Global ETD Search

241	Surface Modification of Multimaterial Multifunctional Fibers Enabling Biosensing Applications Lopez Marcano, Ana Graciela 27 June 2018 (has links) During the last decades, the continuing need for faster and smaller sensors has indeed triggered the rapid growth of more sophisticated technologies. This has led to the development of new optical-based sensors, able to detect and measure different phenomena using light. Furthermore, material processing technologies and micro fabrication methods have exponentially advanced, allowing engineers and scientists to develop new and more complex sensors on optical fibers platforms; specifically attractive for life science and biomedical research. All these substantial developments have brought biosensors to a point where multifunctionality is needed, this has led to envision the "Lab-on-Fiber" concept. Which promotes the integration of different sensing components into a single platform, an optical fiber. In this work, an integrated system with non-conventional polymer optical fibers and their further surface modification has been developed. With these different approaches, electrodes, hollow channels and plasmonic nanostructures can be incorporated into a single optical fiber-based sensor, allowing for both electrical and optical sensing with the capabilities of tuning and signal enhancement thanks to the metallic nanostructures. Different fiber substrates can be designed and modified in order to satisfy multiple requirements for a wide variety of applications. / MS / Silica optical fibers have been used since the 1960’s to guide optical signals, such as light, with low losses through long distances; making them an attractive platform to use in large communication systems. However, over the past couple of decades researchers have been trying to implement these low-loss platforms in sensing devices for many different fields, such as environmental and structural monitoring, and chemical and biomedical research. Unfortunately, their high brittleness has prompted researchers to introduce different materials in the same technology, leveraging the development of multimaterial non-conventional fibers. Where different polymers and even metals have replaced silica as the structural material, making these fibers more cost-affordable, flexible, and allow for multi-sensing capabilities of both electrical and optical signals. Although these multimaterial fibers are able to transmit light, they need to be functionalized or modified in order for them to be able to sense different phenomena occurring in their surrounding media. This can be achieved by integrating small particles or structures onto the fibers end-faces, these small structures are known as plasmonic nanostructures. When light (electromagnetic radiation) travels through a fiber and interacts with the free (conduction) electrons of a metallic nanostructure, it leads to a coupling that results in collective oscillations, which produce strong enhancement of the local electromagnetic fields surrounding the nanostructures. The latter can be easily detected with the help of an optical spectrum analyzer that iv stores the transmitted light as a function of the transmitted wavelength. Noble metals like gold and silver produce unprecedented electromagnetic field enhancements and are also biocompatible, making them very attractive in biosensing applications. In this research metallic plasmonic nanostructures were deposited on the end face of multimaterial polymer fibers to enhance the optical properties and potentially the electrical properties as well, creating new sensing devices. The enhancement produced by these structures was studied with both experimental measurements and theoretical simulations. The results demonstrate that the nanostructures investigated in this work can indeed enhance the optical properties of the used polymer fibers, enabling them to work as sensing probes for a many different applications, especially biosensing research. Surface Modification Plasmonics Multifunctional Fibers Soft Lithography Refractive Index Raman Spectroscopy
242	Étude du confinement acoustique dans des nano-structures métalliques et semiconductrices par diffusion Raman basse fréquence / Acoustic confinement in metallic and semiconducting nanostructures studied by low frequency Raman spectroscopy Girard, Adrien 11 July 2016 (has links) Les spectroscopies de diffusion inélastique de la lumière (Raman/Brillouin) sont un outil versatile qui permet d'étudier les phonons thermiques de la matière à différentes échelles. Dans les milieux nano-granulaires, l'étude des phonons acoustiques dont la longueur d'onde est grande devant le diamètre D des grains (?/D >> 1) permet de caractériser l'élasticité macroscopique gouvernée par la loi du contact de Hertz. La validité de la loi de contact est étudiée pour des poudres d'oxyde constituées de nanoparticules sphériques d'une taille de quelques nanomètres. Lorsque la demi-longueur d'onde des phonons acoustiques devient égale à la dimension du confinement (diamètre D pour les sphères, épaisseur e pour une plaquette), la propagation n'est plus possible et un phénomène de résonance mécanique apparaît. La spectroscopie Raman basse fréquence a été utilisée pour caractériser les modes de vibration acoustique de nanoplaquettes semiconductrices habillées d'un « manteau » organique. Lorsque l'épaisseur est suffisamment faible (e ~1 nm) une forte déviation de la fréquence de résonance est observée par rapport au modèle de la plaquette libre, attribuée à la présence des molécules organiques et est interprétée par un effet nano-balance. Lorsque l'objet confinant est un nano-dimère métallique, une hybridation plasmonique et acoustique des nanoparticules ont lieu conjointement. L'excitation résonante du plasmon dimèrique permet d'observer à l'échelle d'un dimère unique la diffusion par les modes de vibration dipolaire hybridé l=1 ainsi que les modes non hybridés de moment angulaire l >2, interdits par les règles de sélection précédemment établies pour ce régime de taille / Inelastic light scattering spectroscopies (Raman/Brillouin) are a versatile tool to study thermal phonons at various scales. In nano-granular media, the study of acoustic phonons with a wavelength much greater than the grain diameter D (?/D >> 1) allows one to characterize the macroscopic elasticity governed by Hertz law of the contact. The validity of Hertz law is studied for powders made of oxide nanoparticles a few nanometers in diameter. When the phonon half-wavelength reaches the confinement dimension (diameter D for spheres, thickness e for plates) propagation is forbidden and mechanical resonances occur. Low frequency Raman spectroscopy has been used to characterize the acoustic resonances of semiconducting nanoplatelets “dressed” with an organic surfactant layer. When the thickness becomes thin enough (e ~ 1 nm), the resonance frequency is significantly downshifted compared to a free platelet, attributed to a mass load effect due to the organic molecules. When the confining object is a metallic nano-dimer, both plasmonic and acoustic hybridization occur at the same time. The resonant excitation of the dimeric plasmon allows one to observe down to single nano-object scale the inelastic scattering by dimer hybridized dipolar vibration modes l=1 as well as non-hybridized modes with higher angular momentum l >2, known to be Raman inactive in this size range according to previously established selection rules. Possibilities for a new plasmon-vibration coupling mechanism are discussed Nanoparticule unique Vibration acoustique Confinement acoustique Plasmon-phonon coupling Plasmonics Nanoplaquette semiconductrices Nanobalance Nanoparticules d'oxydes Single nanoparticle Acoustic vibration Acoustic confinement Plasmon-phonon coupling Plasmonics Semiconducting nanoplatelets Nanobalance Oxide nanoparticles 534
243	Label-free plasmonic detection using nanogratings fabricated by laser interference lithography Hong, Koh Yiin 02 January 2017 (has links) Plasmonics techniques, such as surface plasmon resonance (SPR) and surface-enhanced Raman scattering (SERS), have been widely used for chemical and biochemical sensing applications. One approach to excite surface plasmons is through the coupling of light into metallic grating nanostructures. Those grating nanostructures can be fabricated using state-of-the-art nanofabrication methods. Laser interference lithography (LIL) is one of those methods that allow the rapid fabrication of nanostructures with a high-throughput. In this thesis, LIL was combined with other microfabrication techniques, such as photolithography and template stripping, to fabricate different types of plasmonic sensors. Firstly, template stripping was applied to transfer LIL-fabricated patterns of one-dimensional nanogratings onto planar supports (e.g., glass slides and plane-cut optical fiber tips). A thin adhesive layer of epoxy resin was used to facilitate the transfer. The UV-Vis spectroscopic response of the nanogratings supported on glass slides demonstrated a strong dependency on the polarization of the incident light. The bulk refractive index sensitivities of the glass-supported nanogratings were dependent on the type of metal (Ag or Au) and the thickness of the metal film. The described methodology provided an efficient low-cost fabrication alternative to produce metallic nanostructures for plasmonic chemical sensing applications. Secondly, we demonstrated a versatile procedure (LIL either alone or combined with traditional laser photolithography) to prepare both large area (i.e. one inch2) and microarrays (μarrays) of metallic gratings structures capable of supporting SPR excitation (and SERS). The fabrication procedure was simple, high-throughput, and reproducible, with less than 5 % array-to-array variations in geometrical properties. The nanostructured gold μarrays were integrated on a chip for SERS detection of ppm-level of 8-quinolinol, an emerging water-borne pharmaceutical contaminant. Lastly, the LIL-fabricated large area nanogratings have been applied for SERS detection of the mixtures of quinolone antibiotics, enrofloxacin, an approved veterinary antibiotic, and one of its active metabolite, ciprofloxacin. The quantification of these analytes (enrofloxacin and ciprofloxacin) in aqueous mixtures were achieved by employing chemometric analysis. The limit of quantification of the method described in this work is in the ppm-level, with <10 % SERS spatial variation. Isotope-edited internal calibration method was attempted to improve the accuracy and reproducibility of the SERS methodology. / Graduate / 2018-02-17 Plasmonics Nanogratings Surface enhanced Raman scattering (SERS) Surface plasmon resonance (SPR) Template stripping Microarrays Environmental detection Quinolones
244	Modélisation multi-échelle de systèmes nanophotoniques et plasmoniques / Multi-scale modelling of nanophotonic and plasmonic systems Fall, Mandiaye 06 December 2013 (has links) Les structures nanophotoniques sont généralement simulées par des méthodes de volumes, comme la méthode des différences finies dans le domaine temporel (FDTD), ou la méthode des éléments finis (FEM). Toutefois, pour les grandes structures, ou des structures plasmoniques métalliques qui nécessitent, la mémoire et le temps de calcul requis peuvent augmenter de façon spectaculaire.Les méthodes de surface, comme la méthode des éléments de frontière (BEM) ont été développées afin de réduire le nombre d'éléments de maillage. Ces méthodes consistent à exprimer le champ formé dans tout l'espace en fonction des courants électrique et magnétique à la surface de l’objet. Combinées avec la méthode multipôle rapide (FMM) qui permet une accélération du calcul de l'interaction entre les éléments lointain du maillage, de grands systèmes peuvent ainsi être manipulés.Nous avons développé, pour la première fois à notre connaissance, une FMM sur un nouveau formalisme BEM, basé sur les potentiels scalaire et vectoriel au lieu de courants électriques et magnétiques. Cette méthode a été montrée pour permettre une simulation précise des systèmes plasmoniques métalliques, tout en offrant une réduction significative des besoins de calcul. Des systèmes nanophotoniques complexes ont été simulés, comme une lentille plasmonique composé d'un ensemble de nanotubes d'or. / Nanophotonic structures are generally simulated by volume methods, as Finite-difference time-domain (FDTD) method, or Finite element method (FEM). However, for large structures, or metallic plasmonic structures, the memory and time computation required can increase dramatically, and make proper simulation infeasible.Surface methods, like the boundary element method (BEM) have been developed to reduce the number of mesh elements. These methods consist in expressing the electromagnetic filed in whole space as a function of electric and magnetic currents at the surface of scatterers. Combined with the fast multipole method (FMM) that enables a huge acceleration of the calculation of interaction between far mesh elements, very large systems can thus be handled.What we performed is the development of an FMM on a new BEM formalism, based on scalar and vector potentials instead of electric and magnetic currents, for the first time to our knowledge. This method was shown to enable accurate simulation of metallic plasmonic systems, while providing a significant reduction of computation requirements, compared to BEM-alone. Several thousands of unknowns could be handled on a standard computer. More complex nanophotonic systems have been simulated, such as a plasmonic lens consisting of a collection of gold nanorods. Mathématiques Appliquées Analyse Numérique Méthode numérique en physique Electromagnétique Plasmonique Nanophotonique Applied Mathematics Numerical Analysis Numerical Method in Physics Electromagnetics Plasmonics Nanophotonics
245	Plasmonic Metasurfaces Utilizing Emerging Material Platforms Krishnakali Chaudhuri (6787016) 02 August 2019 (has links) <p>Metasurfaces are broadly defined as artificially engineered material interfaces that have the ability to determinately control the amplitude and phase signatures of an incident electromagnetic wave. Subwavelength sized optical scatterers employed at the planar interface of two media, introduce abrupt modifications to impinged light characteristics. Arbitrary engineering of the optical interactions and the arrangement of the scatterers on plane, enable ultra-compact, miniaturized optical systems with a wide array of applications (e.g. nanoscale and nonlinear optics, sensing, detection, energy harvesting, information processing and so on) realizable by the metasurfaces. However, maturation from the laboratory to industry scale realistic systems remain largely elusive despite the expanding reach and vast domains of functionalities demonstrated by researchers. A large part of this multi-faceted problem stems from the practical constraints posed by the commonly used plasmonic materials that limit their applicability in devices requiring high temperature stability, robustness in varying ambient, mechanical durability, stable growth into nanoscale films, CMOS process compatibility, stable bio-compatibility, and so on. </p> <p>Aiming to create a whole-some solution, my research has focused on developing novel, high-performance, functional plasmonic metasurface devices that utilize the inherent benefits of various emerging and alternative material platforms. Among these, the two-dimensional MXenes and the refractory transition metal nitrides are of particular importance. By exploiting the plasmonic response of thin films of the titanium carbide MXene (Ti<sub>3</sub>C<sub>2</sub>T<sub>x</sub>) in the near infrared spectral window, a highly broadband metamaterial absorber has been designed, fabricated and experimentally demonstrated. In another work, high efficiency photonic spin Hall Effect has been experimentally realized in robust phase gradient metasurface devices based on two different refractory transition metal nitrides –titanium nitride (TiN) and zirconium nitride (ZrN). Further, taking advantage of the refractory nature of these plasmonic nitrides, a metasurface based temperature sensor has been developed that is capable of remote, optical sensing of very high temperatures ranging up to 1200<sup>o</sup>C.</p> Optical Physics not elsewhere classified Nanophotonics plasmonics metasurfaces nanophotonics MXene Transiton metal nitrides metamaterials
246	Caractérisation de la chiralité optique dans des systèmes plasmoniques / Characterization of optical chirality effects in plasmonic systems Pham, Kim Anh Aline 06 November 2018 (has links) L'objectif de ce projet de thèse est de mettre en évidence des phénomènes de chiralité optique induits dans des systèmes plasmoniques. La manipulation des différents degrés de liberté de la lumière est mise en évidence par le biais de techniques expérimentales complémentaires basées sur la tomographie en polarisation, la microscopie à fuites radiatives et la microscopie en champ proche optique (SNOM). D'une part, nous rapportons une méthode de caractérisation non-invasive afin de révéler la présence conjointe de chiralité planaire et volumique au sein de métasurfaces plasmoniques. Pour décrire cette chiralité mixte, une généralisation du modèle de Kuhn est développée. D'autre part, nous démontrons deux dispositifs plasmoniques exploitant le couplage spin-orbite optique pour contrôler les moments angulaires de spin et orbitaux de la lumière. En particulier, le mécanisme réciproque de l'effet spin Hall optique est démontré à l'aide de nano-ouvertures en forme de T: la trajectoire des plasmons de surface est adressée dans le moment angulaire de spin des photons. Cette fonctionnalité est ensuite mise en œuvre dans une expérience de brouillage d'interférence. La génération de vortex plasmoniques est également réalisée par le biais de cavités spirales, dont la chiralité conditionne l'intensité et le moment angulaire orbital des vortex. Enfin, une preuve de concept sur la mesure de la densité locale d’états optique, façonnée par un environnement chiral, est démontrée à l'aide d'une sonde SNOM classique et quantique. Ce travail permet de connecter les grandeurs de densité et de flux de chiralité aux interactions lumière-matière. L'étude de la chiralité dans le contexte de la plasmonique ouvre des perspectives prometteuses dans la nano-manipulation optique, la séparation de molécules chirales et le contrôle de sources quantiques. / In this thesis, we aim at demonstrating chiral optical effects in plasmonic systems. The manipulation of the different degrees of freedom of light is evidenced by complementary experimental approaches based on polarisation tomography, leakage radiation microscopy and scanning near-field optical microscopy (SNOM). On one hand, we report on a non-invasive method to reveal the coexistence of surface and bulk chirality in plasmonic metasurfaces. Specifically, we extend the model of Kuhn to describe this chirality mixture. On the other hand, we demonstrate two plasmonic devices which rely on the optical spin-orbit coupling to control the spin and the orbital angular momentum of light. In particular, the reciprocal mechanism of the spin-Hall effect of light is shown using T-shaped nano-apertures: the trajectory of surface plasmons can be encoded in the spin of the photons. This which-path marker is then implemented in an interference erazer experiment. Plasmonic vortex generation is also reported in spiral cavities. The spiral chirality rules the intensity as well as the angular orbital momentum of the singular fields. Finally, as a proof of concept, we demonstrate using a conventional and quantum SNOM probe that the local density of optical states can be structured by a chiral environment. We also connect the density and flux chirality to light-matter interactions. Studying chirality in the context of plasmonics opens promising prospects in the optical nano-manipulation, chiral molecules discrimination and the control of quantum sources. Plasmonique Microscope optique en champ proche Chiralité optique Optique quantique Plasmonics Near-Field optical microscopy Optical chirality Quantum Optics 530
247	Demonstration of the spatial self-trapping of a plasmonic wave / Démonstration de l'autofocalisation d'une onde plasmonique Kuriakose, Tintu 12 July 2018 (has links) Cette thèse est une contribution au domaine de recherche de la plasmonique nonlinéaire, domaine émergent de l'optique. L'objectif principal est de démontrer expérimentalement l'autofocalisation d'une onde plasmonique.L'étude débute avec la fabrication et la caractérisation de guides plans en verre de chalcogénure de composition Ge-Sb-Se. Une technique basée sur la formation de solitons spatiaux est développée afin d’estimer leurs non-linéarités Kerr. Les propriétés optiques linéaires et non linéaires de ces guides sont étudiées aux longueurs d’onde de 1200 nm et 1550 nm.Des structures plasmoniques sont ensuite conçues pour propager des ondes hybrides plasmon-solitons avec des pertes de propagation modérées. Elles sont constituées des guides précédents recouverts de nanocouches de silice et d'or.Les caractérisations optiques par couplage plasmon-soliton révèlent une forte autofocalisation subie par l’onde qui se propage à l'intérieur de la structure plasmonique. Comme prévu par la théorie, le comportement est présent uniquement pour une lumière polarisée TM. Des résultats expérimentaux détaillés de cette autofocalisation exaltée par effet plasmonique sont présentés pour différentes configurations. Des simulations confirment les résultats expérimentaux obtenus.Cette démonstration fondamentale vient confirmer le concept d’autofocalisation assistée par plasmon tout en révélant un effet nonlinéaire très efficace. Cela ouvre de nouvelles perspectives pour le développement de dispositifs photoniques non linéaires intégrés ainsi que de nouveaux phénomènes physiques. / This dissertation contributes to the research area of nonlinear plasmonics an emerging field of optics. The main goal is to demonstrate experimentally the spatial self-trapping of a plasmonic wave.The study begins with the fabrication and the characterization of slab Ge-Sb-Se chalcogenide waveguides. A technique based on the formation of spatial solitons is developed to estimate their Kerr nonlinearities. Linear and nonlinear optical properties of the waveguides are studied at the wavelengths of 1200 nm and 1550 nm.Plasmonic structures are then designed to propagate hybrid plasmon-soliton waves with moderate propagation losses. They are constituted of the previous waveguides covered with nanolayers of silica and gold.Optical characterizations reveal a giant self-focusing undergone by the wave that propagates inside the plasmonic structure. The behavior is present only for TM polarized light as expected from theory. Detailed experimental results of this plasmon enhanced nonlinear self-trapping corresponding to different configurations are presented. Simulations confirm the obtained experimental results.This fundamental demonstration confirms the concept of plasmon-assisted self-focusing while revealing a very efficient nonlinear effect. This opens new perspectives for the development of integrated nonlinear photonic devices as well as new physical phenomena. Optique nonlinéaire Plasmonique Solitons spatiaux Kerr Guide plan en chalcogénure Nonlinear optics Plasmonics Kerr spatial solitons Planar chalcogenide waveguides 535
248	Exploration of how light interacts with arrays of plasmonic, metallic nanoparticles Humphrey, Alastair Dalziell January 2015 (has links) The content of this thesis is based upon the interaction of light with metallic nanoparticles arranged in different array geometries. An incident electric field (light) can force the conduction electrons of a metallic nanoparticle to oscillate. At particular frequencies, in the optical regime for gold and silver particles, absorption and scattering of the light by the particle is enhanced, corresponding to the particle plasmon resonance. The spectral position and width of the particle plasmon resonance of an isolated single particle may be tuned by adjusting its size and shape, thus changing the surface charge distribution. Periodic arrays of particles offer additional control over the frequency and width of the resonance attributed to the re-radiating (scattering) property of plasmonic particles. By fabricating arrays with a pitch comparable to the wavelength of an isolated single particle plasmon resonance, a coherent interaction between particles may be produced, known as surface lattice resonances (SLRs). The electromagnetic coupling between in-plane particle plasmon modes for different particle array geometries is explored through experiment and theory. Firstly, SLRs in square, hexagonal and honeycomb arrays are investigated by normal-incidence extinction measurements and compared to a simple-coupled dipole model. Secondly, to verify the nature of the coupling between the scattered electric field associated with particle resonances, the incident electric field polarization-dependence of the extinction of rectangular arrays and chains is studied. Thirdly, the optical response of square arrays with a symmetric two-particle basis is investigated, particularly the retardation of the scattered electric field between particles in a pair. Fourthly, square arrays with an asymmetric two-particle basis are fabricated to explore the symmetric (dipole moments of both particles are parallel) and anti-symmetric (dipole moment of both particles anti-parallel) SLRs, excited by normal-incidence light. 530
249	Propriétés optiques de colloïdes assemblés : plasmonique et confinement diélectrique / Optical properties of deterministic colloidal assemblies : plasmonics and dielectric confinement Lecarme, Olivier 20 December 2011 (has links) Les solutions colloïdales constituées de nanoparticules en solution sont une famille d'objets aux propriétés optiques uniques. Leur utilisation comme élement de base à la fabrication de composants optiques sublongueur d'onde pourrait permettre la naissance de nouvelles applications en particulier dans le domaine de l'optique intégrée et de la détection biologique. La manipulation de ces particules reste toutefois un défi en raison de leur taille et de leur dispersion aléatoire dans un milieu liquide. Dans ce contexte, nous avons réalisé des nouveaux composants optiques grâce au développement de techniques de fabrication basées sur la méthode d'assemblage capillaire assisté par convection. Deux types de structures ont été réalisés puis évalués en terme de comportement optique : les dimères métalliques d'Au et les microsphères diélectriques de polystyrène assemblées en chaînes ou en réseaux. Pour les dimères, une étude fondamentale a été effectuée sur les phénomènes plasmoniques régissant les propriétés optiques de ces objets. Leur potentiel en tant que détecteur ultrasensible SERS et nanoantenne à boîtes quantiques a ensuite été approfondi. Pour les microsphères, une étude sur la propagation et la diffusion des modes de galerie présents dans ces objets a tout d'abord été réalisée dans le but d'en faire des candidats pour la détection ultrasensible. Les propriétés de guidage de la lumière dans des assemblages en chaîne ont ensuite été traitées. Afin de compléter ce travail un dernier composant optique a été développé en complément des guides et capteurs colloïdaux déjà réalisés. Il s'agit d'une nouvelle génération d'émetteurs localisés conçus pour un usage large et versatile et qu'il est possible de définir comme microsource de lumière blanche. / Colloids -- e.g. nanoparticles in solution -- are objects that exhibit original optical properties. Their use as building block for fabrication of subwavelength optical components may allow novel applications in the field of integrated optics and biological detection. Anyway colloidal particles handling remains a challenge because of their small size and their random dispersion into a liquid medium. In this context, we created new colloidal optical components thanks to nanofabrication techniques based on the convective assisted capillary force assembly method. Two different kinds of structure were made and their optical behavior was studied: gold colloidal dimers and polystyrene dielectric microspheres assembled as chains or arrays. For the dimers, a fundamental study was performed on plasmonic phenomena that rule the optical properties of these objects. Next, their potential was evaluated in terms of ultrasensitive SERS sensor and also as optical nanoantenna of quantum dot emitters. For the microspheres, the propagation and scattering behaviors of whispering gallery modes that travel into the microspheres were first investigated. Their potential use as ultrasensitive sensors was also discussed. In addition, a second study was made on the guiding properties of linear microspheres chains. In order to complete this work, one last optical component was developped in addition to the fabricated colloidal waveguides and colloidal sensors. This component is a white light microsource that was designed for applications as a versatile localized emitter for integrated optics. Nanofabrication Assemblage par force de capillarité Plasmonique Colloïdes Microsphères Spectroscopie optique Nanofabrication Capillary Force Assembly Plasmonics Colloids Microspheres Optical spectroscopy 530
250	De la génération de somme de fréquence à la fluorescence paramétrique dans des nanostructures plasmoniques hybrides / From SFG to SPDC in hybrid plasmonic nanostructures Chauvet, Nicolas 05 March 2019 (has links) L'optique non-linéaire étudie des phénomènes capables de modifier la fréquence de la lumière incidente en s'appuyant sur la symétrie intrinsèque de certains matériaux. Le défi actuel de la miniaturisation des composants va de paire avec une perte d'efficacité à l'échelle sub-micrométrique. Pour résoudre ce problème, l'idée explorée au cours de cette thèse consiste à utiliser un phénomène d'oscillation collective des électrons libres d'une nanostructure en métal, appelé résonance plasmon de surface localisé. Cet effet est associé à une exaltation du champ au voisinage immédiat d'une structure plasmonique, une propriété adaptée pour augmenter l'efficacité non-linéaire d'un matériau placé non loin. Les objectifs principaux de ma thèse consistaient à fabriquer ces objets hybrides, à développer une plate-forme expérimentale polyvalente capable de réaliser différents types d'observation à l'échelle de la particule unique, puis à analyser leur génération de second harmonique (SHG). Ces travaux ont abouti à l'obtention de structures hybrides non-linéaires efficaces, dont l'intensité SHG atteint jusqu'à 100 fois celle d'une antenne plasmonique isolée et jusqu'à plus de 1000 fois celle d'un nanocristal non-linéaire unique, confirmant l'intérêt de ces structures. Nous avons aussi tenté d'observer de la fluorescence paramétrique (SPDC) dans une nanostructure individuelle, une prouesse encore inachevée dans le monde; si nos études n'ont pas davantage abouti, elles esquissent des pistes d'amélioration pour y parvenir, et un modèle numérique innovant développé dans l'équipe annonce un rendement compatible avec des observations. Enfin, une source de photons intriqués a été développée dans le cadre d'une collaboration sur l'intelligence artificielle dans des systèmes physiques et constitue une perspective envisageable d'application pour les travaux précédents. Ces résultats ouvrent potentiellement la voie à l'amélioration de l'éfficacité et de la fiabilité des algorithmes IA actuels. / Nonlinear optics study phenomena able to modify the frequency of incoming light by using intrinsic symmetry properties of some materials. The current challenge of component miniaturization goes with an efficiency drop at the sub-micrometer scale. To solve this issue, the idea we have explored during my PhD consists in using a collective oscillation phenomenon from free electrons in a metal structure called localized surface plasmon resonance. This effect is indeed linked to an enhancement of the electromagnetic field near a plasmonic structure, a property well suited to increase the nonlinear efficiency of a material placed beside. The main objectives of my PhD consisted in fabricating these hybrid objects, developing a versatile experimental platform able to make different kinds of observations at the single particle level, and finally analyzing their second harmonic generation (SHG). This work has managed to produce efficient nonlinear hybrid structures, whose SHG intensity is up to 100 times that of an isolated plasmonic antenna and up to 1000 times that of a single nonlinear nanocrystal, confirming the potential of this type of structures. We have also tried to detect spontaneous parametric down conversion (SPDC) in a single nanostructure, a never-achieved feat that has yet to be done; although our study wasn't successful, it gives hints to improve experiments, even more since a cutting edge numerical model developed in our team has predicted intensities compatible with observations. Finally, an entangled photon source has been developed in the framework of a collaboration on artificial intelligence in physical systems and is a reachable perspective for potential applications of our work. These results pave the way to improving efficiency and liability of current AI algorithms. Optique non-Linéaire Plasmonique Génération de fréquence somme Génération de second harmonique Fluroescence paramétrique Nonlinear optics Plasmonics SFG SHG SPDC 530

Search results