Global ETD Search

51	Electrochemical pretreatment of carbon electrodes and the electroanalytical applications Shi, Kang 01 January 2000 (has links) No description available. Electrochemical analysis Electrodes Carbon
52	Studies on the preparation and electroanalytical applications of chemically modified electrodes Song, Fayi 01 January 2000 (has links) No description available. Electrochemical analysis Electrodes Carbon
53	Synthèse électrochimique de films d'hydroxydes doubles lamellaires : applications aux biocapteurs / Electrochemical synthesis of layered doubles hydroxides films : applications to biosensors Ben Assaker, Ibtissem 01 July 2009 (has links) Ce travail de thèse est consacré à la synthèse électrochimique de films minces d’hydroxydes doubles lamellaires (HDL) et à l’élaboration de biocapteurs enzymatiques à détection ampérométriques, utilisant ces films comme matrices d’immobilisation des enzymes. Des études préalables de synthèse de suspensions de HDLs à partir de la neutralisation de mélange de cations métalliques divalents et trivalents par la soude ont été effectuées. Les solides formés ont été caractérisés par spectroscopie FTIR et par diffraction des rayons X ; leurs compositions ont été déterminées par dosages chimiques et par ICP-OES. Les conditions permettant de former exclusivement un HDL ont été précisées pour plusieurs couples cations divalents / cations trivalents, en présence d’ions bicarbonate ou du complexant EDTA. Les suivis pHmétriques ont permis de définir les compositions d’électrolytes les plus adaptées pour les synthèses électrochimiques des films de HDLs. Des films minces d’Hydrotalcite ou de Pyroaurite ont été obtenus sur substrat conducteur (Pt, Au) par augmentation du pH local résultant de la réduction de l’oxygène dissous ou de l’eau. Les paramètres potentiel, courant et temps de réduction ont été étudiés. Des comportements électrochimiques linéaires de ces électrodes modifiées vis-à-vis de l’ion ferricyanure ou des produits de catalyse enzymatique, H2O2 et NADH, ont été mis en évidence. Deux types de biocapteurs, à glucose ou à lactate, ont été fabriqués par co-déposition électrochimique du film HDL et de l’enzyme, glucose oxydase ou lactate déshydrogénase. Leurs sensibilités ampérométriques pour leur substrat, glucose ou lactate, ont été étudiées en fonction de différents paramètres de préparation ou de fonctionnement. / This work is devoted to the electrochemical synthesis of layered double hydroxides (LDH) thin films and to the development of enzymatic biosensors with amperometric detection, using these films as immobilization matrices of enzymes. Preliminary studies of LDH suspensions synthesis by neutralization of mixed divalent and trivalent metallic cations with sodium hydroxide were performed. The powders were characterized by FTIR spectroscopy and X-ray diffraction, and their compositions were determined by chemical titration and ICP-OES. Conditions for the formation of pure LDH were specified for several couples of divalent / trivalent cations, in the presence of bicarbonate ions or EDTA. The pH titration curves allow the determination of the best suited electrolyte compositions for the electrodeposition of LDHs films. Hydrotalcite or Pyroaurite thin films were obtained on conductive substrates (Pt, Au) from the increase of local pH induced by dissolved oxygen or water electrochemical reduction. The following parameters were studied, potential, current and reduction time. The linear electrochemical behaviour of these LDH-modified electrodes was verified for the oxidation of ferricyanide ions or H2O2 and NADH, the products resulting from bio-catalysed reactions. Two types of biosensors, for glucose or lactate determination, were elaborated by electrochemical co-deposition of LDH film and enzyme, glucose oxidase or lactate dehydrogenase. Amperometric sensitivities for glucose or lactate were studied as a function of preparation and operation parameters. Comportement électrochimique Electrochemical behaviour
54	Development of modified TiO2 nanostructures for photocatalysis Mashiya, Nzaliseko January 2019 (has links) Magister Scientiae - MSc / TiO2 has been broadly used as a standard photocatalyst due to its high stability, low cost, relatively low toxicity, and excellent photocatalytic performance in comparison to other semiconductor materials. However, the large band gap of TiO2 limits its use as a photocalyst due to the high energy required for excitation of the electrons in the UV region. Research on the reduction of TiO2 band gap to the visible region of the spectrum has been explored with little success. Therefore, this study focusses on shifting the band gap of TiO2 catalyst from the UV region to the visible region by doping with graphene and nitrogen-doped graphene to form TiO2-G and TiO2-NG nanocomposites, respectively. The N-doped graphene support was prepared by doping the graphene oxide with nitrogen through Hydrothermal process, followed by the reduction of the materials. Fourier Tranform Infrared (FTIR) spectroscopy confirmed the successful doping of graphene to N-graphene by the appearance of C-N and N-H vibrational modes on the spectra. The XRD results show the fingerprint patterns of TiO2 and N-graphene, which confirms the successful preparation of the nanocomposites. Morphological studies of the nanocomposites using transmission electron microscopy (TEM) show the TiO2 nanowires dispersed on graphene related supports. The optical band gap of TiO2 from UV-Vis spectroscopy was found to be 3.2eV, which decreased to 2.7eV and 2.5eV upon incorporation of grapheme and N-graphene, respectively. These results prove the success in the achievement of the aim in this study. When electrochemical studies were further conducted on the materials, TiO2-NG was found to possess better electrochemical properties with fast electron kinetics observed on the impendance spectroscopy results. The results obtained justified use of TiO2-NG photocatalyst the optimal material for organic mineralisation in Advanced Oxidation Processes (AOPs). Photocatalysis Nanostructures TiO2 Electrochemical
55	Determination of heavy metals on macro- and micro-electrodes by adsorptive cathodic stripping voltammetry and anodic stripping voltammetry Hadjichari, Andrew Michael, University of Western Sydney, School of Civic Engineering and Environment January 1999 (has links) This thesis describes the application of macro, micro, ultra-microelectrodes and microelectrode arrays to the measurement of trace concentrations of nickel and cobalt in sediment and natural waters by adsorptive cathodic stripping voltammetric methods. In addition the measurement of tin by adsorptive cathodic stripping voltammetry in sediment and natural waters is discussed. Also, the application of macroelectrodes and microelectrode arrays to the measurement of lead, cadmium and zinc in sediment and natural waters by anodic stripping voltammetry is considered. In all cases the determination of the six metals was optimised by investigating the influence of various significant parameters, such as in-situ mercury plating, complexing agent concentration, scan rate, pulse height, accumulation time and potential, buffer concentration and pH. The results obtained for these investigations are discussed in this thesis / Doctor of Philosophy (PhD) electrochemical analysis voltammetry electrodes
56	Metal-enhanced electrochemical biosensor & nanoremediation K'Owino, Isaac Odhiambo. January 2006 (has links) Thesis (Ph. D.)--State University of New York at Binghamton, Dept. of Chemistry, 2006. / Includes bibliographical references.
57	Nanowire sensor and actuator Sivakumar, Kousik. January 2006 (has links) Thesis (M.E.E.)--University of Delaware, 2006. / Principal faculty advisor: Balaji Panchapakesan, Dept. of Electrical and Computer Engineering. Includes bibliographical references.
58	Formation and electrolysis of disubstituted alkali-metal amides. Korn, Gerhard Gunter, January 1955 (has links) Thesis (M.S.)--Virginia Polytechnic Insttute, 1955. / Typewritten. Vita. Bibliography: p. 138-143. Also available via the Internet.
59	Au and ZnO Nanoparticles Fabrication by Electrochemical Method and Optical Properties Measurements Tseng, Po-Han 28 August 2008 (has links) Abstract Information science and technology ( IT; Including computer and communication), Biotechnology (BT) and Nanotechnology (NT), are the three main technologies dominant in the 21st century. In nanotechnology, quantum size effects or surface effect (due to enhanced surface to volume ratio) can cause many new and interesting phenomena. In the literature there is also evidence that addition of small metal particles to semiconductors can enhance the optical properties of these semiconductor ¡Vnanoparticle hybrid systems. In this thesis, an electrochemical method is used to fabricate Au and ZnO nanoparticles. To characterize the samples we use various techniques like TEM (for the particle size and crystal structure), XRD (for structure, particle size analysis), Absorbance spectroscopy (for analyzing the optical properties of these systems), Photoluminescence (to study the mechanism of internal emission in the ZnO nanoparticles) On the theoretical part, some calculations based on the Drude model we computed and compared to the experimental absorbance spectrum of the samples. electrochemical ZnO Surfactant
60	Effects of surface microstructure and nanostructure on osteoblast-like mg63 cell number, differentiation and local factor production Zhao, Ge 09 January 2004 (has links) Surface roughness affects bone formation around orthopaedic implants in vivo and osteoblast functions in vitro. Osteoblast-like MG63 cells cultured on rough surfaces exhibited decreased cell number, increased differentiation and increased local factor production when compared to cells grow on smooth surfaces. In these experiments, roughness was characterized as average peak to valley height (Ra) which is not equal throughout the surface. Other features of roughness, including peak and valley area distributions and curvature of the valleys, will affect cell functions. In this study, novel titanium surfaces were prepared by photolithography to produce well designed microstructure and nanostructure. Smooth disks were made by producing craters of 10 micrometer, 30 micrometer and 100 micrometer diameters on titanium disks with constant curvatures. Craters were placed sparsely (10/1, 30/1, 100/1) or compactly (10/6, 30/6, 100/6). Smooth disks were also acid etched to make an overall roughness of Ra 0.7 micrometer or anodized to produce volcano-like nanostructure of Ra 0.4 micrometer. The results revealed the distinguishing contributions of microcrater size, crater spacing and nanostructures to surface effect on cell number, differentiation (alkaline phosphatase; osteocalcin) and local factor levels (TGF-beta1; PGE2). Cell attachment depends on crater spacing; cell growth and aggregation depend on crater dimension and cell morphology depends on the presence of nanostructural features. Cell differentiation and local factor production are modulated by acid etched roughness in concert with microstructure, and active TGF-beta1 level depends on nanoscale roughness. Nanoarchitecture Microarchitecture Electrochemical micromachining

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