Global ETD Search

51	Metal Complexes of Modified Cyclen as Catalysts for Hydrolytic Restriction of Plasmid DNA Krauser, Joel A., Joshi, Aarti L., Kady, Ismail O. 01 August 2010 (has links) Simple and novel nuclease models have been synthesized. These involve metal-binding ligand 1,4,7,10-tetraazlcyclododecane (cyclen) tethered to an acridine ring (a DNA-binding group) by amide linkers of various lengths. Binding of these probes to DNA was studied by monitoring changes in their UV-visible spectra affected by the presence of DNA. Titration of these compounds with increasing amounts of pBR322 DNA caused hypochromic effects and shifted the acridine absorption at 360nm to a longer wavelength. Under biologically relevant conditions (37°C and pH 7.4), specific transition metal complexes of these compounds are found to be highly effective catalysts toward the hydrolysis of plasmid DNA. This is demonstrated by their ability to convert the super-coiled DNA (form I) to open-circular DNA (form II). Structure-activity correlation studies show that hydrolytic activity depends on both the structure of ligand (L1>L2>L3) and the nature of metal ion cofactor (Co3+>Zn2+>Cr2+>Ni2+>Cu2+>Fe3+). acridine cyclen DNA intercalation metal complexes nuclease models Chemistry
52	Novel Acridine-Based Compounds That Exhibit an Anti-Pancreatic Cancer Activity Are Catalytic Inhibitors of Human Topoisomerase II Oppegard, Lisa M., Ougolkov, Andrei V., Luchini, Doris N., Schoon, Renee A., Goodell, John R., Kaur, Harneet, Billadeau, Daniel D., Ferguson, David M., Hiasa, Hiroshi 14 January 2009 (has links) We have identified a small library of novel substituted 9-aminoacridine derivatives that inhibit cell proliferation of pancreatic cancer cell lines by inducing apoptosis [Goodell, J.R. et al., 2008. J. Med. Chem. 51, 179-182.]. To further investigate their antiproliferative activities, we have assessed the antiproliferative activity of these acridine-based compounds against several pancreatic cancer cell lines. All four compounds used in this study inhibited the proliferation of pancreatic cancer cell lines in vitro. In addition, we have employed a xenograft tumor model and found that these compounds also inhibit the proliferation of pancreatic cancer in vivo. In light of the potential importance of the anticancer activity of these acridine-based compounds, we have conducted a series of biochemical assays to determine the effect of these compounds on human topoisomerase II. Unlike amsacrine, these compounds do not poison topoisomerase II. Similar to amsacrine, however, these compounds intercalate into DNA in a way that they would alter the apparent topology of the DNA substrate. Thus, inhibition of the relaxation activity of topoisomerase II by these compounds has been reexamined using a DNA strand passage assay. We have found that these compounds, indeed, inhibit the catalytic activity of topoisomerase II. Thus, these novel acridine-based compounds with anti-pancreatic cancer activity are catalytic inhibitors, not poisons, of human topoisomerase II. acridine derivative anticancer drug cancer catalytic inhibitor DNA intercalation topoisomerase
53	Proximity Mechanisms in Graphene: Insights from Density Functional Theory Alattas, Maha H. 27 November 2018 (has links) One of the challenges in graphene fabrication is the production of large scale, high quality sheets. To study a possible approach to achieve quasi-freestanding graphene on a substrate by the intercalation of alkali metal atoms, Cs intercalation between graphene and Ni(111) is investigated. It is known that direct contact between graphene and Ni(111) perturbs the Dirac states. Cs intercalation restores the linear dispersion characteristic of Dirac fermions, which agrees with experiments, but the Dirac cone is shifted to lower energy, i.e., the graphene sheet is n-doped. Cs decouples the graphene sheet, while the spin polarization of Ni(111) does not extend through the intercalated atoms to the graphene sheet, for which we find virtually spin-degeneracy. In order to employ graphene in electronic applications, one requires a finite band gap. We engineer a band gap in metallic bilayer graphene by substitutional B and/or N doping. Specifically, the introduction of B-N pairs into bilayer graphene can be used to create a band gap that is stable against thermal fluctuations at room temperature. Introduction of B-N pairs into B and/or N doped bilayer graphene likewise hardly modifies the band dispersions, however, the size of the band gap is effectively tuned. We also study the influence of terrace edges on the electronic properties of graphene, considering bare edges and H, F, Cl, NH2 terminations. Periodic structural reconstruction is observed for the Cl and NH2 edge terminations due to interaction between the terminating atoms/groups. We observe that Cl edge termination p-dopes the terraces, while NH2 edge termination results in n-doping. Graphene Doping Intercalation 2D Graphene Nanoribbons Electronic Band Structure
54	Using Electrochemical Method to Study the Interaction Between DNA and a compound Known to Have Anticancer Property. Kamasah, Alexander 17 December 2011 (has links) (PDF) The interaction of 4-(1'-[8'-(1''-pyrenyl)naphthyl])-2,6-diaminopyridine bis-glycamide bishydrocholride known to have anticancer properties with deoxyribonucleic acid (DNA) had been studied on a modified gold electrode by self-assembled monolayer using cyclic voltammetry. K4Fe (CN)6 was used as a probe to obtain electrochemical information on the electrode surface. A bare gold (Au) electrode was modified with cysteamine and our results showed no change in the limiting steady state current as compared to the bare Au electrode. There was a reduction in the steady state current after the modification of the gold electrode with DNA. Immobilization of the DNA modified gold electrode with the anticancer compound also revealed a further reduction in the steady state current. The reduction in the steady state current is attributed to the receptor and DNA forming a nonelectrochemical complex due to the intercalation of the receptor and DNA on the gold electrode surface. DNA Modified Electrode Intercalation Chemistry Physical Sciences and Mathematics
55	Recherche d'interacteurs de Myosine II au cours de l'intercalation cellulaire chez l'embryon de Drosophila melanogaster Aubry, Aurélie 08 December 2011 (has links) Un tissu épithélial est composé de cellules polarisées, étroitement liées les unes aux autres par des jonctions adhérentes. La perte de ces jonctions adhérentes est la première étape dans le développement des cancers au niveau des tissus épithéliaux. Il est donc important de comprendre les mécanismes d’attachement inter-cellulaire. Pour étudier ces interactions, nous utilisons comme modèle l’embryon de drosophile, où une fine régulation des jonctions adhérentes est requise pour l’une des étapes précoces de développement. Durant cette étape du développement, les cellules épithéliales changent de voisines le long de l’axe antéro-postérieur sans perdre leur adhérence cellulaire. Ce processus d’intercalation cellulaire est dû au recrutement polarisé du moteur moléculaire Myosine II au niveau des jonctions qui se désassemblent. Il a été mis en évidence qu’au cours de ce processus la perte de fonction de la voie JAK/STAT perturbe la localisation de la Myosine II. Au cours de ma thèse, j’ai réalisé un crible génétique dans un contexte mutant pour le ligand de la voie JAK/STAT pour me permettre d’identifier des interacteurs potentiellement impliqués dans le contrôle spatial de Myosine II. J’ai pu mettre en évidence plusieurs gènes pouvant être impliqués dans cette intercalation. Parmi ces candidats, je me suis focalisée sur celui montrant le plus fort phénotype : le gène CG13992. La caractérisation de ce gène a fut la seconde étape de mon travail de thèse (car seules les séquences nucléotidiques et protéiques étaient connues). Les résultats obtenus ont permis de mettre en évidence l’implication de ce gène dans la localisation de la Myosine II mais ils restent à confirmer. / Epithelial tissue is composed of polarized cells, which are closely attached to each other by adherens junctions. The loss of adherens junctions is often a key step in the development of cancer in epithelial tissues. It is therefore important to understand the mechanisms of attachment between the cells. To study such epithelial plasticity, we use the Drosophila embryo as a model system, where a fine regulation of adherens junctions is required for one of the early processes of development: germ band elongation. During this process, epithelial cells change their neighbors along the anterior-posterior axis (cell cell intercalation) without loss of cell adhesion. Polarized recruitment of the molecular motor Myosin II at the junctions, that disassemble and reassemble, underlies the intercalation process. In part, intercalation relies on the normal activity of the the JAK / STAT pathway that is crucial for the spatial control of Myosin II. During my PhD, I conducted a genetic screen, in a mutant for the ligand of the JAK / STAT pathway, designed to identify second site interactors for Myosin II control. I identified several genes that appear to be involved in the intercalation process. Among these candidates, I focused on one with the strongest phenotype: the gene CG13992. The functional characterization of this gene was the second stage of my thesis (because only the nucleotide and the protein sequences were known). Preliminary results highlight the involvement of this gene in the localization of Myosin II that remain to be confirmed. Drosophila melanogaster Morphogenèse Épithélium Intercalation cellulaire Myosine II. Drosophila melanogaster Morphogenesis Epithelium Cell cell intercalation Myosin II.
56	Étude d'inhibiteurs de corrosion métallique à base d'orthophosphates de zirconium lamellaires fonctionnalisés : synthèse, caractérisations et applications / Study of metal corrosion inhibitors based on functionalized lamellar zirconium orthophosphate : synthesis, characterizations and applications Bouali, Imane 10 July 2018 (has links) Le travail de cette thèse vise le développement de systèmes intelligents d'inhibiteurs de corrosion à base d'un composé lamellaire de type orthophosphate de zirconium α-ZrP. Le principe repose sur le fait que le α-ZrP joue le rôle de microréservoir de sorte à stocker des entités d’inhibiteurs de la corrosion métallique. Les espèces inhibitrices à base de cations Ca2+, Mg2+ et Zn2+ ont pu être incorporées avec succès au sein des espaces interfeuillets de α-ZrP via des réactions d’échanges cationiques avec les protons labiles H+. De même, des entités de l’anion heptanoate ont pu être insérées via l’intercalation préalable du biopolymère cationique chitosane. Par ailleurs, l’intercalation des entités organiques telles que le 2-aminobenzimidazole et la dodécylamine a pu être achevée par des réactions acido-basiques avec les protons H+. Les caractérisations des matériaux avant et après fonctionnalisation par différentes techniques analytiques ont montré que l’ensemble de ces modifications a donné lieu au développement de matériaux hybrides inorgano-inorganiques ou organo-inorganiques. L’évaluation de leurs performances inhibitrices de la corrosion a été accomplie en utilisant des techniques électrochimiques stationnaires et dynamiques. Elles ont révélé que ces pigments, une fois utilisés soit à l’état libre dans le milieu corrosif soit dispersés dans des peintures, améliorent les performances d'inhibition de la corrosion du zinc et de l'acier doux par rapport aux composés commerciaux en relargant les entités intercalées et retenant les entités corrosives. Ceci permet d’assurer la longévité de l’action inhibitrice de la corrosion des substrats métalliques en milieu aqueux / This thesis generally aims at the development of corrosion inhibitors based on a lamellar compound, namely zirconium orthophosphate (α-ZrP). The principle consists in that α-ZrP acts as micro-tanks in such a way to store species of several compounds known for their metallic corrosion inhibition properties. On the other hand, inhibitive species based on Ca2+, Mg2+, and Zn2+ were be able to be successfully incorporated within α-ZrP interlayer spaces via cationic exchange with labile H+ protons. Similarly, entities of the heptanoate anion were inserted via the prior intercalation of the cationic biopolymer chitosan. Nevertheless, the intercalation of organic species such as 2-aminobenzimidazole, dodecylamine was accomplished via acid-basic reaction between –NH2 groups and H+ protons. The characterizations of the materials before and after functionalization by different analytical techniques denote that all these modifications give rise to inorgano-inorganic or organo-inorganic hybrid materials. The evaluation of their performances, in term of metallic corrosion inhibition, was performed by using stationary or dynamic electrochemical techniques. It has been shown that the use of these pigments in corrosive medium, either alone or dispersed in paints, improves corrosion inhibition of zinc and mild steel thanks to the progressive release of intercalated species compensated by the retention of corrosive entities better than those induced by commercial products. This in final allows lengthening the inhibition action of metallic substrates against aqueous corrosion Orthophosphate de zirconium Phosphate Lamellaire Intercalation Inhibiteurs de corrosion Revêtement Zirconium orthophosphate Lamellar Intercalation Corrosion inhibitors Coating 620.112 23
57	Epitaxial graphene on metal for new magnetic manometric systems / Graphène épitaxié sur métal pour nouveaux systèmes magnétiques nanométriques Vo Van, Chi 19 March 2013 (has links) Graphène est un candidat pour la préparation de dispositifs spintroniques de nouvelle génération tirant partie de sa grande longueur de diffusion de spin et de la grande mobilité de ses porteurs de charge. En interagissant avec matériau ferromagnétique, il pourrait en outre devenir un élément actif, comme le suggèrent des études récentes par physique des surfaces, qui mettent en évidence un moment magnétique de quelques fractions de magnéton de Bohr dans le graphène en contact avec du fer, et une séparation en spin des bandes électroniques du graphène, d'environ 10 meV, par un effet Rashba au contact d'un élément de grand numéro atomique (l'or). La façon dont le graphène peut influencer les propriétés, par exemple magnétiques, des matériaux qui y sont contactés, reste peu étudiée. Les systèmes hybrides de haute qualité, constitués de graphène en contact avec des couches minces magnétiques ou des plots de taille nanométrique, sont des terrains de jeu pour explorer les deux aspects, la manipulation des propriétés du graphène par son interaction avec d'autres espèces, et vice versa. Dans le graphène contacté à des couches magnétiques ultra-minces par exemple, de forts effets d'interface pourraient être exploités pour contrôler l'aimantation du matériau magnétique. L'auto-organisation quasi-parfaite récemment découverte pour des plots nanométriques sur graphène, pourrait permettre d'explorer les interactions magnétiques, potentiellement transmises par le graphène, entre plots. Trois systèmes hybrides de haute qualité, intégrant du graphène préparé par dépôt chimique en phase vapeur sur le surface (111) de l'iridium, ont été développés sous ultra-haut vide (UHV) : des films ultra-minces de cobalt déposés sur graphène, et intercalés à température modérée entre graphène et son substrat, ainsi que des plots nanométriques riches-Co et -Fe, organisés avec une période de 2.5 nm sur le moiré entre graphène et Ir(111). Auparavant, des films de 10 nm d'Ir(111), monocristallins, déposés sur saphir, ont été développés. Ces films ont été par la suite utilisés comme substrats en remplacement de monocristaux massifs d'Ir(111). Ces nouveaux substrats ont ouvert la voie à des caractérisations multi-techniques ex situ, peu utilisées jusqu'alors pour étudier les systèmes graphène/métaux préparés sous UHV. Au moyen d'une combinaison de techniques de surface in situ et de sondes ex situ, les propriétés structurales, vibrationnelles, électroniques et magnétiques des trois nouveaux systèmes hybrides ont été caractérisées et confrontées à des calculs ab initio. Un certain nombre de propriétés remarquables ont été mises en évidence. L'interface entre graphene et cobalt implique de fortes interactions C-Co qui conduisent à une forte anisotropie magnétique d'interface, capable de pousser l'aimantation hors de la surface d'un film ultra-mince en dépit de la forte anisotropie de forme dans ces films. Cet effet est optimum dans les systèmes obtenus par intercalation entre graphène et iridium, qui sont par ailleurs naturellement protégés des pollutions de l'air. Les plots nanométriques, au contraire, semblent peu interagit avec le graphène. Des plots comprenant environ 30 atomes restent superparamagnétiques à 10 K, n'ont pas d'anisotropie magnétique, et leur aimantation est difficile à saturer, même sous 5 T. D'autre part, la taille des domaines magnétiques semble dépasser celle d'un plot unique, ce qui pourrait être le signe d'interactions magnétiques entre plots. / Graphene is a candidate for next generation spintronics devices exploiting its long spin transport length and high carrier mobility. Besides, when put in interaction with a ferromagnet, it may become an active building block, as suggested by recent surface science studies revealing few tenth of a Bohr magneton magnetic moments held by carbon atoms in graphene on iron, and a Rashba spin-orbit splitting reaching about 10 meV in graphene on a high atomic number element such as gold. The extent to which graphene may influence the properties, e.g. magnetic ones, of the materials contacted to it was barely addressed thus far. High quality hybrid systems composed of graphene in contact with magnetic thin layers or nanoclusters are playgrounds for exploring both aspects, the manipulation of the properties of graphene by interaction with other species, and vice versa. In graphene contacted to ultra-thin ferromagnetic layers for instance, strong graphene/ferromagnet interface effects could be employed in the view of manipulating the magnetization in the ferromagnet. The recently discovered close-to-perfect self-organization of nanoclusters on graphene, provides a way to probe magnetic interaction between clusters, possibly mediated by graphene. Three high quality hybrid systems relying on graphene prepared by chemical vapor deposition on the (111) surface of iridium have been developed under ultra-high vacuum (UHV): cobalt ultra-thin and flat films deposited on top of graphene, and intercalated at moderate temperature between graphene and its substrate, and self-organized cobalt- and iron-rich nanoclusters on the 2.5 nm-periodicity moiré between graphene and Ir(111). Prior to these systems, 10 nm-thick Ir(111) single-crystal thin films on sapphire were developed: they were latter employed as a substrate replacing bulk Ir(111) single-crystals usually employed. This new substrate opens the route to multi-technique characterizations, especially ex situ ones which were little employed thus far for studying graphene/metal systems prepared under UHV. Using a combination of in situ surface science techniques (scanning tunneling microscopy, x-ray magnetic circular dichroism, spin-polarized low-energy electron microscopy, auger electron spectroscopy, reflection high-energy electron diffraction) and ex situ probes (x-ray diffraction, transmission electron microscopy, Raman spectroscopy, MOKE magnetometry) the structural, vibrational, electronic, and magnetic properties of the three new graphene hybrid systems were characterized and confronted to first-principle calculations. Several striking features were unveiled. The interface between graphene and cobalt involves strong C-Co interactions which are responsible for a large interface magnetic anisotropy, capable of driving the magnetization out-of-the plane of the surface of an ultra-thin film in spite of the strong shape anisotropy in such films. The effect is maximized in the system obtained by intercalation between graphene and iridium, which comes naturally air-protected. Nanoclusters, on the contrary, seem to weakly interact with graphene. Small ones, comprising ca. 30 atoms each, remain super paramagnetic at 10 K, have no magnetic anisotropy, and it turns out difficult, even with 5 T fields to saturate their magnetization. Besides, the magnetic domains size seem to exceed the size of a single cluster, possibly pointing to magnetic interactions between clusters. Graphène Anisotropie magnétique perpendiculaire Intercalation Plots Auto-organisation Couches minces Graphene Perpendicular magnetic anisotropy Intercalation Clusters Self-organization Thin fillms
58	Surface Engineering and Synthesis of Graphene and Fullerene Based Nanostructures Gnanaprakasa, Tony Jefferson January 2016 (has links) Graphene is a two-dimensional carbon structure that exhibits remarkable structure-property relations. Consequently, there has been immense effort undertaken towards developing methods for graphene synthesis. Chemical vapor deposition (CVD) and chemical exfoliation from colloidal suspensions are two common methods used for obtaining graphene films. However, the underlying experimental conditions have to be carefully optimized in order to obtain graphene films of controllable thickness and morphology. In this context, a significant part of this dissertation was devoted towards developing and improving current CVD-based and chemical exfoliation based methods for synthesizing high quality graphene films. Specifically, in the CVD based procedure for growing graphene on copper, the effect of surface pretreatment of copper was investigated and the quality of graphene grown using two different pretreatment procedures was compared and analyzed. In particular, graphene grown on electropolished copper (EP-Cu) was analyzed with respect to its surface morphology, surface roughness and thickness, and compared with graphene grown on as cold-rolled acetic acid cleaned copper (AA-Cu). It was shown that electropolishing of the Cu substrates prior to graphene growth greatly enhanced the ability to obtain flat, uniform, predominantly single layer graphene surface coverage on copper. The reported surface roughness of the graphene on EP-Cu was found to be much lower than for previously reported systems, suggesting that the electropolishing procedure adopted in this work has great promise as a pretreatment step for Cu substrates used in CVD growth of graphene. Obtaining graphene from colloidal suspensions of graphitic systems was also examined. In this work, an acid (H₂SO₄ + HNO₃) treatment process for intercalating natural graphite flakes was examined and the ability to reversibly intercalate and deintercalate acid ions within graphitic galleries was investigated. More importantly, a rapid-thermal expansion (RTP) processing was developed to thermally expand the acid-treated graphite, followed by exfoliation of predominantly bilayer graphene as well as few layer graphene flakes in an organic solvent (N, N-Dimethylformamide - DMF). The developed method was shown to provide bilayer and few layer graphene flakes in a reliable fashion. Fullerene is another carbon nanostructure that has garnered attention due to unique structure and chemical properties. Recently, there has been increased focus towards harnessing the properties of fullerenes by synthesizing fullerene self-assemblies in the form of extended rods, tubes and more complex shapes. Current methods to synthesize these self-assemblies are either cumbersome, time consuming or expensive. In this context, an alternate, straightforward dip-coating procedure technique to self-assemble equal-sized, faceted, polymerized fullerene nanorods on graphene-based substrates in a rapid fashion was developed. By suitably modifying the kinetics of self-assembly, the ability to reliably control the spatial distribution, size, shape, morphology and chemistry of fullerene nanorods was achieved. Fullerene based Superstructures Graphene Self-assembly of Nanomaterials Synthesis of Carbon Nanostructures Materials Science & Engineering Chemical Vapor Deposition
59	Électrochimie et spectroscopie Raman de matériaux d’électrode positive pour batteries Li-ion / Electrochemistry and Raman study of positive electrode as materials for Li-ion batteries Dridi Zrelli, Yosra 08 November 2012 (has links) Dans ce travail de thèse, la microspectrométrie Raman a été mise à profit pour décrire les changements structuraux induits par la réaction électrochimique d'insertion/désinsertion des ions lithium dans des composés de structure lamellaire LiCoO2 et cubique LiMn2O4 et LiNi0.4Mn1.6O4, utilisés comme électrodes positives dans les batteries Li-ion. L'étude du composé d'électrode LiCoO2 pendant le processus de charge permet de mettre en évidence une région biphasée où la phase initiale coexiste avec une nouvelle phase hexagonale caractérisée par une expansion du paramètre inter-feuillets de l'ordre de 3% et un affaiblissement de la liaison Co-O dans le plan des feuillets. Dans le cas de LiMn2O4, une nouvelle attribution du spectre Raman a pu être proposée. Pendant la charge à 4V, un mécanisme à trois phases (phase initiale LiMn2O4, phase intermédiaire, phase pauvre en lithium) est décrit par spectroscopie Raman alors que la diffraction des RX ne permet pas d'observer la phase intermédiaire dans nos conditions de mesure. L'étude de l'insertion électrochimique du lithium dans LiMn2O4 (région 3V), a permis de montrer pour la première fois par spectroscopie Raman la formation progressive d'une phase tétragonale de composition Li2Mn2O4 qui coexiste avec la phase cubique initiale et qui est pure en fin de décharge. La réversibilité de cette transition structurale a également été démontrée. Dans le cas du composé substitué au nickel, LiNi0.4Mn1.6O4, une attribution complète du spectre Raman est proposée pour la première fois. L'étude par diffraction des RX du matériau en fonction de l'état de charge et de décharge met en évidence une conservation de la structure cubique avec des variations modérées de paramètres de maille. Le spectre Raman présente quant à lui des variations très significatives qui rendent compte de la présence dans des proportions différentes des espèces redox impliquées dans le fonctionnement électrochimique (Mn4+, Mn3+, Ni2+, Ni3+, Ni4+). Une analyse spectrale par décompositions de bandes permet d'identifier et de quantifier les proportions relatives des différents couples redox du nickel. Une réversibilité complète de la signature Raman est observée en décharge. Une application concrète et originale de la spectroscopie Raman a consisté à étudier le mécanisme d'autodécharge qui est observé pour le matériau LiNi0.4Mn1.6O4 complètement chargé. L'évolution des spectres Raman permet de mettre en évidence une réduction rapide et quantitative des ions Ni4+ pendant les premières heures de séjour dans l'électrolyte, puis un processus plus lent de réduction des ions Ni3+. Enfin, pour la première fois également, l'insertion du lithium dans le composé LiNi0.4Mn1.6O4 a été explorée par microspectrométrie Raman et a permis notamment d'identifier l'empreinte Raman de la phase la plus réduite de symétrie tétragonale Li2Ni0.4Mn1.6O4. L'originalité de ce travail a été d'apporter un grand nombre de données Raman expérimentales sur des matériaux d'électrode performants fonctionnant à 4V. De nouvelles attributions ont pu être proposées pour les composés initiaux, et des données vibrationnelles inédites ont été fournies sur les composés formés en charge et en décharge. Dans certains cas, ces données ont permis, sur la base d'une analyse détaillée des spectres Raman par décompositions de bandes, de proposer un raisonnement quantitatif sur l'existence de phases ou d'espèces redox en mélange. Il conviendrait bien sûr de corroborer ces nouvelles données et attributions par des calculs théoriques ab initio capables de simuler les fréquences et les intensités des modes vibrationnels dans les structures hôtes et lithiées / In this work, we show the relevance of Raman spectroscopy as a useful technique to investigate the local changes induced by the electrochemical reaction of intercalation/deintercalation of lithium in positive electrode materials for rechargeable lithium ion batteries.Raman investigations concern three types of high voltage cathode materials (4-5Volts) which are layered LiCoO2 and cubic LiMn2O4 and LiNi0.4Mn1.6O4.During electrochemical deintercalation of LiCoO2, we show the existence of a two phase region where the initial hexagonal phase coexist with a second hexagonal phase with a 3% expansion of the lattice parameter indicating a weakening of the Co-O bond in the Li1-xCoO2 material.On the other hand, a new assignment of LiMn2O4 Raman spectrum was proposed. During the charge in the 4V region, a three region phase (initial LiMn2O4 phase, intermediary phase and poor lithium phase) was described using Raman spectroscopy. RX measurements can not detect this intermediary phase. Lithiated phase Raman signature shows a specific local order: Fd3m for extreme phases and F43m for partially lithiated phase. A rich Raman band spectrum is attributed to this later phase in coherence with literature calculations. Structural changes reversibility is demonstrated. Identification of this intermediary phase as a major component of a cycled electrode, underline the incomplete reduction and explain the important loss of capacity observed during cycling. Raman study of LiMn2O4 electrochemical insertion in the 3V region, has demonstrated for the first time a progressive formation of tetragonal Li2Mn2O4 phase, which is in coexistence with initial cubic phase and is pure at the end of discharge. Structural transition reversibility was also demonstrated.In the case of LiNi0.4Mn1.6O4, the assignment of the Raman spectrum of LiNi0.4Mn1.6O4 is provided for the first time. DRX study in function of the state of charge and discharge, exhibit cubic structure conservation with moderate lattice parameters variations. The Raman spectrum of the spinel oxide exhibits drastic spectral changes during Li extraction. These changes have been directly related to the Mn and Ni oxidation states in the cathode material under operation. It comes out that electrochemical reactions of LiNi0.4Mn1.6O4 are reversible and based on three redox couples of Mn3+/Mn4+, Ni2+/Ni3+, and Ni3+/Ni4+. An original and concrete Raman spectroscopy application is the study of self discharge mechanism of completely charged LiNi0.4Mn1.6O4. Raman spectra evolution exhibits a quantitative Ni4+ reduction during the first hours, and then a slower Ni3+ reduction process. Finally, LiNi0.4Mn1.6O4 lithium insertion has been explored for the first time using Raman spectroscopy, and a tetragonal Li2Ni0.4Mn1.6O4 phase has been identified.The originality of this work is the important number of experimental Raman data of 4V electrode materials. New assignment of initial compound has been proposed and original vibrationnal data of compound during charge/discharge has been presented. These Raman data has permitted to propose a quantitative explanation which must be completed with ab initio calculations to simulate vibrationnal modes frequencies/ intensities Spectroscopie Raman Electrochimie Diffraction des Rayons X Intercalation lithium Batterie lithium ion Structure Raman spectroscopy Electrochemistry Xray diffraction Lithium intercalation Lithium ion batterie Structure
60	Investigação dos processos de intercalação e esfoliação de hexaniobato lamelar e preparação de materiais híbridos com biopolímeros / Investigation of the intercalation and exfoliation processes of layered hexaniobate and preparation of hybrid materials with biopolymers Shiguihara, Ana Lucia 01 September 2010 (has links) A presente tese tem como objetivo principal a investigação do processo de intercalação e esfoliação do hexaniobato lamelar em soluções de hidróxidos de tetraalquilamônios e, também, do emprego das partículas do niobato na preparação de materiais híbridos com polissacarídeos. O material de composição H2K2Nb6O17 foi suspenso em soluções aquosas contendo diferentes concentrações dos hidróxidos de tetrametilamônio (TMA+), tetraetilamônio (TEA+) e tetrapropilamônio (TPA+). Após o tempo de reação foram separadas duas frações: o sólido depositado no recipiente e o sobrenadante turvo contendo as partículas não depositadas de características coloidais. Os resultados de difratometria de raios X, análise termogravimétrica, análise elementar, espectroscopia vibracional no infravermelho e Raman mostram que o processo de intercalação é promovido segundo a ordem: TMA+ > TEA+ > TPA+, isto é, a intercalação é facilitada para íons pouco volumosos. Já o processo de esfoliação do hexaniobato é promovido na ordem inversa: TPA+ » TEA+ > TMA+, ou seja, quanto mais volumoso o íon tetraalquilamônio, maior a extensão do processo de separação das lamelas. A formação das partículas cilíndricas, presentes em maior quantidade nas amostras tratadas com soluções de TPA+ e TBA+, é favorecida pelo aumento do tamanho da cadeia carbônica e da concentração das soluções do hidróxido. Além dos processos de intercalação ou esfoliação, observou-se o processo de formação de gel na etapa de remoção de eletrólitos na lavagem dos sólidos depositados. O entumescimento das lamelas empilhadas de hexaniobato é favorecido para amostras intercaladas com íons TEA+; possivelmente esses íons possuem a melhor relação entre hidrofilicidade e tamanho, promovendo a formação de gel. O composto contendo íons TEA+ intercalados no hexaniobato ácido foi empregado na preparação de material híbrido contendo o polissacarídeo quitosana intercalado na matriz inorgânica, com o objetivo de modificar a superfície do hexaniobato para promover a compatibilização com o amido e a formação de nanocompósitos. Filmes de amido desestruturado contendo partículas de hexaniobato foram preparados por casting. Para alcançar alto grau de dispersão da partícula inorgânica no polímero, três tipos de partículas de hexaniobato foram empregadas: (i) partículas esfoliadas com n-butilamina, (ii) partículas altamente hidratadas de TEA+-hexaniobato e (iii) partículas modificadas pela intercalação com quitosana. As técnicas de difratometria de raios X, análise termogravimétrica acoplada à espectrometria de massa, espectroscopia vibracional no infravermelho e microscopia eletrônica de varredura sugerem que nos filmes transparentes e flexíveis obtidos, a matriz lamelar se encontra preferencialmente na forma intercalada. Os resultados preliminares de análise dinâmico-mecânica sugerem a seguinte tendência no comportamento mecânico dos filmes: a adição do hexaniobato torna os filmes de amido mecanicamente mais resistentes e as amostras sem o plastificante glicerol apresentam maior resistência e menor deformação que aquelas com glicerol. / The main aim of this Thesis is the investigation of intercalation and exfoliation processes occurring when the layered material H2K2Nb6O17 is suspended in alkaline solutions containing tetramethylammonium (TMA+), tetraethylammonium (TEA+) or tetrapropylammonium (TPA+) cations, as well as the employment of the hexaniobate particles in the preparation of hybrid materials with polysaccharides. After the reaction using different concentrations of the tetraalkylammonium hydroxide solutions, two fractions were separated: the deposited solid (i.e. the sediment at bottom of the flasks) and the opaque supernatant containing particles with colloidal characteristics. Experimental data from X-ray diffractometry (XRD), mass spectrometry coupled thermogravimetric analyses (TG-MS), elemental analysis, vibrational infrared (IR) and Raman spectroscopies show that intercalation reaction is promoted in the order TMA+ > TEA+ > TPA+ while exfoliation process is facilitated in the inverse order: TPA+ » TEA+ > TMA+. Development of particles with stick-like shapes is observed when H2K2Nb6O17 is kept mainly in the solutions containing the larger TPA+ and TBA+ ions. Samples containing intercalated TEA+ ions form a gel-like system when washed to remove the non-intercalated ions dissolved in water. Experimental data suggest that the gel phase constituted by long-range swelled particles. This fact was interpreted as a consequence of the intermediate characteristics (surface polarity and ion radius) of the TEA+ ions compared to the others ions investigated in this study. The hexaniobate material intercalated with TEA+ ions was used to prepare a hybrid material having the chitosan polymer intercalated into the inorganic matrix in order to compatibilize the hexaniobate particles with starch and a nanocomposite formation. The study of the films of starch-niobate showed that the matrix is in the intercalation form preferentially, even using different exfoliation agents and modification species (n-butylamine, TEAOH and chitosan). Films of destructured starch having hexaniobate particles were prepared by casting method. In order to reach a high level of inorganic particles dispersed in the polymer, three kinds of hexaniobate particles were used: (i) particles exfoliated with n-butylamine, (ii) hydrated particles of TEA+-hexaniobate and (iii) hexaniobate particles intercalated with chitosan. XRD, TG-MS, IR, and scanning electron microscopy (SEM) techniques suggest that hexaniobate particles are mainly in the intercalated form in the transparent and flexible obtained starch films. Preliminary dynamic mechanical analysis data indicate the following general tendency in the mechanic characteristics of the films: niobate particles make the starch films more resistant and the samples without the glycerol plasticizer present higher resistance and lower deformation than the films with glycerol. Amido Biopolímeros Biopolymers Composites Compósitos Esfoliação Exfoliation Hexaniobato lamelar Hidróxido de teraalquilamônio Intercalação Intercalation Intercalation Chemistry Layered hexaniobate Química de intercalação Starch Tetraalkylammonium hydroxide

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