Global ETD Search

11	Study of the oxygen reduction reaction on platinum with scanning electrochemical microscopy and rotating disk voltammetry Sun, Xiaojing, January 2007 (has links) Thesis (M.S.)--Mississippi State University. Department of Chemistry. / Title from title screen. Includes bibliographical references.
12	Scanning electrochemical microscope (SECM) study of charge transfer through solid/liquid interfaces, liquid/liquid interfaces, and bilayer lipid membranes / Zhou, Junfeng, January 2000 (has links) Thesis (Ph. D.)--University of Texas at Austin, 2000. / Vita. Includes bibliographical references. Available also in a digital version from Dissertation Abstracts.
13	Electrode surface modification using metallophthalocyanines and metal nanoparticles : electrocatalytic activity Maringa, Audacity January 2015 (has links) Metallophthalocyanines and metal nanoparticles were successfully synthesized and applied for the electrooxidation of amitrole, nitrite and hydrazine individually or when employed together. The synthesized materials were characterized using the following techniques: predominantly scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS), electrochemistry and scanning electrochemical microscopy (SECM). Different electrode modification methods were used to modify the glassy carbon substrates. The methods include adsorption, electrodeposition, electropolymerization and click chemistry. Modifying the glassy carbon substrate with MPc (electropolymerization) followed by metal nanoparticles (electrodeposition) or vice versa, made a hybrid modified surface that had efficient electron transfer. This was confirmed by electrochemical impedance studies with voltammetry measurements having lower detection potentials for the analytes. This work also describes for the first time the micropatterning of the glassy carbon substrate using the SECM tip. The substrate was electrografted with 4-azidobenzenediazonium salt and then the click reaction was performed using ethynylferrocene facilitated by Cu⁺ produced at the SECM tip. The SECM imaging was then used to show the clicked spot. Phthalocyanines Nanoparticles Electrocatalysis Scanning electron microscopy X-ray photoelectron spectroscopy Electrochemistry Scanning electrochemical microscopy
14	Uso da microscopia eletroquímica de varredura (SECM) no estudo de sistemas micelares e do transporte de espécies químicas através de membranas lipídicas / The use of scanning electrochemical microscopy (SECM) on studies of micellar systems and in the transport of chemical species through lipid membranes Alex da Silva Lima 31 July 2015 (has links) A presente tese versa sobre resultados obtidos na aplicação da microscopia eletroquímica de varredura no estudo de sistemas micelares e no estudo de bicamadas lipídicas. Os estudos envolvendo sistemas micelares foram realizados utilizando a SECM no modo substrato-gerador/microeletrodo-coletor. Neste modo de operação, um microeletrodo de platina foi posicionado próximo a um substrato de platina e utilizado para monitorar espécies eletrogeradas nesse substrato. Conhecendo o tempo necessário para a espécie eletrogerada difundir do substrato até o microeletrodo, foi possível aplicar a equação de Einstein-Smoluchowski para determinar o coeficiente de difusão da espécie eletroativa e de micelas de surfactantes. Como as micelas não são eletroativas, o ferroceno eletrogerado no substrato e incorporado nas micelas foi utilizado como sonda para a estimativa do tempo de difusão. Os resultados obtidos para o surfactante brometo de tetradecil trimetil amônio (C14TABr) corroboram dados reportados na literatura, demonstrando a utilidade da metodologia proposta no estudo de sistema micelares. Também foram realizados experimentos envolvendo micelas do surfactante cloreto de 1-alquil-3-metilimidazólio, CxMelmCl (x = 10, 12, 14, 16) e com os resultados obtidos foi possível evidenciar o efeito da cadeia carbônica no coeficiente de difusão das espécies. Os experimentos envolvendo a permeação de substâncias através de bicamadas lipídicas foram realizados em duas etapas. Os primeiros ensaios foram realizados utilizando modelo de membrana semipermeável (papel celofane) com o intuito de verificar a aplicabilidade da SECM no monitoramento de espécies eletroativas que permeiam através da membrana. Na segunda etapa, apresentou-se metodologia para a obtenção de microfuros em folhas de poliestireno utilizados para a formação das bicamadas lipídicas, assim como detalhes sobre a construção da célula de medidas utilizadas nos experimentos de permeação. Foram realizados experimentos envolvendo o uso de bicamadas lipídicas planas obtidas pelo método de Miller preparadas com lecitina de soja. Esses experimentos foram realizados com o intuito de avaliar a estabilidade e para verificar a permeabilidade de algumas substâncias nas bicamadas formadas. Os experimentos de permeação foram realizados posicionando um microeletrodo próximo à membrana, com posterior detecção amperométrica da espécie eletroativa que atravessa a membrana. / This thesis shows results on the use of scanning electrochemical microscopy in the study of micellar systems and lipid bilayers. Studies involving micellar systems were performed by using SECM in the substrate-generator/tip-collector mode. In this operation mode a platinum microelectrode was positioned close to a platinum substrate and used to monitor electrogenerated species on this surface. Taking into account the time for the electrogenerated species to diffuse from the substrate to the microelectrode, the diffusion coefficient of the electroactive species and of the micelles can be calculated by applying the Einstein-Smoluchowski equation. As micelles are not electroactive, ferrocene electrogenerated on the substrate and incorporated into the micelles was used as a probe to estimate the diffusion time. The results obtained for tetradecyl trimethyl ammonium bromide (C14TABr) corroborate those reported in the literature, demonstrating the applicability of the proposed methodology in the study of micellar systems. Experiments with micelles obtained from 1-alkyl-3-methylimidazolium, CxMelmCl (x = 10, 12, 14, 16) chloride surfactants were also performed and results showed the effect of the carbon chain in the diffusion coefficient. Experiments involving the permeation of chemical species through lipid bilayers were carried out in two steps. A membrane model (cellophane) was preliminary used in order to investigate the possibility of using SECM as a tool for monitoring the permeation of electroactive species through the membrane. Then, a methodology for obtaining microholes in polystyrene sheets used to form lipid bilayers was presented, as well as details about the design of an electrochemical cell used in the permeation experiments. Experiments involving the use of planar lipid bilayers obtained by the method of Miller prepared using soybean lecithin were performed. These experiments were carried out in order to evaluate the stability and to check the permeation of some substances through the prepared bilayers. Permeation experiments were performed by placing the microelectrode close to the membrane with subsequent amperometric detection of any electroactive species that cross the membrane Bicamadas lipídicas Micelas Microeletrodo Microscopia eletroquímica de varredura Lipid bilayers Micelles Microelectrode Scanning electrochemical microscopy
15	Mechanoelectrochemistry of electroactive polymers using shear-force based near-field microscopy Venkatesh, Vijay 01 October 2020 (has links) No description available. Engineering Mechanical Engineering scanning electrochemical microscopy scanning ion conductance microscopy shear-force
16	Preparation of Gold Nanoparticles with Scanning Electrochemical Microscopy Han, Changhong 12 May 2012 (has links) Scanning electrochemical microscopy (SECM) is used to deposit gold nanoparticles on a glassy carbon electrode (GCE). Deposition conditions, including the tip-substrate distance, current density, substrate potential, and addition of Ag ions in the electrolyte are changed to study the effects on gold spot size and particle morphology. Atomic force microscopy (AFM) is used to analyze the gold nanoparticles. The size and shape of the nanoparticle can be controlled by different SECM experimental conditions. OMSOL Multiphysics software is used to simulate the results of SECM deposition. By comparing the simulation results and experimental results, the deposition process can be understood better. Heterogeneous irreversible reaction rate constant of the reaction happened on GCE can be estimated. COMSOL Multiphysics simulation gold nanoparticles atomic force microscopy scanning electrochemical microscopy
17	Study of the oxygen reduction reaction on platinum with scanning electrochemical microscopy and rotating disk voltammetry Sun, Xiaojing 15 December 2007 (has links) The tip generation/substrate collection mode (TG/SC) of scanning electrochemical microscopy (SECM) was used to study the ORR reactivity on Pt catalysts in sulfuric acid solution. The SECM reactivity image and the photographic image of different single crystalline regions of the etched Pt electrode correlated well. The electron backscatter diffraction (EBSD) image of Pt confirmed the surface single crystalline orientation. The image resolution is improved by employing smaller tip-substrate distance. The kinetics of the ORR on Pt surface was also studied at -15 - 30 C by means of the rotating disk voltammetry techniques. The calculated Tafel slopes for 0.1 m and 0.9 m HClO4 changed with decreasing temperature, indicating lower kinetics at low temperature. Peroxide is produced at potentials below 0 V vs SCE. rotating ring-disk electrode scanning electrochemical microscopy oxygen reduction reaction rotating disk electrode
18	Examining the Effects of Applied Potential on the Surface Charge of Functionalized Monolayers for Site-Directed Ionic Self Assembly Sanders, Wesley Crowell 02 December 2008 (has links) The focus of this dissertation research involves surface charge manipulation of functionalized monolayers. Application of potential to acid or base terminated organic films immobilized on electrodes results in the ionization of the terminal groups. The ionization of these groups using applied potential provides conditions favorable the control of polyelectrolyte deposition to the monolayer surface. Research is presented that asserts that the interfacial pH of acid or base terminated monolayers responds to applied potential as a result of the accumulation of phosphate counterions to the monolayer-solution interface. Results obtained from applied potential modulation of surface charge endeavors strongly suggest that manipulation of terminal group ionization with applied potential “turns on“ or “turns off“ the charge of the monolayer. Switching on the surface charge of functionalized monolayers using applied potential yields conditions that make it possible for the promotion or inhibition of electrostatic attachment of polyelectrolyte to the monolayer surface. Electrostatic interactions between immobilized polyelectrolytes and redox probes result in changes in electron transfer that can be monitored with electrochemical impedance measurements. Impedance measurements provide a qualitative assessment of the degree of potential-driven polyelectrolyte self assembly. The electrostatic interactions between the redox probe in solution and the terminal region of monolayers directly affects the extent of charge-transfer between the electrode and the redox probe in solution. For this reason, impedance measurements are able to provide an indication of whether or not potential drives to electrostatic deposition to the terminal region of a functionalized monolayer. Unlike impedance measurements, quartz crystal microbalance measurements provide quantitative mass assessments that confirm polyelectrolyte deposition of inhibition under the direction of applied potential. Application of appropriate potentials is shown to induce variations in the electrostatic interactions between redox probes in solution and terminal groups of monolayers. Variations in the electrostatic interactions between the modified electrode and the redox probe modulate electron transfer that produces varying current. Since scanning electrochemical microscopy (SECM) relies on modulation of feedback current underneath a ten-micrometer platinum tip, SECM provides a means for monitoring of potential-driven surface charge modulation. Experiments presented in this dissertation will show that in addition to monitoring the effect of applied potential on the charge of ionizable surface groups, SECM can also be used to selectively deposit a polyelectrolyte to the surface of a carboxylic acid terminated monolayer. The SECM tip was rastered over the surface of a functionalized monolayer in the form of a simple pattern while the electrode was immersed in a dilute polyelectrolyte solution. As the SECM tip was moved and potential stepped more positive than the PZC, ionization was confined ionization to one spot encouraging localized ionic self assembly. / Ph. D. redox probe scanning electrochemical microscopy Ionic self assembly polyelectrolytes electrochemical impedance quartz crystal microbalance
19	Novel Applications of Scanning Electrochemical Microscopy Roach, David Michael 23 January 2006 (has links) Scanning Electrochemical Microscopy (SECM) is most commonly used to spatially resolve reaction rates, image surface topography and surface reactivity. In this research, SECM is applied to various chemical systems in order to resolve local reaction chemistry and to produce patterns with dimensions of tens of microns in n-alkanethiol passivated gold substrates. Upon completing construction of the instrumentation, SECM was applied to capillary electrophoresis to accurately and reproducibly place the electrode directly above a very small capillary opening. Feedback SECM was then used to image and pattern surfaces, effectively distinguishing between insulating and conductive domains. Finally, the size of desorbed features patterned on a passivated gold substrate were studied as a function of both applied potential and ionic strength. Electrochemical detection in capillary electrophoresis requires decoupling the voltage applied to the working electrode from the separation voltage applied across the capillary. End-capillary electrochemical detection achieves this by placing the electrode just outside the ground end of the separation capillary. Obtaining adequate signal-to-noise in this arrangement requires using small inner diameter capillaries. Decreasing the inner diameter of the separation capillary, however, increases the difficulty of aligning the microelectrode with the open end of the capillary. Using SECM, the position of the capillary opening is determined while electroactive material is continuously emerging from the end of the capillary. The SECM instrument is then used to place the electrode at the position of maximum current for subsequent separations. Subsequent measurements found that the best signal-to-noise is obtained when the detection electrode is placed directly opposite the capillary opening and just outside of the capillary opening. When the electrode is further above the opening (but still opposite the capillary opening), the signal-to-noise does not dramatically decrease until the electrode is more than 30 μm above the 10 μm inner-diameter capillary. Limits of detection for 2,3-dihydroxybenzoic acid were found to be 8.2 fmol when aligned manually, and 3.8 fmol when the SECM is used to automatically align the microelectrode. SECM was then used to image a series of multi-disk electrode arrays in order to demonstrate the ability of the instrument to discriminate between conductive and insulating domains. Upon demonstrating the capacity of the SECM to image very small domains of conductor on an insulating substrate, n-alkanethiol passivated gold surfaces were patterned using site-selective desorption. A number patterns, potentially useful for enzyme deposition, were subsequently produced in the passivated gold substrate. The feature size of the desorbed domains was monitored as a function of applied potential and the ionic strength of the solution used for desorption. Results showed that applying a more negative potential or increasing the ionic strength of the solution increased the magnitude of the electric field at the surface of the passivated gold substrate and resulted in a more complete, larger desorption. Both ionic strength and applied desorption potential prove to be parameters useful for controlling the size of patterned features in site selective desorption. / Master of Science Lithography Site Selective Desorption Self-Assembled Monolayers Scanning Electrochemical Microscopy Capillary Electrophoresis
20	Production and study of a Ti/Ti02/Noble metal anode Gueneau de Mussy, Jean Paul 09 October 2002 (has links) <p align="justify">Plusieurs métaux de notre vie courante sont obtenus industriellement au moyen de procédés électrolytiques. Un des procédés les plus communs est l’électro-obtention de cuivre, dans lequel le métal est déposé à la cathode tandis que l'oxygène se dégage à l'anode. Généralement, en usine, plusieurs anodes et cathodes, ayant une surface de 1 m2 et séparées par plus ou moins 10 cm sont alternées dans une cellule contenant une solution d'acide sulfurique riche en sulfate de cuivre. En fonction des conditions d'utilisation, les cathodes sont remplacées, après un certain temps, par des nouvelles de façon à récupérer le cuivre déposé. De ce fait, les anodes doivent être capables de résister sans se corroder, se déformer ou perdre leurs propriétés électrocatalytiques pendant de longues périodes. Au début, des alliages en Pb (pb-Ag, Pb-Ca-Sn,...) ont été utilisés comme anodes. Malheureusement, malgré leur faible prix, ces anodes présentent des surtensions élevées et une faible résistance à la corrosion et au fluage. Par conséquent, une alternative aux anodes traditionnelles en 1 développée. Ce nouveau type d'anode, connu sous le nom d’anode dimensionnellement stable (DSA) est fabriquée à partir d'une tôle en Ti recouverte par un mélange d'oxydes de métaux nobles catalysant la réaction de dégagement d'oxygène. Différentes techniques peuvent être utilisées pour préparer la couche d'oxyde. La technique la plus souvent employée consiste à décomposer thermiquement une solution de chlorures contenant un ou plusieurs nobles. Malheureusement, ce type d'anode est cher et a tendance à perdre son activité électrocatalytique avec le temps.</p> <p align="justify">Dans le but de produire une DSA à faible prix, pouvant résister de longues périodes sans se passiver, un nouveau type de DSA a été développé dans le présent travail. Cette anode est produite par électrodépôt d'un métal noble dans les pores d'un substrat microporeux en Ti/TiO2.</p> <p align="justify">Ce travail a permis de démontrer qu'une DSA avec une concentration en métal noble peut être obtenue par la voie proposée. Il a été montré que les propriétés électriques et électrochimiques de ces DSAs sont directement liées aux caractéristiques morphologiques et structurales du en Ti/TiO2. Lorsque la couche barrière existant au fond des pores est suffisamment fine et que le film présente des défauts, la résistance me l'interface Ti/métal noble est faible. Ceci abouti à des DSAs possédant d'excellentes propriétés électrocatalytiques. Les DSAs optimales sont capables de résister à des conditions similaires à celles employées en industrie avec des surtensions de ~ 0.4 V, ce qui représente un gain de 50% par rapport aux surtensions normalement atteintes par les anodes traditionnelles en Pb.</p> Dimensionally Stable Anode (DSA) Chimie des surfaces et des interfaces Chimie des solides

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