852 resultados para carbon nanotube
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Les expériences de spectroscopie ont été réalisées en collaboration avec Jean-François Allard du groupe de Denis Morris de l'Université de Sherbrooke.
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Les nanotubes de carbone forment une structure quasi-unidimensionnelle de diamètre nanométrique, dont les propriétés mécaniques et électroniques, en particulier leur remarquable conductivité électrique, présentent un grand potentiel pour la conception de dispositifs électroniques. Les nanotubes fonctionnalisés, c’est-à-dire dont la paroi a été chimiquement modifiée, présentent aussi un intérêt majeur pour leur mise en œuvre facilitée et pour la formation d’une interface active entre le nanotube et l’environnement, cette dernière étant essentielle pour la conception de nanocapteurs chimiques et biologiques. La présente thèse porte sur l’étude des mécanismes gouvernant le transport électrique dans les nanotubes de carbone et leurs dérivés fonctionnalisés. Les travaux, de nature expérimentale, ont été réalisés sur des dispositifs électroniques constitués d’un nanotube individuel monoparoi ou biparoi, additionné de groupes fonctionnels au besoin. En première partie, on s’intéresse à l’effet de la dimensionnalité sur les mécanismes d’injection des porteurs de charge au niveau des contacts électriques avec le nanotube. En seconde partie, on étudie l’effet de la fonctionnalisation covalente sur les propriétés de transport électrique des nanotubes, et on montre notamment que l’impact de l’addition des greffons varie fortement selon leur valence et qu’il est possible d’obtenir des nanotubes fonctionnalisés avec une bonne conductance. En troisième partie, on explore les phénomènes de saturation du courant et de claquage électrique survenant à haut voltage. Enfin, on discute de l’impact des résultats obtenus sur l’avancement de la compréhension des mécanismes de transport électrique dans les systèmes hautement confinés, ainsi que des perspectives fondamentales et technologiques ouvertes par ces travaux.
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Les nanotubes de carbone et le graphène sont des nanostructures de carbone hybridé en sp2 dont les propriétés électriques et optiques soulèvent un intérêt considérable pour la conception d’une nouvelle génération de dispositifs électroniques et de matériaux actifs optiquement. Or, de nombreux défis demeurent avant leur mise en œuvre dans des procédés industriels à grande échelle. La chimie des matériaux, et spécialement la fonctionnalisation covalente, est une avenue privilégiée afin de résoudre les difficultés reliées à la mise en œuvre de ces nanostructures. La fonctionnalisation covalente a néanmoins pour effet de perturber la structure cristalline des nanostructures de carbone sp2 et, par conséquent, d’affecter non seulement lesdites propriétés électriques, mais aussi les propriétés optiques en émanant. Il est donc primordial de caractériser les effets des défauts et du désordre dans le but d’en comprendre les conséquences, mais aussi potentiellement d’en exploiter les retombées. Cette thèse traite des propriétés optiques dans l’infrarouge des nanotubes de carbone et du graphène, avec pour but de comprendre et d’expliquer les mécanismes fondamentaux à l’origine de la réponse optique dans l’infrarouge des nanostructures de carbone sp2. Soumise à des règles de sélection strictes, la spectroscopie infrarouge permet de mesurer la conductivité en courant alternatif à haute fréquence des matériaux, dans une gamme d’énergie correspondant aux vibrations moléculaires, aux modes de phonons et aux excitations électroniques de faible énergie. Notre méthode expérimentale consiste donc à explorer un espace de paramètres défini par les trois axes que sont i. la dimensionnalité du matériau, ii. le potentiel chimique et iii. le niveau de désordre, ce qui nous permet de dégager les diverses contributions aux propriétés optiques dans l’infrarouge des nanostructures de carbone sp2. Dans un premier temps, nous nous intéressons à la spectroscopie infrarouge des nanotubes de carbone monoparois sous l’effet tout d’abord du dopage et ensuite du niveau de désordre. Premièrement, nous amendons l’origine couramment acceptée du spectre vibrationnel des nanotubes de carbone monoparois. Par des expériences de dopage chimique contrôlé, nous démontrons en effet que les anomalies dans lespectre apparaissent grâce à des interactions électron-phonon. Le modèle de la résonance de Fano procure une explication phénoménologique aux observations. Ensuite, nous établissons l’existence d’états localisés induits par la fonctionnalisation covalente, ce qui se traduit optiquement par l’apparition d’une bande de résonance de polaritons plasmons de surface (nanoantenne) participant au pic de conductivité dans le térahertz. Le dosage du désordre dans des films de nanotubes de carbone permet d’observer l’évolution de la résonance des nanoantennes. Nous concluons donc à une segmentation effective des nanotubes par les greffons. Enfin, nous montrons que le désordre active des modes de phonons normalement interdits par les règles de sélection de la spectroscopie infrarouge. Les collisions élastiques sur les défauts donnent ainsi accès à des modes ayant des vecteurs d’onde non nuls. Dans une deuxième partie, nous focalisons sur les propriétés du graphène. Tout d’abord, nous démontrons une méthode d’électrogreffage qui permet de fonctionnaliser rapidement et à haute densité le graphène sans égard au substrat. Par la suite, nous utilisons l’électrogreffage pour faire la preuve que le désordre active aussi des anomalies dépendantes du potentiel chimique dans le spectre vibrationnel du graphène monocouche, des attributs absents du spectre d’un échantillon non fonctionnalisé. Afin d’expliquer le phénomène, nous présentons une théorie basée sur l’interaction de transitions optiques intrabandes, de modes de phonons et de collisions élastiques. Nous terminons par l’étude du spectre infrarouge du graphène comportant des îlots de bicouches, pour lequel nous proposons de revoir la nature du mécanisme de couplage à l’œuvre à la lumière de nos découvertes concernant le graphène monocouche.
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Voltammetric sensors are an important class of electrochemical sensors in which the analytical information is obtained from the measurement of current obtained as a result of electrochemical oxidation/reduction.This current is proportional to the concentration of the analyte.Chemically modified electrodes(CMEs) have great significance as important analytical tools for the electrochemical determination of pharmaceuticals.The modification of electrode results in efficient determination of electro-active biomolecules at very lower potential without its major interferences.The operation mechanism of CMEs depends on the properties of the modifier materials that are used to promote selectivity towards the target analytes.Modified electrodes can be prepared by deposition of various compounds such as organic compounds ,conducting polymers,metal oxides,etc. on the various electrode surfaces.The thesis presents the development ,electrochemical characterization and analytical application studies of eight voltammetric sensors developed for six drugs viz.,Ambroxol,Sulfamethoxazole,PAM Chloride, Lamivudine,Metronidazole and Nimesulide.The modification techniques adopted as part of the present work include Multiwalled Carbon Nanotube(MWCNT) based modification.Electropolymerisation and Gold Nanoparticle (AuNP) based modifications.
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We have analyzed the shot noise of electron emission under strong applied electric fields within the Landauer-Bttiker scheme. In contrast to the previous studies of vacuum-tube emitters, we show that in new generation electron emitters, scaled down to the nanometer dimensions, shot noise much smaller than the Schottky noise is observable. Carbon nanotube field emitters are among possible candidates to observe the effect of shot-noise suppression caused by quantum partitioning.
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Electrochemical sensors are increasingly being investigated to perform measurements for single or multiple analytes. Demanded by modern medical diagnosis, advances in microfabrication technology have led to the development of fast, sensitive and selective electrochemical sensors for drug analysis. Electrochemical sensors for the measurement of analytes of interest in clinical chemistry are ideally suited for these applications, due to their high sensitivity and selectivity, simple-to-operate, rapid response time and low-cost. As part of the present investigations eight voltammetric sensors have been fabricated for six drugs such as PAM Chloride, Tamsulosin Hydrochloride, Hesperidin Methyl Chalcone, Guaiphenesin, Cephalexin and Amoxicillin trihydrate. The modification techniques adopted as part of the present work include multiwalled carbon nanotube (MWNT) based modifications, electropolymerization, gold nanoparticle (AuNP) based modifications and platinum nanoparticle (PtNP) based modifications. The thesis is divided into nine chapters
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The current research investigates the possibility of using unmodified and modified nanokaolin, multiwalled carbon nanotube (MWCNT) and graphene as fillers to impart enhancement in mechanical, thermal, and electrical properties to the elastomers. Taking advantage of latex blending method, nanoclay, MWCNT and graphene dispersions, prepared by ultra sound sonication are dispersed in polymer latices. The improvement in material properties indicated better interaction between filler and the polymer.MWCNT and graphene imparted electrical conductivity with simultaneous improvement in mechanical properties. Layered silicates prepared by microwave method also significantly improve the mechanical properties of the nanocomposites. The thesis entitled ‘Studies on the use of Nanokaolin, MWCNT and Graphene in NBR and SBR’ consists of ten chapters. The first chapter is a concise introduction of nanocomposites, nanofillers, elastomeric matrices and applications of polymer nanocomposites. The state-of-art research in elastomer based nanocomposites is also presented. At the end of this chapter the main objectives of the work are mentioned. Chapter 2 outlines the specifications of various materials used, details of experimental techniques employed for preparing and characterizing nanocomposites. Chapter3 includes characterization of the nanofillers, optimsation of cure time of latex based composites and the methods used for the preparation of latex based and dry rubber based nanocomposites. Chapter4 presents the reinforcing effect of the nanofillers in XNBR latex and the characterization of the nanocomposites. Chapter5 comprises the effect of nanofillers on the properties of SBR latex and their characterization Chapter 6 deals with the study of cure characteristics, mechanical and thermal properties and the characterization of NBR based nanocomposites. Chapter7 is the microwave studies of MWCNT and graphene filled elastomeric nanocomposites. Chapter 8 gives details of the preparation of layered silicates, their characterization and use in different elastomeric matrices. Chapter 9 is the study of mechanical properties of nanoclay incorporated nitrile gloves .Chapter 10 presents the summary and conclusions of the investigation.
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There is an enormous demand for chemical sensors in many areas and disciplines including chemistry, biology, clinical analysis, environmental science. Chemical sensing refers to the continuous monitoring of the presence of chemical species and is a rapidly developing field of science and technology. They are analytical devices which transform chemical information generating from a reaction of the analyte into an measurable signal. Due to their high selectivity, sensitivity, fast response and low cost, electrochemical and fluorescent sensors have attracted great interest among the researchers in various fields. Development of four electrochemical sensors and three fluorescent sensors for food additives and neurotransmitters are presented in the thesis. Based on the excellent properties of multi walled carbon nanotube (MWCNT), poly (L-cysteine) and gold nanoparticles (AuNP) four voltammetric sensors were developed for various food additives like propyl gallate, allura red and sunset yellow. Nanosized fluorescent probes including gold nanoclusters (AuNCs) and CdS quantum dots (QDs) were used for the fluorescent sensing of butylated hydroxyanisole, dopamine and norepinephrine. A total of seven sensors including four electrochemical sensors and three fluorescence sensors have been developed for food additives and neurotransmitters.
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The electrochemical oxidation of promethazine hydrochloride was made on highly boron-doped diamond electrodes. Cyclic voltammetry experiments showed that the oxidation mechanisms involved the formation of an adsorbed product that is more readily oxidized, producing a new peak with lower potential values whose intensity can be increased by applying the accumulation potential for given times. The parameters were optimized and the highest current intensities were obtained by applying +0.78 V for 30 seconds. The square-wave adsorptive voltammetry results obtained in BR buffer showed two well-defined peaks, dependent on the pH and on the voltammetric parameters. The best responses were obtained at pH 4.0, frequency of 50 s(-1), step of 2 mV, and amplitude of 50 mV. Under these conditions, linear responses were obtained for concentrations from 5.96 x 10(-7) to 4.76 x 10(-6) mol L-1, and calculated detection limits of 2.66 x 10(-8) mol L-1 (8.51 mu g L-1) for peak 1 and of 4.61 x 10(-8) mol L-1 (14.77 mu g L-1) for peak 2. The precision and accuracy were evaluated by repeatability and reproducibility experiments, which yielded values of less than 5.00% for both voltammetric peaks. ne applicability of this procedure was tested on commercial formulations of promethazine hydrochloride by observing the stability, specificity, recovery and precision of the procedure in complex samples. All results obtained were compared to recommended procedure by British Pharmacopeia. The voltammetric results indicate that the proposed procedure is stable and sensitive, with good reproducibility even when the accumulation steps involve short times. It is therefore very suitable for the development of the electroanalytical procedure, providing adequate sensitivity and a reliable method.
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The self-assembly of short amino acid chains appears to be one of the most promising strategies for the fabrication of nanostructures. Their solubility in water and the possibility of chemical modification by targeting the amino or carboxyl terminus give peptide-based nanostructures several advantages over carbon nanotube nanostructures. However, because these systems are synthesized in aqueous solution, a deeper understanding is needed on the effects of water especially with respect to the electronic, structural and transport properties. In this work, the electronic properties of l-diphenylalanine nanotubes (FF-NTs) have been studied using the Self-Consistent Charge Density-Functional-based Tight-Binding method augmented with dispersion interaction. The presence of water molecules in the central hydrophilic channel and their interaction with the nanostructures are addressed. We demonstrate that the presence of water leads to significant changes in the electronic properties of these systems decreasing the band gap which can lead to an increase in the hopping probability and the conductivity. © the Owner Societies 2013.
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In this report, hierarchical ZnO nano- and microstructures were directly grown for the first time on a bacterial cellulose substrate and on two additional different papers by hydrothermal synthesis without any surface modification layer. Compactness and smoothness of the substrates are two important parameters that allow the growth of oriented structures. © 2013 The Royal Society of Chemistry.
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Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)
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Falhas inesperadas em transformadores levaram a identificação da formação de sulfeto de cobre, depositado sobre os condutores, avaliando-se da presença qualitativa de enxofre corrosivo resultando na alteração da norma brasileira ABNT NBR 10505, que avalia a presença de enxofre corrosivo em óleo mineral, alterando-se o tempo e a temperatura de ensaio para 150 °C por 48 horas. Realizando-se a especiação química de compostos organosulfurados via cromatografia gasosa acoplada a espectrometria de massas, onde foram encontrados 13 compostos sulfurados no óleo Nynas e 9 compostos no óleo da Petrobras, sendo o dibenzil dissulfeto (DBDS) o de maior concentração, encontrado apenas no óleo Nynas. Para realizar a determinação da presença do DBDS em óleo mineral isolante foi desenvolvido um método através de cromatografia gasosa acoplada a espectrometria de massas, e por este método foi possível quantificar o teor de DBDS em amostras de OMI oriundas de transformadores de potência. Foi avaliado o processo de passivação do cobre por benzotriazol e tolutriazol, utilizados como aditivos anticorrosivos no núcleo dos equipamentos elétricos, verificando-se que o efeito da adição agente de passivação torna-se ineficaz com o passar do tempo. A solução para a remoção de DBDS em óleo mineral foi a utilização de nanotubo de carbono baseado em matriz metálica (NTC/Al) como agente de remoção do DBDS. Verificou-se que o agente de adsorção foi capaz de efetuar a remoção total do DBDS do OMI até um volume de 4000 mL de óleo contaminado com DBDS.
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A primeira parte deste trabalho aborda a simulação computacional de dinâmica molecular clássica da interação de sistemas matriciais constituídos de nanofios paralelos de Au simuladas em função do tempo. Como resultados foram encontrados os tempos de colisões entre os fios da matriz. A segunda parte deste trabalho utiliza dinâmica molecular clássica para simular cinco gerações de dendrímeros PAMAM, cada qual interagindo individualmente com um nanotubo de carbono em função do tempo resultando num motor molecular. Além disso, foram calculados os espectros de absorção deste sistema e foi verificado que eles são nanomotores controlados pela luz. Para todos estes sistemas foram calculadas energias cinética, potencial, total, velocidade, propriedades termodinâmicas como variação de entropia molar, capacidade molar térmica e temperatura in situ. Estas grandezas nos forneceram valiosas informações sobre o comportamento destes sistemas.
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Os nanotubos de carbono e nitreto de boro são nano estruturas unidimensionais que apresentam comportamento tanto metálico quanto semicondutor, dependendo da sua quiralidade, exceto para os nanotubos de nitreto de boro que apresentam sempre características semicondutoras, caso não estejam dopados. Devido suas características eletrônicas, os nanotubos apresentam grandes possibilidades de aplicação em dispositivos de nanoeletrônica, tais como nanodiodos, nanotransistores e como elementos de interconexão, dentre outros. Por esta razão, é importante compreender como fatores externos agem sobre as propriedades de tais materiais. Um desses fatores externos é a introdução de defeitos nos nanotubos. Tais defeitos são a ausência de um ou mais átomos de carbono, pertencente ao nanotubo de carbono e, de nitrogênio ou boro, para os nanotubos de nitreto de boro, ou ainda, a substituição de átomos de carbono, nitrogênio ou boro por diferentes átomos na estrutura dos correspondentes nanotubos. Este trabalho apresenta um estudo teórico dos efeitos da introdução de defeitos, por substituição, nas propriedades eletrônicas dos nanotubos de carbono e nitreto de boro, via simulação ab-initio. Avaliam-se as estruturas de banda de energia e densidade de estados de nanotubos de carbono semicondutores e metálicos tipos armchair e zig-zag e apenas do tipo armchair para os nanotubos de nitreto de boro usando o método LACW – método das ondas cilíndricas linearizadas aumentadas. Além disso, devido a crescente importância dos nanotubos de nitreto de boro, fazemos um estudo sistematizado da estrutura eletrônica desses nanotubos, para uma supercélula formada por três células unitárias, usando dopagem intrínseca, bem como uma análise quantitativa, baseada na energia total e banda proibida, de estabilidade dessas estruturas.