Global ETD Search

11	From Synthesis To Applications Of Pristine And Nitrogen-Doped Carbon Nanotubes Goswami, Gopal Krishna 07 1900 (has links) (PDF) Carbon nanotubes (CNTs) are well known as excellent electrical conductors. However, their transport properties are limited by electrical breakdown in ambient. Moreover, the electronic properties can further be modulated by doping. Devices such as Schottky diodes, transistors and logic gates based on un-doped and doped CNT junctions have been realized. Recently, nitrogen doped CNTs show potential application in replacing platinum cathode catalyst in fuel cell technology. We synthesize pristine, nitrogen-doped and nitrogen-doped:pristine CNT intratubular junctions by one-step co-pyrolysis and explore them for different applications. We show that the position of electrical breakdown can be predicted which is essential to know for high current applications. Among other applications, we show that individual CNT intratubular junction exhibits rectifying characteristics. Further investigation indicates the intratubular junction behaves like Schottky diode. Lastly, the potential replacement of platinum by nitrogen doped CNTs in direct methanol fuel cell has been explored. Carbon Nanotubes (CNTs) Nitrogen Doped Carbon Nanotubes (NCNTs) Carbon Nanotubes - Synthesis Nitrogen-doped:pristine Single Multi-walled Carbon Nanotubes Pristine Carbon Nanotubes Nanowires Nanoparticles Nanowire Arrays Nantechnology
12	Optics and spectroscopy of gold nanowires Vasanthakumar, Priya 14 May 2012 (has links) (PDF) We have reported the optical properties of isolated gold nanowires and of nanowire arrays. Despite the advantages gold has to offer as it is less sensitive to oxidation and as an biocompatible metal, it has been scarcely studied than silver or semiconductors nanowires. We have made surface enhanced Raman spectroscopic (SERS) studies on the isolated nanowires and nanowire arrays. Single molecule regime is attained and has been proven with the aid of two dye molecules that are co-deposited. The propagation of surface plasmons in these nanowires and their evolution with the excitation wavelength have been studied. We report a propagation distance of 3.8 µm which is longer than the values previously reported in literature. Nanowire arrays have been investigated with two dyes again to disentangle the various factors contributing to SERS. Polarization studies and the evolution of enhancement in the nanowires with the wavelength have been reported and explained with the aid of simulations obtained by the discrete dipole approximation (DDA). The scanning near field optical microscopy (SNOM) has been done to investigate the local field enhancements on the nanowire arrays. Two different polarizations and two excitation wavelengths have been used. The original idea of the technique includes the use of two illumination modes which serves two purposes. One, to map the regions of enhanced field and the other to study the propagation effects seen on the nanowire. Gold Nanowire Gold nanowire arrays Plasmon propagation SM-SERS SNOM Co-deposition ATTO 740
13	Étude et optimisation de l'absorption optique et du transport électronique dans les cellules photovoltaïques à base de nanofils / Study and optimization of the optical absorptance and electrical transport in photovoltaic nanowire based solar cells Michallon, Jérôme 26 January 2015 (has links) La conversion photovoltaïque est un procédé très attractif pour la fourniture d’énergie propre et renouvelable. Cette filière est en plein essor grâce à une réduction constante des coûts de revient et des politiques incitatives de nombreux pays. Pourtant, l’ensemble des panneaux photovoltaïques installés ne produit qu’une faible part de la consommation mondiale en électricité. Les récents développements technologiques dans l’industrie photovoltaïque se sont surtout concentrés sur les cellules dites de seconde génération, à savoir les couches minces à base de CIGS, CdTe, a-Si, a-SiGe. Cette filière permet la fourniture d’électricité à coût inférieur à la technologie standard silicium, mais les rendements de conversion demeurent encore faibles, ce qui nécessite de larges surfaces disponibles. Il est à noter notamment que les cellules couches minces à base de matériaux semiconducteurs à gap direct comme le CIGS et le CdTe sont en plein essor puisqu’ils profitent en particulier d’une absorption accrue par rapport au silicium ; toutefois, ces matériaux sont présents en quantité limitée à la surface de la planète (In, Te). Dans ce contexte, les cellules à base de nanofils constituent une solution intéressante aux problèmes de l’absorption de la lumière, du transport et de la séparation des porteurs de charge photo-générés mais aussi de la quantité de matière utilisée. En effet, en utilisant une jonction radiale (i.e. entourant le nanofil), il est possible de séparer l’absorption de la lumière ( liée notamment à la longueur du nanofil) de la collecte des porteurs de charge (qui dépend du diamètre des nanofils). L’intérêt de ces structures réside également dans les propriétés de base des nanofils : la relaxation élastique favorable sur leur surface latérale ouvre le champ au dépôt de nanofils par hétéro-épitaxie sur tout type de substrat alors que la faible densité de défauts étendus en leur sein est propice à un transport efficace des porteurs de charges. Ainsi, la possibilité de réaliser des nanofils sur substrat souple en réduisant de manière importante la quantité de matière utilisée par rapport à une cellule en silicium cristallin massif peut être envisagée. Plusieurs laboratoires grenoblois ont déjà une expertise dans le domaine de la croissance des nanofils. Cette thèse a pour but de réaliser une analyse expérimentale approfondie des propriétés optoélectroniques des nanofils (par des mesures de réflectivité, de durée de vie des porteurs minoritaires et de recombinaisons en surface et aux interfaces) combinée à des simulations optiques (de type RCWA ou FDTD) et électriques (TCAD). L’objectif ultime étant de concevoir et de développer des cellules à base de nanofils de silicium et de ZnO/CdTe. Des démonstrateurs seront réalisés sur la base des simulations électro-optiques. Pour cela, les moyens d’élaboration, de caractérisation et de technologie des différents laboratoires et entités, ainsi que les compétences associées, seront mis en commun pour accompagner les travaux du doctorant. / Photovoltaic energy is a very attractive way to produce renewable energy. The current increase in the photovoltaic energy production mainly takes advantage of the continuous decrease in the solar cell cost as well as to incentive policy. However, installed photovoltaic panels only contribute to a very small part of the global electricity production. Therefore, important technological developments are dedicated to the second generation of solar cells (i.e. thin film solar cells) in order to reduce more their manufacturing cost despite the resulting lower conversion efficiency owing to a weaker structural and optical material quality. One alternative way to increase the solar cell efficiency is to fabricate nanowire-based solar cells since they may benefit from a higher light absorption and carrier collection efficiency. The light absorption is actually increased thanks to the high surface/volume ratio of nanowires but also to light trapping related to the nanowire length. Furthermore, the collection of minority charge carriers is more efficient in radial structures (i.e. core-shell structures) since the nanowire diameter is very small. This PhD thesis aims at investigating the optoelectronic properties of silicon and ZnO/CdTe nanowires (absorption, lifetime of minority charge carriers, bulk and surface recombination…) in order to design an optimised nanowire-based solar cell structure. Electromagnetic simulations will be first performed to define the best nanowire geometry for the absorbance, and then compared to experimental measurements of the absorption coefficient. Electrical characterisations (lifetime measurements, surface recombination…) will be also achieved to analyse the structural quality and to simulate the solar cell electrical properties. Some prototypes of optimised solar cells will eventually be fabricated. Cellule photovoltaïque Réseaux de nanofils ZnO/CdTe C-Si/a-Si Modes optiques Transport de charges Solar cell Nanowire arrays ZnO/CdTe C-Si/a-Si Optical modes Charge transport 620
14	Organometallic approach to the growth of metallic magnetic nanoparticles in solution and on substrates / Approche organométallique de la synthèse de nanoparticules métalliques magnétiques en solution et sur des substrats Liakakos, Nikolaos 08 July 2013 (has links) Cette thèse concerne une nouvelle méthode chimique de croissance par germes qui peut produire des assemblés de nanostructures métalliques epitaxiées sur des surfaces macroscopiques cristallines qui agissent comme germes. Cette approche permet d’obtenir des assemblés bien organisées en échelle centimétrique de nanofils métalliques de Co, qui sontmonocristallins, monodisperses de diamètres inferieurs à 10nm et qui ont une orientation perpendiculaire. Ils ont une anisotropie magnétique perpendiculaire et sont intéressantes pour des applications d’enregistrement magnétique à très haute densité. L’extension de cette méthode au fer donne des films nanostructurés de fer. L’orientation des nanostructures sur le support solide dépend de l’orientation cristallographique du substrat, alors que leur morphologie est dictée par la composition de la solution. Cet objectif a été atteint grâce à des études parallèles sur le mécanisme de croissance de nano-cristaux de cobalt en solution qui ont révélées une influence inattendue de la procédure de préparation de la solution mère sur la morphologie des nanocristaux. En plus,l’utilisation des germes nanoscopiques pour la croissance de Co et de Fe a rendu des nanofils longs de Co et des altères de Co-Fe et elle a contribué à la définition et l’amélioration des conditions expérimentales pour la croissance par germes de Co et de Fe sur les substrats solides. / This thesis concerns a new wet chemical seeded growth method that can produce arrays of metal nanostructures epitaxially grown on crystalline macroscopic surfaces which act as seeds. This approach produces wafer-scale organized 2D hexagonal arrays of perpendicularly oriented, monodisperse and monocrystalline metallic Co nanowires with diameters below 10 nm which exhibit perpendicular magnetic anisotropy and are interesting for applications in ultra high density magnetic recording. Extension of this approach to iron gives rise to nanostructured iron films. The orientation of the nanostructures on the solid substrate depends on the substrate crystallographic orientation, whereas their morphology is dictated by the solution composition. This objective was attained through parallel studies on the growth mechanism of cobalt nano-crystals in solution which revealed an unexpected influence of the stock solution preparation procedure on the nanocrystal morphology. In addition, the use of nanoscopicseeds for the overgrowth of cobalt and iron gave rise to long Co nanowires and Co-Fe dumbbells and contributed to the definition and the improvement of the experimental conditions for the seeded growth of Co and Fe on the solid substrates Cobalt Fer Nanoparticules Nano-objets hybrides Nanoparticules magnétiques Croissance par germes Croissance épitaxiale Assemblés de nanofils Couches minces Cobalt Hybrid nano-objects Magnetic nanoparticles Seeded growth Epitaxial growth Nanowire arrays Thin films Nanoparticles Iron 620.5
15	Optics and spectroscopy of gold nanowires / Propriétés optiques et spectroscopiques de nanofils d'or Vasanthakumar, Priya 14 May 2012 (has links) Les études portent sur les propriétés optiques de nanofils d’or individuels et de réseaux de nanofils d’or. Malgré ses avantages, comme une sensibilité moindre à l’oxydation et sa biocompatibilité, les nanofils en or ont été peu étudiés par comparaison avec les nanofils en argent ou semiconducteurs. Les études sur ces substrats ont été réalisées par spectroscopie Raman exaltée de surface (SERS). Le régime de la molécule unique est atteint, ce que j’ai démontré en utilisant deux molécules différentes de colorant, co-déposées. J’ai étudié la propagation des plasmons de surface dans les nanofils ainsi que son évolution en fonction de la longueur d’onde. Une distance de propagation de 3,8 µm a été observée, plus grande que les valeurs précédemment rapportées. Les réseaux de nanofils ont également été étudiés en combinant la réponse de deux molécules pour démêler les différents processus contribuant au signal de la diffusion Raman. Les résultats obtenus par des études en polarisation et en fonction de la longueur d’onde sur l’évolution de l’intensité du signal SERS ont été confrontés aux résultats de simulations réalisées par la méthode de l’approximation des dipôles discrets (DDA). La microscopie de champ proche optique à balayage (SNOM) a été mise en œuvre pour étudier les effets d’exaltation locale sur les réseaux de nanofils. Ces études ont été réalisées avec deux polarisations croisées et à deux longueurs d’onde différentes. L’originalité des études SNOM repose sur l’utilisation de deux modes différents d’éclairement. L’un est utilisé pour cartographier l’exaltation des champs électromagnétiques, l’autre pour étudier les effets de propagation des plasmons dans les nanofils. / We have reported the optical properties of isolated gold nanowires and of nanowire arrays. Despite the advantages gold has to offer as it is less sensitive to oxidation and as an biocompatible metal, it has been scarcely studied than silver or semiconductors nanowires. We have made surface enhanced Raman spectroscopic (SERS) studies on the isolated nanowires and nanowire arrays. Single molecule regime is attained and has been proven with the aid of two dye molecules that are co-deposited. The propagation of surface plasmons in these nanowires and their evolution with the excitation wavelength have been studied. We report a propagation distance of 3.8 µm which is longer than the values previously reported in literature. Nanowire arrays have been investigated with two dyes again to disentangle the various factors contributing to SERS. Polarization studies and the evolution of enhancement in the nanowires with the wavelength have been reported and explained with the aid of simulations obtained by the discrete dipole approximation (DDA). The scanning near field optical microscopy (SNOM) has been done to investigate the local field enhancements on the nanowire arrays. Two different polarizations and two excitation wavelengths have been used. The original idea of the technique includes the use of two illumination modes which serves two purposes. One, to map the regions of enhanced field and the other to study the propagation effects seen on the nanowire. Nanofil en or Réseau de nanofils en or Propagation de plasmons SM-SERS Microscopie de champ proche optique Co-déposition ATTO 740 Gold Nanowire Gold nanowire arrays Plasmon propagation SM-SERS SNOM Co-deposition ATTO 740
16	Functional Noble Metal, Bimetallic And Hybrid Nanostructures By Controlled Aggregation Of Ultrafine Building Blocks Halder, Aditi 07 1900 (has links) Functional nanomaterials are gaining attention due to their excellent shape and size dependent optical, electrical and catalytic properties. Synthesizing nanoparticles is no longer novel with the availability of a host of synthesis protocols for a variety of shapes and sizes of particles. What is currently needed is an understanding the fundamentals of shape and size controlled synthesis to produce functional nanomaterials that is simple and general. In addition to simple metallic nanostructures, synthesizing bimetallic and hybrid nanostructures are important for applications. Instead of trying to add functionality to the preformed nanomaterials, it is advantageous to look for cost effective and general synthetic protocols that can yield bimetallic, hybrid nanostructures along with the shape and size control. In this dissertation, a novel synthetic protocol for the synthesis of ultrfine single crystalline nanowires, metallic and bimetallic nanostructures and hybrid nanostructures has been investigated. The key point of the synthesis is that all different functional nanostructures are achieved by the use of noble metal intermediates in organic medium without phase transfer reagents. The roles of capping agents, oriented attachment and aggregation phenomenon have been studied in order to understand the formation mechanisms. Along with the synthesis, formation mechanisms, the optical and catalytic properties of the functional, noble metal, bimetallic and hybrid nanostructures have been studied. The entire thesis based on the results and findings obtained from the present investigation is organized as follows: Chapter I provides a general introduction to functional nanomaterials, their properties and some general applications, along with a brief description of conventional methods for size and shape-controlled synthesis. Chapter II deals with the materials and methods which essentially gives the information about the materials used for the synthesis and the techniques utilized to characterize the materials chosen for the investigation. Chapter III presents a novel method of for synthesizing noble metals nanostructures starting from an intermediate solid phase. The method involves the direct synthesis of noble metal intermediates in organic medium without the use of any phase transfer reagent. Controlled reduction of these intermediates leads to the formation of ultrafine nanocrystallite building blocks. Controlled aggregation of the nanocrystallites under different conditions leads to the formation of different nanostructures ranging from single crystalline nanowires to porous metallic clusters. In this chapter, the details of synthesis of the intermediate phase of gold are presented. This intermediate phase is the rocksalt phase of AuCl that has been experimentally realized for the first time. Manipulation of the AuCl nanocubes leads to the formation of a variety of nanostructures of Au starting from hollow cubes to extended porous structures. Mechanistic details of the formation of the intermediate and the nanostructures are presented in this chapter. Chapter IV deals with the symmetry breaking of an FCC metal (gold) by oriented attachment of metal nanoparticles by the preferential removal of capping agent from certain facets and followed by the attachment of gold nanoparticles along those bare facets. This kind of oriented attachment leads to the formation of 1D nanostructures with high aspect ratios. In this chapter, the synthesis, characterisation, formation mechanism and optical properties of high aspect ratio, molecular scale single crystalline gold nanowires has been described. This represent the first ever successful method to produce ultrafine 1D metallic nanostructures approaching molecular dimensions. Chapter V deals with the formation of hybrid nanostructures by attaching the cubic intermediate phase to a substrate like carbon nanotubes followed by the reduction of the attached intermediates on the tubes. The Pt intermediates have been synthesized and attached on the wall of functionalized CNTs and reduced. The PtCNT nanocomposites been characterized by several spectroscopic and microscopic techniques. The electrocatalytic activity of these nanocomposites towards the methanol oxidation has also been investigated. The composites exhibit high catalytic activity and good long term performance. The presence of functional groups on the CNT surface overcomes some of the limitations of current single metal catalysts that suffer from CO poisoning. Chapter VI deals with the formation of palladium nanostructures ranging from nanoparticles to hierarchical aggregates by controlled aggregation of nanoparticles in an organic medium that is tuned by the dielectric constant of the system. A crystalline intermediate of palladium salt has been synthesized and this intermediate of palladium has been used as the precursor solution for the synthesis of palladium nanostructures. The formation mechanism of the nanoporous Pd cluster is investigated using the modified DLVO approach. The catalytic efficiency of the Pd nanostructures has been investigated using the reduction of pnitrophenol and electrocatalytic hydrogen storage as model reactions. Chapter VII discusses the possibility of achieving functional bimetallic alloys by simultaneous reduction of the cubic intermediate of two different metals with experimental evidences. The synergistic effect of the two different metals gives rise to better catalytic activity. This chapter mainly deals with the synthesis of bimetallic porous nanoclusters of goldpalladium and goldplatinum in an organic medium. Detailed microstructural and spectroscopic characterisation of the bimetallic nanoclusters has been carried out and their electrocatalytic performance, morphological stability also investigated. Nanomaterials Noble Metals - Aggregation Silver Gold Nanomaterials - Synthesis Nanostructures Palladium Nanostructures Noble Metal Nanostructures Hybrid Nanostructures Gold Nanostructures Nanowire Arrays Platinum Nanoparticles Rocksalt AuCl Carbon Nanotubes Nanoclusters Nanocomposites Nanaotechnology
17	APPLICATIONS OF MICROHEATER/RESISTANCE TEMPERATURE DETECTOR AND ELECTRICAL/OPTICAL CHARACTERIZATION OF METALLIC NANOWIRES WITH GRAPHENE HYBRID NETWORKS Doosan Back (6872132) 16 December 2020 (has links) <div>A microheater and resistance temperature detector (RTD) are designed and fabricated for various applications. First, a hierarchical manifold microchannel heatsink with an integrated microheater and RTDs is demonstrated. Microfluidic cooling within the embedded heat sink improves heat dissipation, with two-phase operation offering the potential for dissipation of very high heat fluxes while maintaining moderate chip temperatures. To enable multi-chip stacking and other heterogeneous packaging approaches, it is important to densely integrate all fluid flow paths into the device. Therefore, the details of heatsink layouts and fabrication processes are introduced. Characterization of two-phase cooling as well as reliability of the microheater/RTDs are discussed. In addition, another application of microheater for mining particle detection using interdigitated capacitive sensor. While current personal monitoring devices are optimized for monitoring microscale particles, a higher resolution technique is required to detect sub-micron and nanoscale particulate matters (PM) due to smaller volume and mass of the particles. The detection capability of the capacitive sensor for sub-micron and nanoparticles are presented, and an incorporated microheater improved stable capacitive sensor reading under air flow and various humidity. </div><div>This paper also introduces the characterization of nanomaterials such as metallic nanowires (NWs) and single layer graphene. First, the copper nanowire (CuNW)/graphene hybrid networks for transparent conductors (TC) is investigated. Though indium tin oxide (ITO) has been widely used, demands for the next generation of TC is increasing due to a limited supply of indium. Thus, the optical and electrical properties of CuNW/graphene hybrid network are compared with other transparent conductive materials including ITO. Secondly, silver nanowire (AgNW) growth technique using electrodeposition is introduced. A vertically aligned branched AgNW arrays is made using a porous anodic alumina template and the optical properties of the structure are discussed.</div><div><br></div> Microelectronics and Integrated Circuits Environmental Technologies Microtechnology Composite and Hybrid Materials Fluidisation and Fluid Mechanics Heat and Mass Transfer Operations Microheater Temperature Sensor Evaporative Cooling Electromigration capacitive sensor devices Transparent conductive oxides nanowire arrays graphene
18	Nanostructured Materials for Energy Applications Li, Yanguang 08 September 2010 (has links) No description available. Chemistry Materials Science Nanostructure Nanowire arrays Cobalt oxide (Co3O4) Nickel (Ni) doping Screw dislocation Lithium ion battery Oxygen evolution Lithium iron phosphate (LiFePO4) Graphene oxide Kirkendall effect Mesoporous Metal oxide Self-assembly

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