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Synthèse par co-pulvérisation cathodique magnétron en condition réactive et caractérisation de revêtements d’oxydes conducteurs transparents à base de CuCrO2 de structure délafossite / Synthesis by reactive megnetron co-sputtering and characterization of delafossite structure CuCrO2-based transparent conductive filmsSun, Hui 19 July 2016 (has links)
Les TCOs (Transparent Conductive Oxide) trouvent des applications dans de nombreux domaines s'étendant del'électrochromie au photovoltaique en passant par l'opto-électronique. Parmi les matériaux historiques, les TCOs detype n font l'objet d'une littérature abondante tandis que les TCO de type p sont quant à eux étudiés de façon plusconfidentielle mais commencent à susciter un engouement, notamment dans l'objectif de jonctions p-ntransparentes.Sur la base de la théorie de la méthode de modulation chimique de bande de valence, le composé CuCrO2 destructure délafossite est considéré comme un candidat intéressant de TCO de type p. L'objectif de ces travaux estd'élaborer des films minces à base de CuCrO2 avec une transmittance optique acceptable et une conductivitéélectrique de type p élevée afin de envisager la possibilité de fabrication des jonctions p-n transparents pourdiverses applications.Dans ce travail, les films CuCrO2 ont été déposés par co pulvérisation cathodique magnétron en condition réactiveà partir de cibles métalliques. Une substitution partielle de Cr par Mg a ensuite été effectuée et l'influence del'épaisseur du film CuCrO2 :Mg sur ses propriétés optoélectroniques a été étudiée. Enfin, des revêtementsd'architecture sandwich CuCrO2 :Mg/Ag/CuCrO2 :Mg ont été élaborés en faisant varier le temps de dépôt de lacouche intermédiaire d'argent afin d'améliorer les performances optoélectroniques des films. / Transparent conductive oxides (TCOs) can be widely used in various domains from electrochromics to photovoltaicsowing to their unique optoelectronic properties. During the history of the development of TCOs, most attention hasbeen focused on n-type TCOs, while p-type TCOs have made slow progress. Recently, the studies on p-type TCOsraised many interest especially due to their potential application in the fabrication of transparent p-n junctions.Based on the theory of chemical method of valance band, CuCrO2 compound with delafossite structure isconsidered as an interesting candidate for p-type TCOs. The objective of this work is to synthesize CuCrO2-basedthin films with acceptable optical transmittance and high p-type electrical conductivity in order to explore thepossibility of fabrication of transparent p-n junctions for various applications.In this work, CuCrO2 films were deposited by reactive sputtering from metallic targets. Then, partial Cr substitutionby Mg was performed into CuCrO2 films and the influence of the films thickness on its optoelectronic properties wasstudied. Finally, sandwich architectural coatings of CuCrO2 :Mg/Ag/CuCrO2 :Mg were designed in order to improvethe films optoelectronic performances.
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Fabrication Of Functional Nanostructures Using Polyelectrolyte Nanocomposites And Reduced Graphene Oxide AssembliesChunder, Anindarupa 01 January 2010 (has links)
A wide variety of nanomaterials ranging from polymer assemblies to organic and inorganic nanostructures (particles, wires, rods etc) have been actively pursued in recent years for various applications. The synthesis route of these nanomaterials had been driven through two fundamental approaches - 'Top down' and 'Bottom up'. The key aspect of their application remained in the ability to make the nanomaterials suitable for targeted location by manipulating their structure and functionalizing with active target groups. Functional nanomaterials like polyelectrolyte based multilayered thin films, nanofibres and graphene based composite materials are highlighted in the current research. Multilayer thin films were fabricated by conventional dip coating and newly developed spray coating techniques. Spray coating technique has an advantage of being applied for large scale production as compared to the dip coating technique. Conformal hydrophobic/hydrophilic and superhydrophobic/hydrophilic thermal switchable surfaces were fabricated with multilayer films of poly(allylaminehydrochloride) (PAH) and silica nanoparticles by the dip coating technique, followed by the functionalization with thermosensitive polymer-poly(N-isopropylacrylamide)(PNIPAAM) and perfluorosilane. The thermally switchable superhydrophobic/ hydrophilic polymer patch was integrated in a microfluidic channel to act as a stop valve. At 70 degree centigrade, the valve was superhydrophobic and stopped the water flow (close status) while at room temperature, the patch became hydrophilic, and allowed the flow (open status). Spray-coated multilayered film of poly(allylaminehydrochloride) (PAH) and silica nanoparticles was fabricated on polycarbonate substrate as an anti-reflection (AR) coating. The adhesion between the substrate and the coating was enhanced by treating the polycarbonate surface with aminopropyltrimethoxylsilane (APTS) and sol-gel. The coating was finally made abrasion-resistant with a further sol-gel treatment on top of AR coating, which formed a hard thin scratch-resistant film on the coating. The resultant AR coating could reduce the reflection from 5 to 0.3% on plastic. Besides multilayered films, the fabrication of polyelectrolyte based electrospun nanofibers was also explored. Ultrathin nanofibers comprising 2-weak polyelectrolytes, poly(acrylic acid) (PAA) and poly(allylaminehydrochloride) (PAH) were fabricated using the electrospinning technique and methylene blue (MB) was used as a model drug to evaluate the potential application of the fibers for drug delivery. The release of MB was controlled in a nonbuffered medium by changing the pH of the solution. Temperature controlled release of MB was obtained by depositing temperature sensitive PAA/poly(N-isopropylacrylamide) (PNIPAAM) multilayers onto the fiber surfaces. The sustained release of MB in a phosphate buffered saline (PBS) solution was achieved by constructing perfluorosilane networks on the fiber surfaces as capping layers. The fiber was also loaded with a real life anti-depressant drug (2,3-tertbutyl-4-methoxyphenol) and fiber surface was made superhydrophobic. The drug loaded superhydrophobic nanofiber mat was immersed under water, phosphate buffer saline and surfactant solutions in three separated experiments. The rate of release of durg was monitored from the fiber surface as a result of wetting with different solutions. Time dependent wetting of the superhydrophobic surface and consequently the release of drug was studied with different concentrations of surfactant solutions. The results provided important information about the underwater superhydrophobicity and retention time of drug in the nanofibers. The nanostructured polymers like nanowires, nanoribbons and nanorods had several other applications too, based on their structure. Different self-assembled structures of semiconducting polymers showed improved properties based on their architectures. Poly(3-hexylthiophene) (P3HT) supramolecular structures were fabricated on P3HT-dispersed reduced graphene oxide (RGO) nanosheets. P3HT was used to disperse RGO in hot anisole/N, N-dimethylformamide solvents, and the polymer formed nanowires on RGO surfaces through a RGO induced crystallization process. The Raman spectroscopy confirmed the interaction between P3HT and RGO, which allowed the manipulation of the composite's electrical properties. Such a bottom-up approach provided interesting information about graphene-based composites and inspired to study the interaction between RGO and the molecular semiconductor-tetrasulphonate salt of copper phthalocyanine (TSCuPc) for nanometer-scale electronics. The reduction of graphene oxide in presence of TSCuPc produced a highly stabilized aqueous composite ink with monodispersed graphene sheets. To demonstrate the potential application of the donor (TSCuPc)'acceptor (graphene) composite, the RGO/TSCuPc suspension was successfully incorporated in a thin film device and the optoelectronic property was measured. The conductivity (dark current) of the composite film decreased compared to that of pure graphene due to the donor molecule incorporation, but the photoconductivity and photoresponsivity increased to an appreciable extent. The property of the composite film overall improved with thermal annealing and optimum loading of TSCuPc molecules.
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