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591	Desenvolvimento de biossensores para a determinação da razão glutationa reduzida/oxidada utilizando plataformas à base de nanotubos de carbono dispersos em quitosana / Development of biosensors for the determination of oxidized/reduced glutathione ratio using platforms based on carbon nanotubes dispersed in chitosan Corrêa, Cátia Crispilho, 1982- 23 August 2018 (has links) Orientadores: Lauro Tatsuo Kubota, André Luiz Barboza Formiga / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-23T02:11:05Z (GMT). No. of bitstreams: 1 Correa_CatiaCrispilho_D.pdf: 1212097 bytes, checksum: c6504372165b045433ebb0234876cf97 (MD5) Previous issue date: 2013 / Resumo: Este trabalho descreve o desenvolvimento de dois biossensores, sendo um para a detecção da glutationa oxidada (GSSG), baseada na imobilização da enzima glutationa redutase (GR) e outro para a detecção da glutationa total (glutationa reduzida e oxidada) através da imobilização das enzimas glutationa redutase e glutationa peroxidase (GPx). Ambas as imobilizações foram realizadas sobre uma plataforma nanoestruturada com nanotubos de múltiplas paredes (MWCNT), dispersos em quitosana ligada covalentemente a um mediador de elétrons, o ácido 3,5-dinitrobenzoico, que apresentou atividade eletrocatalítica para NADH. A plataforma nanoestruturada foi caracterizada por microscopia eletrônica de varredura (MEV), voltametria cíclica e cronoamperometria. Os valores de ks e da constante cinética da reação entre o mediador de elétrons e NADH (kobs) foram 14 s e 5,1x10 L mol s, respectivamente. Após o processo de ativação do par redox e da caracterização, a enzima GR foi facilmente imobilizada na superfície do eletrodo usando quitosana e glutaraldeído. Empregando medidas cronoamperométricas, foi possível analisar a influência de cada parâmetro utilizado na construção do biossensor para detecção de GSSG. As melhores condições para o emprego do biossensor foram: 50 unidades de GR, 2,5 mg mL de quitosana e 600 mmol L de NADH. O biossensor apresentou uma faixa linear de 2,0 a 35 mmol L para a detecção de GSSG. Já os limites de detecção e quantificação foram 0,6 e 2,0 mmol L, respectivamente. Utilizando a mesma plataforma nanoestruturada foi possível imobilizar as duas enzimas (GR e GPx), sendo esse biossensor destinado para a detecção da glutationa total (GSH+GSSG). Este biossensor apresentou uma faixa linear 2,0 a 10 mmol L para a detecção da glutationa total, apresentando um limite de detecção e de quantificação de 0,6 e 2,0 mmol L, respectivamente / Abstract: This work describes the development of two biosensors, one for the detection of oxidized glutathione (GSSG) based on the immobilization of glutathione reductase (GR) and other for the detection of total glutathione (glutathione reduced and oxidized) by immobilizing the enzymes glutathione peroxidase (GPx) and glutathione reductase (GR). Both assets were carried on a nanostructured platform with multiwalled carbon nanotubes (MWCNT) dispersed in chitosan covalently linked to 3,5-dinitrobenzoic acid, a redox mediator, which showed electrocatalytic activity for NADH. The nanostrutucred platform was characterized performing scanning electron microscopy (SEM), cyclic voltammetry and chronoamperometry analyses. The obtained values for the ks and for chemical reaction (kobs) between redox mediator and NADH were 14 s and 5.1x10 L mol s, respectively. After the activation process and of the redox couple characterization the enzyme glutathione reductase was easily immobilized on the electrode surface using chitosan and glutaraldehyde. Employing chronoamperometric measures, it was possible to analyze the influence of each parameter used in the construction of the biosensor for detection of GSSG. The best conditions for the use of the biosensor were: 50 units of GR, 2.5 mg mL chitosan and 600 mmol L NADH. The biosensor showed a linear range for detecting GSSG in concentrations from 2.0 to 35 mmol L. The detection and quantification limits obtained were 0.6 e 2.0 mmol L, respectively. Using the same nanostructured platform, it was possible to immobilize both enzymes (GPx and GR), being this biosensor dedicated to detect the total glutathione (GSH + GSSG). This biosensor showed a linear range for detecting GSSG in concentrations from 2.0 up to 10 mmol L. The detection and quantification limits obtained were 0.6 e 2.0 mmol L, respectively / Doutorado / Quimica Analitica / Doutora em Ciências Biossíntese Estresse oxidativo Razão glutationa reduzida/oxidada Plataforma nanoestrutura Nanotubos de carbono Biosensors Oxidative stress Ratio oxidized/reduced glutathione Nanostructured platform Carbon nanotube
592	Caractérisation électrique et électro-optique de transistor à base de nanotube de carbone en vue de leur modélisation compacte Liao, Si-yu 29 April 2011 (has links) Afin de permettre de développer un modèle de mémoire non-volatile basée sur le transistor à nanotube de carbone à commande optique qui est utilisée dans des circuits électroniques neuromorphiques, il est nécessaire de comprendre les physiques électroniques et optoélectroniques des nanotubes de carbone, en particulier l’origine de l'effet mémoire que présente ces transistors. C’est dans ce contexte général que cette thèse s'intègre. Le travail est mené sur trois plans :• Caractériser électriquement et optoélectroniquement des structures de test des CNTFETs et des OG-CNTFETs.• Développer un modèle compact pour les contacts Schottky dans les transistors à nanotube de carbone de la façon auto-cohérente basé sur le diamètre et la nature du métal d’électrode en utilisant la méthode de la barrière effective avec les paramètres nécessaires calibrés.• Modéliser l'OG-CNTFET selon les régimes de fonctionnement, lecture, écriture, effacement ou programmation pour application à une mémoire non-volatile en intégrant le mécanisme de piégeage et dépiégeage à l’interface polymère/oxyde. / This PhD thesis presents a computationally efficient physics-based compact model for optically-gated carbon nanotube field effect transistors (OG-CNTFETs), especially in the non-volatile memory application. This model includes memory operations such as “read”, “write”, “erase” or “program”, and “reset” which are modeled using trapping and detrapping mechanisms at the polymer/oxide interface. The relaxation of the memory state is taken into account. Furthermore, the self-consistent modeling of Schottky barriers at contacts between the carbon nanotube channel and metal electrodes is integrated in this model applying the effective Schottky barrier method. The Schottky contact model can be included in CNTFET based devices for a typical biasing range of carbon nanotube transistors. This compact model is validated by the good agreement between simulation results and experimental data (I-V characteristics). In the non-volatile memory application, this model can fully reproduce device behaviors in transient simulations. A prediction study of the key technological parameter, the CNT diameter variety is established to expect its impact on the transistor performance, and more importantly, on the memory operation. In the other hand, this thesis presents a preliminary electric characterization (I-V) of CNTFETs and OG-CNTFETs for the device modeling database. A preliminary optoelectronic characterization method is proposed. Modélisation compact Transistor à nanotube de carbone Barrière Schottky Mémoire non-volatile Piégeage Dépiégeage Optoelectronique Device modeling Spice simulation Cntfet Non-volatile memory Optoelectronics Compact modeling Schottky barrier Trapping Detrapping
593	Size Dependence of Static and Dynamic Properties of Nanobars and Nanotubes Pathak, Sandeep 10 1900 (has links) (PDF) This thesis aims at investigating size dependence of properties of nanostructures from the point of view of a general scaling theory that smoothly connects properties of the bulk to that of nanostructures. Two different examples of a ``static'' and a ``dynamic'' property are considered in this study. The first example studied is of size dependence of coefficient of thermal expansion (CTE) which a static property of nanostructures. The CTE of nanobars and nanoslabs is studied using equilibrium molecular dynamics and dynamical matrix formulation in an electrically insulating medium. It is found that the fractional change in CTE from the bulk value scales inversely with the size of the nanostructures, thus, showing a simple description in terms of a scaling theory. In the second part, electron transport in carbon nanotube field effect transistors (CNTFETs) is studied using Landauer formalism. A CNTFET involves transport through a 1-d ballistic carbon nanotube channel with Schottky barriers (SB) at contacts which determines the transport characteristics. The CNT is modeled as a 1-d semiconductor having only two bands separated by an energy gap which depends inversely on tube diameter. After the contact is made, a self-consistent potential appears due to charge transfer between CNT and metal, which is calculated by solving Poisson equation. The electron transmission across the barriers is calculated using WKB approximation. Current and conductance are calculated using Landauer-Buttiker formula. Diameter dependence of properties like, conductance, threshold voltage, VON, etc. is calculated. It is found that there is no simple scaling for a property for small values of diameter. The scaling form is, however, found to be valid for larger diameters. Also, other calculated device characteristics are in close agreement with experiments. The model presented in this thesis is the first detailed study illustrating the applicability of the scaling approach to the properties of nanostructures. The static properties show scaling behavior, while ``dynamic'' properties derived from electronic response do not. Nanostructured Materials Nanotubes Nanobars Nanostructures Nanomaterials CNTFET Coefficient of Thermal Expansion (CTE) Landauer Formalism Materials Science
594	Modélisation compacte des transistors à nanotube de carbone à contacts Schottky et application aux circuits numériques Najari, Montassar 10 December 2010 (has links) Afin de permettre le développement de modèles manipulables par les concepteurs, il est nécessaire de pouvoir comprendre le fonctionnement des nanotubes, en particulier le transport des électrons et leurs propriétés électroniques. C’est dans ce contexte général que cette thèse s’intègre. Le travail a été mené sur quatre plans : développement de modèles permettant la description des phénomènes physiques importants au niveau des dispositifs, expertise sur le fonctionnement des nano-composants permettant de dégager les ordres de grandeurs pertinents pour les dispositifs, les contraintes, la pertinence de quelques procédés de fabrication (reproductibilité, taux de défauts, collection de caractéristiques mesurées et développement éventuel d'expériences spécifiques, expertise et conception des circuits innovatifs pour l’électronique numérique avec ces nano-composants. / This PhD work presents a computationally efficient physics-based compact model for the Schottky barrier (SB) carbon nanotube field-effect transistor (CNTFET). This compact model includes a new analytical formulation of the channel charge, taking into account the influence of the source and drain SBs. Compact model simulation results (I–V characteristic and channel density of charge) as well as Monte Carlo simulation results, which are provided by a recent work, will be given and compared to each other and also to experimental data to validate the used approximations. Good agreement is observed over a large range of gate and drain biases. Furthermore, a scaling study is presented to examine the impact of technological parameters on the device figure of merit. Then, for the assessment of the SB on circuit performances, traditional logical circuits are designed using the SB-CNTFET compact model, and results are compared with a conventional CNTFET with zero-SB height. Finally, exploiting the particular properties of SB-CNTFETs, a three-valued static memory that is suitable for high density integration is presented. Modélisation compacte Simulation circuit Cellule mémoire SRAM Effet tunnel Wkb Compact modelling Schottky barrier carbon based transistor Spice simulation Static memory cell Tunnelling Wkb
595	On the stability of carbon nanotube and titania nanowire based catalyst materials:from synthesis to applications Rautio, A.-R. (Anne-Riikka) 08 March 2016 (has links) Abstract Degradation of the support and sintering of catalyst nanoparticles inherently leads to a loss of functionality of catalyst materials in converters and sensors. Malfunction in such devices may lead to serious economic and environmental damage. The quest for novel and sustainable catalyst materials with better durability is thus ongoing. In this thesis, one-dimensional nanomaterials such as carbon nanotubes and titanium dioxide nanowires are studied and compared to their conventional zero-dimensional counterparts in regard to their structural and functional stability. With the combination of several catalyst nanomaterials and supporting surfaces, aging properties of more than 70 different materials are assessed by the means of X-ray diffraction, transmission electron microscopy and energy-dispersive X-ray analyses. Although CNTs were shown to be thermally the most stable carbonaceous supports for metal nanoparticles, they are, similar to other carbon supports, more sensitive to high temperatures than metal oxide supports and can suffer deactivation by catalytic oxidation and gasification even at moderate temperatures. In addition, the irradiation of the samples with e-beams caused the most dramatic changes in CNT based materials, where nanosized deformities (voids, channels) were formed when either nanoparticles or defects were present. The prepared nanocompositions have been utilized successfully in three different applications including (i) synthesis of hydrogen from ethanol via a steam reforming reaction, (ii) hydrogenation of citral to form value added chemicals and (iii) the application of advanced electrode materials in electric double-layer capacitors. Both CNT and TiO₂ nanowire based nanomaterials were shown to outperform their conventional nano- and microparticle based counterparts in the studied catalytic reactions, i.e. in citral hydrogenation and steam reforming of ethanol, respectively. Furthermore, nanostructured CNTs obtained by catalytic partial oxidation of the material showed an increased specific surface area, which could be exploited in supercapacitor electrodes with enhanced specific capacitance. / Tiivistelmä Katalyyttitukimateriaalin pilaantuminen ja katalyyttinanopartikkelien sintrautuminen johtavat siihen, että muuntajissa ja sensoreissa käytettävät katalyyttiset materiaalit eivät enää toimi, mikä voi aiheuttaa sekä vakavia taloudellisia haittoja että ympäristöhaittoja. Tämän vuoksi kehitetään uusia kestävämpiä katalyyttimateriaaleja. Tässä väitöskirjassa tutkittiin yksiulotteisia nanomateriaaleja, kuten hiilinanoputkia sekä titaanidioksidinanojohtimia ja verrattiin niiden rakenteellista ja toiminnallista stabiiliutta perinteisiin nollaulotteisiin vastineisiin. Erilaisten katalyyttinanomateriaalien ja tukimateriaalien yhdistelmien ikääntymistä arvioitiin röntgendiffraktion, läpäisyelektronimikroskopian ja energiadispersiivisen röntgenanalyysin avulla yli 70 erilaisesta näytteestä. Vaikka hiilinanoputket osoittautuivat termisesti stabiileimmaksi hiilipohjaiseksi tukimateriaaliksi metallinanopartikkeleille, ne ovat kuten kaikki hiilimateriaalit, metallioksiditukimateriaaleja herkempiä korkeille lämpötiloille. Hiilinanoputkipohjaiset katalyytit voivat deaktivoitua katalyyttisen hapettumisen tai kaasuuntumisen vuoksi jo kohtalaisissa lämpötiloissa. Lisäksi elektronisäteellä säteilytetyt nanopartikkelit tai pintavirheitä sisältävät hiilinanoputkipohjaiset katalyytit olivat tutkituista nanomateriaaleista herkimpiä muodostamaan nanorakenteita (koloja, kanavia). Valmistettuja nanokomposiitteja käytettiin onnistuneesti kolmessa eri sovelluksessa: i) vedyn valmistuksessa etanolista höyryreformointireaktiolla, ii) hienokemikaalien valmistuksessa sitraalin hydrauksella sekä iii) elektrodimateriaalina EDLC-kondensaattorissa. Sekä hiilinanoputki- sekä TiO₂-nanojohdinpohjaiset nanomateriaalit toimivat testatuissa katalyyttisissa reaktioissa (etanolin reformointi sekä sitraalin hydraus) paremmin kuin niiden perinteiset vastineet. Lisäksi superkondensaattorin ominaiskapasitanssia onnistuttiin nostamaan lisäämällä hiilinanoputkipohjaisen elektrodin ominaispinta-alaa katalyyttisella hapetusreaktiolla. capacitor carbon nanotube catalyst citral hydrogenation ethanol reforming nanoparticle nanowire stability titanium dioxide nanowire TiO₂ etanolin reformointi hiilinanoputki katalyytti kondensaattori nanojohdin nanopartikkeli sitraalin hydraus stabiilius titaanidioksidinanojohdin CNT
596	Interaction between Nanoparticles and Aggregates of Amphiphile Molecules / Interaction entre nanoparticules et agrégats de molécules amphiphile Tian, Falin 03 July 2015 (has links) Ayant une structure particulière avec une tête hydrophile et une queue hydrophobe, des molécules amphiphile ont de nombreuses applications importantes, comme par exemple, la fabrication des détergents, la protection et la fonctionnalisation de surfaces, etc. Des agrégats de diverses formes, micelles, véhicules, membranes etc., peuvent se former à partir des amphiphiles. La complexité de ces agrégats moléculaires rend l’étude théorique de ce type de systèmes extrêmement difficile. Jusqu’à présent, notre connaissance sur l’interaction entre des nanoparticules et des agrégats des amphiphiles reste encore incomplète. A l’aide de certaines méthodes de simulations moléculaire et une approche théorique, nous avons entrepris une série d’études pour mieux comprendre les questions fondamentales suivantes :1. Comment la présence de nanoparticules, notamment la courbure de ses surfaces, affecte l’agrégation de molécules amphiphile ?2. Comment une bicouche de lipide, une forme d’agrégat particulier des amphiphile, peut induire l’assemblage auto-organisé de nanoparticules hydrophobes ?3. Est-ce que la présence des nanoparticules peut provoquer des transitions morphologiques d’un nanotube membranaire ? / Amphiphile molecules, endowed with a particular structure containing a hydrophilic head and a hydrophobic tail, have many important applications, e.g., fabrication of detergents, surface coating or surface functionalization, etc. Molecular aggregates of various forms, micelles, vehicle, membranes, etc. can be formed from amphiphile molecules. The complexity of these molecular aggregates involving a large number of atoms make the theoretical study of these system very challenging. Up to now, our understanding of the interaction between nanoparticles and aggregates of amphiphiles remains quite incomplete. Using a variety of molecular simulation methods and some theoretical approaches (Helfrich theory and perturbation theory), we have studied the following issues in the present thesis: 1. How the presence of nanoparticles, especially due to their highly curved surfaces, affects the aggregation of the amphiphiles? 2. How a lipid bilayer, a particular amphiphile aggregate, induces the self-assembly of hydrophobic nanoparticles.3. How the morphology transition of a membrane nanotube can be induced by nanoparticles? Molécule amphiphile Lipides membranaires Nano particule Nano tube lipide Simulation moléculaire Amphiphilic molecule Lipid membrane Nanoparticle Lipid nanotube Tube pearling Molecular simulation
597	TiO2 nanotube based dye- sensitised solar cells Cummings, Franscious Riccardo January 2012 (has links) Philosophiae Doctor - PhD / This work investigated the synthesis of Al2O3-coated TiO2 nanotubes via the anodisation technique for application in DSCs. TiO2 nanotube arrays with an average length of 15 μm, diameter of 50 nm and wall thickness of 15 nm were synthesised via anodisation using an organic neutral electrolyte consisting of 2 M H2O + 0.15 M NH4F + ethylene glycol (EG) at an applied voltage of 60 V for 6 hours. In addition, scanning electron microscope (SEM) micrographs showed that anodisation at these conditions yields nanotubes with smooth walls and hexagonally shaped, closed bottoms. X-ray diffraction (XRD) patterns revealed that the as-anodised nanotubes were amorphous and as such were annealed at 450 °C for 2 hours in air at atmospheric pressure, which yielded crystalline anatase TiO2 nanotubes. Highresolution transmission electron microscope (TEM) images revealed that the nanotube walls comprised of individual nano-sized TiO2 crystallites. Photoluminescence (PL) spectroscopy showed that the optical properties, especially the bandgap of the TiO2 nanotubes are dependent on the crystallinity, which in turn was dependent on the structural characteristics, such as the wall thickness, diameter and length. The PL measurements were supplemented by Raman spectra, which revealed an increased in the quantum confinement of the optical phonon modes of the nanotubes synthesised at low anodisation voltages, consequently yielding a larger bandgap The annealed nanotubes were then coated with a thin layer of alumina (Al2O3) using a simple sol-gel dip coating method, effectively used to coat films of nanoparticles. Atomic force microscopy (AFM) showed that the average nanotube diameter increased post sol-gel deposition, which suggests that the nanotubes are coated with a layer of Al2O3. This was confirmed with HR-TEM, in conjunction with selected area electron diffraction (SAED) and XRD analyses, which showed the coating of the nanotube walls with a thin layer of amorphous Al2O3 with a thickness between 4 and 7 nm. Ultraviolet-visible (UVvis) absorbance spectra showed that the dye-adsorption ability of the nanotubes are enhanced by the Al2O3 coating and hence is a viable material for solar cell application. Upon application in the DSC, it was found by means of photo-current density – voltage (I – V) measurements that a DSC fabricated with a 15 μm thick layer of bare TiO2 nanotubes has a photon-to-light conversion efficiency of 4.56%, which increased to 4.88% after coating the nanotubes with a layer of alumina. However, these devices had poorer conversion efficiencies than bare and Al2O3-coated TiO2 nanoparticle based DSCs, which boasted with efficiencies of 6.54 and 7.26%, respectively. The low efficiencies of the TiO2 nanotube based DSCs are ascribed to the low surface area of the layer of nanotubes, which yielded low photocurrent densities. Electrochemical impedance spectroscopy (EIS) showed that the electron lifetime in the alumina coated nanotubes are almost 20 times greater than in a bare layer of nanoparticles. In addition, it was also found that the charge transfer resistance at the interface of the TiO2/dye/electrolyte is the lowest for an Al2O3-coated TiO2 layer. Dye-sensitised solar cells TiO2 nanotube Photovoltaics Electrochemical anodisation Sol-Gel deposition Renewable energy Core-shell nanostructures Materials science Opto-electronic properties Morphology Electron charge transfer Crystallinity
598	Adsorption, aggregation and phase separation in colloidal systems Dai, Jing January 2017 (has links) The thesis presents work regarding amphiphilic molecules associated in aqueous solution or at the liquid/solid interface. Two main topics are included: the temperature-dependent behavior of micelles and the adsorption of dispersants on carbon nanotube (CNT) surfaces. Various NMR methods were used to analyze those systems, such as chemical shift detection, spectral intensity measurements, spin relaxation and, in particular, self-diffusion experiments. Besides this, small angle X-ray scattering (SAXS) was also applied for structural characterization. A particular form of phase transition, core freezing, was detected as a function of temperature in micelles composed by a single sort of Brij-type surfactants. In mixed micelles, that phase transition still occurs accompanied by a reversible segregation of different surfactants into distinct aggregates. Adding a hydrophobic solubilizate shifts the core freezing point to a lower temperature. Upon lowering the temperature to the core freezing point, the solubilizate is released. The temperature course of the release curves with different initial solubilizate loadings is rationalized in terms of a temperature-dependent loading capacity. The behavior of amphiphilic dispersant molecules in aqueous dispersions of carbon nanotubes (CNTs) has been investigated with a Pluronic-type block copolymer as frequent model dispersant. Detailed dispersion curves were recorded and the distribution of the dispersant among different available environments was analyzed. The amount of dispersed CNT was shown to be defined by a complex interplay of several factors during the dispersion process such as dispersant concentration, sonication time, centrifugation and CNT loading. In the dispersion process, high amphiphilic concentration is required because the pristine CNT surfaces made available by sonication must be rapidly covered by dispersants to avoid their re-attachment. In the prepared dispersions, the competitive adsorption of possible dispersants was investigated that provided information about the relative strength of the interaction of those with the nanotube surfaces. Anionic surfactants were found to have a strong tendency to replace Pluronics, which indicates a strong binding of those surfactants. CNTs were dispersed in an epoxy resin to prepare nanotube-polymer composites. The molecular mobility of epoxy was investigated and the results demonstrated the presence of loosely associated CNT aggregates within which the molecular transport of epoxy is slow because of strong attractive intermolecular interactions between epoxy and the CNT surface. The rheological behavior is dominated by aggregate-aggregate jamming. / <p>QC 20180103</p> NMR chemical shift spin relaxation self-diffusion micelle core freezing segregation solubilization release adsorption binding surfactant carbon nanotube block copolymer dispersion competitive adsorption nanocomposite Physical Chemistry Fysikalisk kemi
599	Creation and Evaluation of Polymer/Multiwall Carbon Nanotube Films for Structural Vibration Control and Strain Sensing Properties lin, weiwei 10 November 2016 (has links) Multifunctional materials both with damping properties and strain sensing properties are very important. They promise to be more weight-efficient, and provide volume-efficient performance, flexibility and potentially, less maintenance than traditional multi-component brass-board systems. The goal of this dissertation work was to design, synthesize, investigate and apply polyaniline/Multiwall carbon nanotube (PANI/MWCNT) and polyurethane (PU) /MWCNT composites films for structural vibration control and strain sensors using free layer damping methods and static and dynamic strain sensing test methods. The PANI/MWCNT was made by in situ polymerization of PANI in the presence of MWCNT, then frit compression was used to make circular and rectangular PANI/MWCNT composite films. PU/MWCNT composites were made by the layer-by-layer method. Free end vibration test results showed both of PANI/MWCNT and PU/MWCNT have better damping ratios than each of their components. Static sensing test indicated that though there appears to be residual strain in both composite sensors after the load is removed, both the sensor and the foil strain gage react linearly when re-engaged. A drift test of the sensor showed that it is stable. The dynamic sensing test results showed that over the range of 10-1000 Hz, the PANI/MWCNT composite sensor was consistently superior to foil strain gage for sensing purposes since the highest peak consistently corresponded to the input frequency and was much higher, for example, at 20 Hz, 820 times higher than those of the strain gage. Using the same criterion, the PU/Buckypaper composite sensor was comparable to or superior to the foil strain gage for sensing purposes over the range of 10 Hz to 200 Hz. The relationship of loss factor, η, and beam coverage length, L1/L, is discussed for single sided and double sided attachment. For both PANI/MWCNT and PU/MWCNT, the loss factor, η, was found to increase as coverage length, L1/L, increases. The loss factor, η, was found to have a maximum as with coverage length, L1/L, as the coverage length continues to increase. The trend for double sided attachment was found to follow the trends discussed by Rao (2004) and Levy and Chen (1994) for viscoelastic material constrained damping. Polymer/Multiwall Carbon Nanotube Polyaniline Polyurethane Damping properties Strain Sensing properties. Nanoscience and Nanotechnology Other Materials Science and Engineering Polymer and Organic Materials Structural Materials
600	Propriétés optiques hors-équilibre des nanotubes de carbone nus ou fonctionnalisés / Nonequilibrium optical properties of bare and functionalized carbon nanotubes Langlois, Benjamin 11 December 2014 (has links) Cette thèse est consacrée à l'étude expérimentale par spectroscopie pompe-sonde femtoseconde des propriétés optiques hors-équilibre de solutions micellaires de nanotubes de carbone. Les propriétés des nanotubes de carbone sont profondément affectées par leur géométrie unidimensionnelle. Les interactions coulombiennes exaltées du fait du confinement quantique des électrons à une dimension donnent naissance à des excitons fortement liés. L'analyse des spectres d'absorption transitoire par la méthode des moments permet une étude des interactions entre excitons. La relaxation des excitons s'avère gouvernée par les collisions entre excitons, limitées par la diffusion à 1D dans le nanotube. La présence d'excitons dans une sousbande conduit à un décalage uniforme vers le bleu de l'ensemble des transitions excitoniques et à un élargissement de même ampleur. Ainsi, les interactions croisées entre excitons de sousbandes différentes sont de même amplitude qu'entre excitons de même sousbande, en accord avec une modélisation simple.Par ailleurs, les nanotubes sont constitués uniquement d'atomes de surface, ce qui leur confère une forte sensibilité à l'environnement. Cette sensibilité est mise à profit dans des composés hybrides où la fonctionnalisation non-covalente par des colorants ouvre une nouvelle voie d'excitation des nanotubes. Notre étude montre que le transfert d'énergie entre les colorants et les nanotubes permet une excitation monochromatique efficace et uniforme de l'ensemble des espèces de nanotubes. Une fois l'exciton transféré au nanotube, sa relaxation s'avère ensuite identique à celle observée dans les nanotubes nus. / This thesis is devoted to the experimental study by femtosecond pump-probe spectroscopy of micellar solutions of carbon nanotubes. The properties of carbon nanotubes are greatly affected by their 1D geometry. Quantum confinement of electrons in 1D leads to enhanced coulomb interactions giving rise to strongly bound excitons. Many-body effects between excitons is investigated by the moment method analysis of the transient absorption spectra. The relaxation of excitons is controlled by diffusion-limited collisions between excitons. The presence of excitons in the lowest subband results in a broadening and an uniform blue-shift of the excitonic energy spectrum. Intra and intersubband interactions turn out to be of the same magnitude, in agreement with a simple mean field theory of excitonic interactions.Moreover, the one-layer structure of nanotubes results in strong interaction with the environment. We take advantage of the environmental sensitivity of nanotubes in hybrid compounds where the non-covalent functionalization with dyes opens a new extrinsic monochromatic excitation channel of the nanotubes through an efficient and ultrafast energy transfer between dyes and nanotubes. Once the exciton transferred to the nanotube, its relaxation is similar to the one observed in bare nanotubes. Nanotube de carbone Propriétés optiques Pompe-sonde Exciton Interactions Relaxation Transfert d'énergie Carbon nanotubes Optical properties Pump-probe Exciton Interactions Relaxation Energy transfer 530

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