Global ETD Search

1	Hybrid Organic / Inorganic Solar Cells Based On Electrodeposited ZnO Nanowire Arrays on ITO and AZO Cathodes Wen, Wei-Te 27 June 2013 (has links) ZnO nanowire arrays (NWAs) and Al-doped ZnO (AZO) cathodes were applied in hybrid organic / inorganic solar cells for lower-cost solar energy. Parameters for the electrodeposition of ZnO NWAs and the fabrication of NWA-free baseline devices were systematically optimized using ITO as the cathodes. High efficiencies of up to 5.4% were achieved. Incorporation of the ZnO NWAs into the baseline devices significantly reduced their efficiencies due to possible shorting in the active layer. Devices fabricated using AZO cathodes were characterized. The AZO-based devices achieved efficiencies of up to ~4.8%, showing promising results for the application of AZO as an ITO alternative. Formation of numerous large nanoplatelets was observed during the electrodeposition of ZnO NWAs on AZO cathodes. The NWAs grown on AZO cathodes were also non-uniform. Future studies were proposed to address the issues with incorporation of ZnO NWAs in hybrid solar cells and their combination with AZO cathodes. ZnO Nanowire Arrays Hybrid Organic / Inorganic Solar Cells 0794
2	Hybrid Organic / Inorganic Solar Cells Based On Electrodeposited ZnO Nanowire Arrays on ITO and AZO Cathodes Wen, Wei-Te 27 June 2013 (has links) ZnO nanowire arrays (NWAs) and Al-doped ZnO (AZO) cathodes were applied in hybrid organic / inorganic solar cells for lower-cost solar energy. Parameters for the electrodeposition of ZnO NWAs and the fabrication of NWA-free baseline devices were systematically optimized using ITO as the cathodes. High efficiencies of up to 5.4% were achieved. Incorporation of the ZnO NWAs into the baseline devices significantly reduced their efficiencies due to possible shorting in the active layer. Devices fabricated using AZO cathodes were characterized. The AZO-based devices achieved efficiencies of up to ~4.8%, showing promising results for the application of AZO as an ITO alternative. Formation of numerous large nanoplatelets was observed during the electrodeposition of ZnO NWAs on AZO cathodes. The NWAs grown on AZO cathodes were also non-uniform. Future studies were proposed to address the issues with incorporation of ZnO NWAs in hybrid solar cells and their combination with AZO cathodes. ZnO Nanowire Arrays Hybrid Organic / Inorganic Solar Cells 0794
3	Photochemical and Photoelectric Applications of II-VI Semiconductor Nanomaterials Sugunan, Abhilash January 2010 (has links) <p>In this work we investigated fabrication of semiconductor nanomaterials and evaluated their potential for photo-chemical and photovoltaic applications. We investigated two different II-VI semiconductor nanomaterial systems; (i) ZnO oriented nanowire arrays non-epitaxially grown from a substrate; and (ii) colloidal CdTe nanotetrapods synthesized by solution-based thermal decomposition of organo-metallic precursors. In both the cases our main focus has been optimizing material synthesis for improving potential applications based on photon-electron interactions.</p><p>We have studied the synthesis of vertically aligned ZnO nanowire arrays (NWA), by a wet chemical process on various substrates. The synthesis is based on epitaxial growth of ZnO seed-layer on a substrate in a chemical bath consisting of an aqueous solution of zinc nitrate and hexamethylenetetramine (HMT). We have suggested an additional role played by HMT during the synthesis of ZnO nanowire arrays. We have also extended this synthesis method to fabricate hierarchical nanostructures of nanofibers of poly-L-lactide acting as a substrate for the radially oriented growth of ZnO nanowires. The combination of high surface area of the nanofibrous substrate with the flexibility of the PLLA-ZnO hierarchical nanostructure enabled the proof-of-principle demonstration of a ‘continuous-flow’ water treatment system that could effectively decompose single and combination of known organic pollutants in water, as well as render common waterborne bacteria nonviable.</p><p>We have studied another chemical synthesis that is commonly used for size controlled synthesis of colloidal quantum dots, which was modified to obtain anisotropic nanocrystals mainly for CdE (E=S, Se, Te) compositions. In this work we demonstrate by use of oleic acid (instead of alkylphosphonic acids) it is possible to synthesize CdTe and CdSe nanotetrapods at much lower temperatures (~180 ºC) than what is commonly reported in the literature, with significantly different formation mechanism in the low-temperature reaction.</p><p>Finally, we have performed preliminary photoconduction measurements with CdTe nanotetrapods using gold ‘nanogap’ electrodes fabricated in-house, and obtain up to 100 times enhancement in current levels in the <em>I–V </em>measurements under illumination with a white light source.</p> / QC20100607 ZnO Nanowire arrays Photocatalysis Nanofibers CdTe Nanotetrapods Ostwalds ripening Photoconduction Nano-gap electrodes
4	Design and Fabrication of Nanostructures for the Enhancement of Photovoltaic Devices Prevost, Richard M, III 19 May 2017 (has links) In 2012 the net world electricity generation was 21.56 trillion kilowatt hours. Photovoltaics only accounted for only 0.1 trillion kilowatt hours, less than 1 % of the total power. Recently there has been a push to convert more energy production to renewable sources. In recent years a great deal of interest has been shown for dye sensitized solar cells. These devices use inexpensive materials and have reported efficiencies approaching 12% in the lab. Here methods have been studied to improve upon these, and other, devices. Different approaches for the addition of gold nanoparticles to TiO2 films were studied. These additions acted as plasmonic and light scattering enhancements to reported dye sensitized devices. These nanoparticle enhancements generated a 10% efficiency in device performance for dye sensitized devices. Quantum dot (QD) sensitized solar cells were prepared by successive ionic layer adsorption and reaction (SILAR) synthesis of QDs in mesoporous films as well as the chemical attachment of colloidal quantum dots using 3-mercaptopropionic acid (3-MPA). Methods of synthesizing a copper sulfide (Cu2S) counter electrode were investigated to improve the device performance. By using a mesoporous film of indium tin oxide nanoparticles as a substrate for SILAR growth of Cu2S catalyst, an increase in device performance was seen over that of devices using platinum. These devices did suffer from construction drawbacks. This lead to the development of 3D nanostructures for use in Schottky photovoltaics. These high surface area devices were designed to overcome the recombination problems of thin film Schottky devices. The need to deposit a transparent top electrode limited the success of these devices, but did lead to the development of highly ordered metal nanotube arrays. To further explore these nanostructures depleted heterojunction devices were produced. Along with these devices a new approach to depositing lead sulfide quantum dots was developed. This electrophoretic deposition technique uses an applied electric field to deposit nanoparticles onto a substrate. This creates the possibility for a low waste method for depositing nanocrystals onto nanostructured substrates. quantum dots solar cells gold nanowire arrays electrophoretic deposition SILAR Inorganic Chemistry Materials Chemistry
5	Incorporation of Gold Nanowires into Photovoltaic Devices Gordon, Scott W 23 May 2019 (has links) To this day, fossil fuels still make up over 80% of the earth’s energy production. Many sources of renewable energy are available, but photovoltaics is the only source with the capacity proven to meet the increasing world energy needs. Third generation devices such as dye-sensitized and organic solar cells have gained much interest due to their cost effectiveness and flexibility but have yet to become commercially viable. Here methods have been studied to improve these devices with the use of Gold nanowire arrays. These additions provide plasmonic and light scattering enhancements in dye-sensitized solar cells. Different TiO2 deposition methods have been studied to protect the gold from the redox couple in the electrolyte. Several novel methods have been undertaken to incorporate gold nanowire arrays in organic solar cells with some success. Structural characterization shows the proposed architecture is achieved, but working devices met suffered from low success rate. dye-sensitized solar cells organic photovoltaics gold nanowire arrays Materials Chemistry
6	Photochemical and Photoelectric Applications of II-VI Semiconductor Nanomaterials Sugunan, Abhilash January 2010 (has links) In this work we investigated fabrication of semiconductor nanomaterials and evaluated their potential for photo-chemical and photovoltaic applications. We investigated two different II-VI semiconductor nanomaterial systems; (i) ZnO oriented nanowire arrays non-epitaxially grown from a substrate; and (ii) colloidal CdTe nanotetrapods synthesized by solution-based thermal decomposition of organo-metallic precursors. In both the cases our main focus has been optimizing material synthesis for improving potential applications based on photon-electron interactions. We have studied the synthesis of vertically aligned ZnO nanowire arrays (NWA), by a wet chemical process on various substrates. The synthesis is based on epitaxial growth of ZnO seed-layer on a substrate in a chemical bath consisting of an aqueous solution of zinc nitrate and hexamethylenetetramine (HMT). We have suggested an additional role played by HMT during the synthesis of ZnO nanowire arrays. We have also extended this synthesis method to fabricate hierarchical nanostructures of nanofibers of poly-L-lactide acting as a substrate for the radially oriented growth of ZnO nanowires. The combination of high surface area of the nanofibrous substrate with the flexibility of the PLLA-ZnO hierarchical nanostructure enabled the proof-of-principle demonstration of a ‘continuous-flow’ water treatment system that could effectively decompose single and combination of known organic pollutants in water, as well as render common waterborne bacteria nonviable. We have studied another chemical synthesis that is commonly used for size controlled synthesis of colloidal quantum dots, which was modified to obtain anisotropic nanocrystals mainly for CdE (E=S, Se, Te) compositions. In this work we demonstrate by use of oleic acid (instead of alkylphosphonic acids) it is possible to synthesize CdTe and CdSe nanotetrapods at much lower temperatures (~180 ºC) than what is commonly reported in the literature, with significantly different formation mechanism in the low-temperature reaction. Finally, we have performed preliminary photoconduction measurements with CdTe nanotetrapods using gold ‘nanogap’ electrodes fabricated in-house, and obtain up to 100 times enhancement in current levels in the I–V measurements under illumination with a white light source. / QC20100607 ZnO Nanowire arrays Photocatalysis Nanofibers CdTe Nanotetrapods Ostwalds ripening Photoconduction Nano-gap electrodes
7	GaN Based Nanomaterials Fabrication with Anodic Aluminium Oxide by MOCVD Wang, Yadong, Sander, Melissa, Peng, Chen, Chua, Soo-Jin, Fonstad, Clifton G. Jr. 01 1900 (has links) A highly self-ordered hexagonal array of cylindrical pores has been fabricated by anodizing a thin film of Al on substrate and subsequent growth of GaN and InGaN in these nanoholes has been performed. This AAO template-based synthesis method provides a low cost process to fabricate GaN-based nanomaterials fabrication. / Singapore-MIT Alliance (SMA) GaN-based nanomaterials fabrication template synthesis anodic porous alumina AAO template nitride nanowire arrays anodic aluminium oxide template
8	Fabrication and Photoelectrochemical Applications of II-VI Semiconductor Nanomaterials Sugunan, Abhilash January 2012 (has links) In this work we investigated fabrication of semiconductor nanomaterials and evaluated their potential for photo-chemical and photovoltaic applications. We investigated different II-VI semiconductor nanomaterial systems; (i) ZnO oriented nanowire arrays non-epitaxially grown from a substrate; and (ii) colloidal CdE (E=Te,Se,S) quantum structures synthesized by solution-based thermal decomposition of organo-metallic precursors. We have studied the synthesis of vertically aligned ZnO nanowire arrays (NWA), by a wet chemical process on various substrates. We have extended this method wherein nanofibers of poly-L-lactide act as a substrate for the radially oriented growth of ZnO nanowires. By combining the large surface area and the flexibility of the PLLA-ZnO hierarchical nanostructure we have shown the proof-of-principle demonstration of a ‘continuous-flow’ water treatment system to decompose known organic pollutants in water, as well as render common waterborne bacteria non-viable. We have studied synthesis of colloidal quantum dots (QD), and show size, morphology and composition tailored nanocrystals for CdE (E=S, Se, Te) compositions. We have studied the influence of crystal growth habits of the nanocrtsyals on the final morphology. Furthermore we have synthesized core-shell, CdSe-CdS QDs with spherical and tetrahedral morphologies by varying the reaction conditions. We show that these core-shell quantum dots show quasi-type II characteristics, and demonstrate with I-V measurements, the spatial localization of the charge carriers in these hetero-nanocrystals. For this purpose, we developed hybrid materials consisting of the core-shell quantum dots with electron acceptors (ZnO nanowires) and hole acceptors (polymeric P3HT nanofibers). In addition we have also compared the synthesis reaction when carried out with conventional heating and microwave-mediated heating. We find that the reaction is enhanced, and the yield is qualitatively better when using microwave induced heating. / QC 20120525 ZnO nanowire arrays photocatalysis CdTe CdSe CdS nanotetrapods nanotetrahedrons photoconduction nano-gap electrodes Type-II QDs P3HT nanofibers microwave synthesis.
9	NEAR WALL SHEAR STRESS MODIFICATION USING AN ACTIVE PIEZOELECTRIC NANOWIRE SURFACE Guskey, Christopher R. 01 January 2013 (has links) An experimental study was conducted to explore the possible application of dynamically actuated nanowires to effectively disturb the wall layer in fully developed, turbulent channel flow. Actuated nanowires have the potential to be used for the mixing and filtering of chemicals, enhancing convective heat transfer and reducing drag. The first experimental evidence is presented suggesting it is possible to manipulate and subsequently control turbulent flow structures with active nanowires. An array of rigid, ultra-long (40 μm) TiO2 nanowires was fabricated and installed in the bounding wall of turbulent channel flow then oscillated using an attached piezoelectric actuator. Flow velocity and variance measurements were taken using a single sensor hot-wire with results indicating the nanowire array significantly influenced the flow by increasing the turbulent kinetic energy through the entire wall layer. Turbulent Flow TiO2 Nanowire Arrays Nanoelectromechanical Systems (NEMS) Boundary Layers Flow Actuator Aerodynamics and Fluid Mechanics Mechanical Engineering Nanoscience and Nanotechnology
10	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

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