel technique for measuring light polarization rotation caused by an optically active substance. The system is composed by a LED, two polarizers, a semi cylindrical glass prism, a cuvette, a linear CCD camera and a computer for data analysis. Light from the LED passes through the first polarizer, whose transmission axis is set at 45°. After that, the linear polarized light enters the prism by the semi cylindrical face, occurring reflection in the flat face at critical angle approximately. Several incidence angles are accessed due to the beams finite size and the shape of the semi cylindrical lens. The reflected light passes through the cuvette and then through the analyzer, whose transmission axis is set parallel to the first polarizer. Finally, the light is detected by the CCD. When the cuvette is filled up with water, a destructive interference at the critical angle is observed, characterized by a narrow valley centered at this angle. If the cuvette is filled up with an optically active substance, the center of this valley is shifted depending on the substance, its concentration and the optical path travelled by the light in the substance. A calibration is needed and is performed using a set of solutions of known concentrations. Our apparatus was used to measure the angle rotation caused by a normal solution (0,26 g/ml) of sucrose and fructose solutions and has a precision of 0,04°. It corresponds to a precision that is one order of magnitude above most used commercial apparatus and developed techniques. In contrast, the cost of our experimental setup is two orders of magnitude less than the same commercial devices. The production of a range of angles of incidence due to focusing on the cylindrical surface of the prism replaces the need of producing a rotation of the analyzer polarization axis after the light passes through the optically active sample, as it happens in some commercial devices. Since this device has a low cost, is compact and easy to handle, it may be of great importance for applications in the pharmaceutical industry to identify enantiomers, and in the sugar industry for measuring sugar content in sugar cane juice. Ângulo crítico Critical angle Dispositivos ópticos Optical active substances Optical devices Polarimetria Polarimetry Reflexão total interna Substâncias opticamente ativas Total internal reflection

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