Global ETD Search

1	Mode-matching method in optical corrugated waveguides with large rectangular groove depth Tsa, Woo-Hu January 1995 (has links) No description available. 535 Integrated optical devices
2	Optical strip waveguides in lithium niobate formed by helium ion implantation Reed, G. T. January 1987 (has links) The implantation of helium ions into lithium niobate produces a reduction in its refractive indices, due to radiation damage produced close to the end of the ion trajectories. This reduction can be utilised to form the boundaries of optical waveguides, which form the basis of any integrated optical circuit. Stripe waveguide fabrication using ion implantation has been demonstrated for the first time in this work. Firstly a buried damage layer was formed to define the depth of the waveguide, followed by additional implants around a gold mask to form the waveguide sidewalls. The gold mask was used to protect the guiding region during the latter implantation process. The waveguides were evaluated using the end-fire coupling technique to excite individual modes. Propagation loss and modal dimensions were determined experimentally for the fundamental mode of each guide, and it was shown that these properties are sensitive to both the ion energy of the wall implants, and the number of wall implants. Each of these two variables affects the propagation loss in the opposite sense to the other, and therefore the lowest propagation loss becomes dependant on the trade off between these two effects. The lowest loss of the waveguides presented in this thesis was found to be ~1 dB/cm, and it is expected that this figure may be further reduced by the optimisation suggested in the conclusions of this work. Additional results are presented which consider the electrooptic and photorefractive properties of ion implanted LiNbO3. Previous work of others suggested that the electrooptic effect would be considerably reduced in the implanted material, but the results were much more encouraging, showing a reduction of only ~20% in the r13 electrooptic coefficient. Furthermore, one of the most serious drawbacks of Ti:indiffused waveguides is the undesirable reduction of the output intensity due to the photorefractive effect, which has been shown not to affect the waveguides presented in this thesis. 530.41 Integrated optical circuit
3	Hybrid Plasmonic Waveguides and Devices: Theory, Modeling and Experimental Demonstration Sun, Xiao 17 July 2013 (has links) This thesis prompt a theoretical analysis of the hybrid plasmonic waveguide (HPWG) and a TE-pass polarizer based on HPWG has been designed, fabricated and characterized. A combination of low propagation loss, high power density, and large confinement is useful for many applications. The analysis results in this thesis show that the HPWG offers a better compromise between loss and confinement as compared to pure plasmonic waveguides. Another interesting property of the HPWG is its polarization diversity. In the HPWG the transverse electric and the transverse magnetic modes reside in different layers. We have designed a very compact hybrid TE-pass polarizer using this property. The polarizer was fabricated and characterized. The device shows low insertion loss for the TE mode with a high extinction ratio at telecommunication wavelength range for a 30 µm long HPWG section. Its performance compares favorably against previously reported silicon based integrated optic TE-pass polarizers. plasmonic waveguide polarizer integrated optical circuit 0544
4	Hybrid Plasmonic Waveguides and Devices: Theory, Modeling and Experimental Demonstration Sun, Xiao 17 July 2013 (has links) This thesis prompt a theoretical analysis of the hybrid plasmonic waveguide (HPWG) and a TE-pass polarizer based on HPWG has been designed, fabricated and characterized. A combination of low propagation loss, high power density, and large confinement is useful for many applications. The analysis results in this thesis show that the HPWG offers a better compromise between loss and confinement as compared to pure plasmonic waveguides. Another interesting property of the HPWG is its polarization diversity. In the HPWG the transverse electric and the transverse magnetic modes reside in different layers. We have designed a very compact hybrid TE-pass polarizer using this property. The polarizer was fabricated and characterized. The device shows low insertion loss for the TE mode with a high extinction ratio at telecommunication wavelength range for a 30 µm long HPWG section. Its performance compares favorably against previously reported silicon based integrated optic TE-pass polarizers. plasmonic waveguide polarizer integrated optical circuit 0544
5	Analytical and Numerical Analysis of Low Optical Overlap Mode Evanescent Wave Chemical Sensors Solam, Anupama 21 September 2009 (has links) No description available. Electrical Engineering IO integrated optical biohazards LOOM REM
6	Arsenic Trisulfide on Lithium Niobate Devices for Infrared Integrated Optics Xia, Xin 2011 May 1900 (has links) Arsenic trisulfide (As₂S₃) waveguide devices on lithium niobate substrates (LiNbO₃) provide a set of compact and versatile means for guiding and manipulating optical modes in infrared integrated optical circuits, including the integrated trace gas detection system. As a member of the chalcogenide glass family, As₂S₃ has many properties superior to other materials, such as high transparency up to 10 [mu]m, large refractive index and high nonlinear coefficient. At the wavelength of 4.8[mu]m, low-loss As₂S₃ waveguides are achieved: The propagation loss is 0.33 dB/cm; the coupling efficiency is estimated to be 81 %; and less than 3 dB loss is measured for a 90-degree bent waveguide of 250 [mu]m bending radius. They offer an ideal solution to the optical interconnection -- the fundamental element of an optical circuit. LiNbO₃ is a birefringent crystal that has long been studied as the substrate material. Titanium diffused waveguides in lithium niobate substrate (Ti: LiNbO₃) have excellent electro-optical properties, based on which, on-chip polarization converters are demonstrated. New benefits can be obtained by integrating As₂S₃ and Ti: LiNbO₃ to form a hybrid waveguide, which benefits from the high index contrast of As₂S₃ and the electro-optical properties of Ti: LiNbO₃ as well as its easy connection with commercial single mode fibers. For hybrid waveguides, the mode coupling is key. A taper coupler is preferred owing to its simplicity in design and fabrication. Although preliminary experiments have shown the feasibility of such integration, the underlying mechanism is not well understood and guidelines for design are lacking. Therefore, a simulation method is first developed and then applied to the taper coupler design. Devices based on taper couplers are then fabricated and characterized. The study reveals that in the presence of mode beating, it is not necessarily the longer taper that is the better coupling. There exists an optimum length for a taper with fixed width variation. A two-stage taper design can largely reduce the total length, e. g. by 64%, while keeping the coupling efficiency above 90%. According to the frequency domain analysis, these practical taper couplers work for a wavelength range instead of a single wavelength. Integrated optical circuits chalcogenide glass waveguides integrated polarization converters mode couplers
7	Design and characterization of optical phased array with half-wavelength spacing Ziyun Kong (11812673) 20 December 2021 (has links) <div>Integrated optical phased arrays (OPAs) have gained popularity for achieving beam steering with no moving parts and potential high speed and small beam divergence angle. These characteristics are crucial for applications like free-space communication and light detection and ranging (LiDAR), a key component in autonomous driving. Two main aspects that affect the performance of an integrated OPA are discussed: high power handling and large beam steering range.</div><div><br></div><div>High emission power from the OPA is desirable for long range detection applications. Silicon is broadly used in integrated OPA designs as it allows for structures with a more compact footprint. However, its power-handling capability is limited by the two-photon absorption of the material, resulting in higher loss and potential damage at high input power levels. In this work, high power delivery into free space is realized by using a silicon nitride (SiN) and silicon hybrid platform. SiN components are used to direct and split high input power into smaller portions and coupled into silicon components for a more compact emitter array.</div><div><br></div><div>In order to achieve a full 180-degree beam steering range with aliasing-free operation, the pitch of a periodic emitter array is required to be half of the operating wavelength or less. At such a small pitch, evanescent coupling between adjacent emitters causes strong crosstalk. We demonstrate the optical phased array based on uniform half-wavelength spaced grating emitter array. Two-dimensional beam confinement and a record-high aliasing-free beam steering field-of-view of 135 degrees from grating emitter are measured from a 32 channel SiN/Si hybrid OPA. Evanescent coupling between waveguides are suppressed by metamaterial-based <b>e</b>xtreme <b>ski</b>n-<b>d</b>epth (e-skid) waveguides. The e-skid waveguides utilize an alternating air-silicon multi-fin side cladding. The high index contrast of those sub-wavelength ridges provides strong anisotropy, which leads to faster decay of the evanescent wave for transverse electric (TE) input modes, thus limiting evanescent coupling between closely spaced waveguides.</div><div><br></div><div>Furthermore, we extend the concept of the half-wavelength-pitched emitter array to the design of a two-dimensional end-fire OPA. This OPA can potentially achieve 180-degree by 180-degree full-range beam steering with no grating lobes by having a half-wavelength emitter pitch in both dimensions. The design of a broadband 8 by 8 silicon photonics switch based on the half-wavelength-pitched emitter array with low path-dependent loss (PDL) is also discussed.</div> Nanophotonics Optical Phased Array LiDAR integrated optical devices Photonics Integrated Circuit
8	SiGe photonic integrated circuits for mid-infrared sensing applications / Circuits photoniques intégrés SiGe pour des applications capteurs dans le moyen-infrarouge Liu, Qiankun 16 July 2019 (has links) La spectroscopie dans le moyen-infrarouge est une méthode universelle pour identifier les substances chimiques et biologiques, car la plupart des molécules ont leurs résonances de vibration et de rotation dans cette plage de longueurs d'onde. Les systèmes moyen infrarouge disponibles dans le commerce reposent sur des équipements volumineux et coûteux, tandis que de nombreux efforts sont maintenant consacrés à la réduction de leur taille et leur intégration sur circuits intégrés. L’utilisation de la technologie silicium pour la réalisation de circuits photoniques dans le moyen-infrarouge présente de nombreux avantages: fabrication fiable, à grand volume, et réalisation de circuits photoniques à hautes performances, compacts, légers et à faible consommation énergétique. Ces avantages sont particulièrement intéressant pour les systèmes de détection spectroscopique moyen infrarouge, qui besoin d'être portable et à faible coût. Parmi les différents matériaux disponibles en photonique silicium, les alliages silicium-germanium (SiGe) à forte concentration en Ge sont particulièrement intéressants en raison de la grande fenêtre de transparence du Ge, pouvant atteindre 15 µm. Dans ce contexte, l'objectif de cette thèse est d'étudier une nouvelle plate-forme SiGe à forte concentration en Ge, pour la démonstration de circuits photoniques moyen infra rouge. Cette nouvelle plate-forme devrait bénéficier d'une large gamme de transparence en longueurs d'onde de transparence et de la possibilité d’ajuster les propriétés des guides optiques (indice effectif, dispersion,…). Au cours de cette thèse, différentes plates-formes basées sur différents profils graduels du guide d’onde ont été étudiées. Tout d'abord, il a été démontré qu’il était possible d’obtenir des guides présentant de faibles pertes optiques inférieures à 3 dB/cm dans une large plage de longueurs d'onde, de 5,5 à 8,5 µm. Une preuve de concept de détection de molécules, basée sur l'absorption de la partie évanescent du mode optique a ensuite été démontrée. Ensuite, les composants formant les briques de base classiques de la photonique intégrée ont été étudiés. Les premières cavités intégrées ont été réalisées à 8 µm. Deux configurations ont été étudiées : des cavité Fabry-Perot utilisant des miroirs de Bragg intégrés dans les guides d’onde et des résonateurs en anneau. Un spectromètre à transformée de Fourier fonctionnant sur une large bande spectrale, et pour les deux polarisations de la lumière a également été démontré. Tous ces résultats reposent sur la conception des matériaux et des composants, la fabrication en salle blanche et la caractérisation expérimentale. Ce travail a été effectué dans le cadre du projet européen INsPIRE en collaboration avec le Pr. Giovanni Isella de Politecnico Di Milano. / Mid-infrared (mid-IR) spectroscopy is a nearly universal way to identify chemical and biological substances, as most of the molecules have their vibrational and rotational resonances in the mid-IR wavelength range. Commercially available mid-IR systems are based on bulky and expensive equipment, while lots of efforts are now devoted to the reduction of their size down to chip-scale dimensions. The use of silicon photonics for the demonstration of mid-IR photonic circuits will benefit from reliable and high-volume fabrication to offer high performance, low cost, compact, lightweight and power consumption photonic circuits, which is particularly interesting for mid-IR spectroscopic sensing systems that need to be portable and low cost. Among the different materials available in silicon photonics, Germanium (Ge) and Silicon-Germanium (SiGe) alloys with a high Ge concentration are particularly interesting because of the wide transparency window of Ge up to 15 µm. In this context, the objective of this thesis is to investigate a new Ge-rich graded SiGe platform for mid-IR photonic circuits. Such new plateform was expected to benefit from a wide transparency wavelength range and a high versatility in terms of optical engineering (effective index, dispersion, …). During this thesis, different waveguides platforms based on different graded profiles have been investigated. First it has been shown that waveguides with low optical losses of less than 3 dB/cm can be obtained in a wide wavelength range, from 5.5 to 8.5 µm. A proof of concept of sensing based on the absorption of the evanescent component of the optical mode has then been demonstrated. Finally, elementary building blocs have been investigated. The first Bragg mirror-based Fabry Perot cavities and racetrack resonators have been demonstrated around 8 µm wavelength. A broadband dual-polarization MIR integrated spatial heterodyne Fourier-Transform spectrometer has also been obtained. All these results rely on material and device design, clean-room fabrication and experimental characterization. This work was done in the Framework of EU project INsPIRE in collaboration with Pr. Giovanni Isella from Politecnico Di Milano. Photonique silicium Moyen-Infrarouge SiGe Capteurs optiques intégrées Silicon photonics Mid-Infrared SiGe Integrated optical sensors
9	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
10	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

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