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901	Anisotropia de resistividade elétrica em filmes finos nanoestruturados. / Electrical resistivity anisotropy in nanostructured thin films. Fernanda de Sá Teixeira 18 May 2007 (has links) O objetivo principal deste trabalho foi desenvolver um dispositivo de filme fino com anisotropia de resistividade elétrica. A idéia foi usar um efeito quântico presente em filmes muito finos de materiais condutores ou semicondutores com morfologia anisotrópica na superfície. A morfologia foi um perfil unidirecional quase-senoidal. As resistividades foram determinadas medindo-se as resistências elétricas destes materiais em direções ortogonais, levando-se em conta a geometria da amostra e suas dimensões. O material condutor usado foi Polimetilmetacrilato (PMMA) com ouro implantado na superfície. A profundidade média de implantação foi 2,7 nm. Na fabricação do dispositivo foi utilizada micro e nanolitografia, caracterização por Microscopia Eletrônica de Varredura e Microscopia de Força Atômica e implantação de ouro por MePIIID (Metal Plasma Immersion Ion Implantation and Deposition). / The main purpose of this work was to develop a thin film device with electrical anisotropic resistivity. The idea was to use a quantum effect which is present in very thin films of conductor or semiconductor materials with anisotropic morphology on the surface. The morphology was a sinusoidal-like unidirectional profile. The resistivities were determined measuring the electrical resistances of theses materials in orthogonal directions, taking in account the sample geometry and dimensions. The conductive material used was Polymethylmethacrylate (PMMA) with gold implanted on the surface. The average implanted depth was 2.7 nm. In the device fabrication were used micro and nanolithography, characterization by Scanning Electron Microscopy and Atomic Force Microscopy and gold implantation by MePIIID (Metal Plasma Immersion Ion Implantation and Deposition). Deposição por plasma Litografia Materiais nanoestruturados Microfabricação Microscopia de força atômica Microscopia eletrônica de varredura Nanofabricação Nanolitografia Novos materiais Plasma (microeletrônica) Resistividade elétrica Atomic force microscopy Electrical resistivity Litography Microfabrication Nanofabrication Nanolithography Nanostructured materials New Materials Plasma (microeletronics) Plasma deposition Scanning electron microscopy
902	Desenvolvimento da microscopia de força química usando modelagem molecular Amarante, Adriano Moraes 19 March 2013 (has links) Made available in DSpace on 2016-06-02T19:19:55Z (GMT). No. of bitstreams: 1 AMARANTE_Adriano_2013.pdf: 11925080 bytes, checksum: 6de5e4ba7ae233d30b78c7f1d927740a (MD5) Previous issue date: 2013-03-19 / Universidade Federal de Sao Carlos / In this work was developed a prototype of a new nanobiosensor with molecular specificity through a study of theoretical models of Chemical Force Microscope. For the sensing were used molecular modeling techniques as well as experimental models of the functionalized Atomic Force Microscope tip with the Acetil co-A Carboxylase (ACC) attached. Specific and non-specific inhibitors were used to evaluate substrate-enzyme interactions. The nanobiosensor investigates specific enzymatic inhibition characteristics of the ACC enzyme through the herbicide Diclofop by reversing this process applying a force in a determined direction. The force is theoretically calculated by using molecular dynamic techniques associated to the adhesion force experimentally obtained. Theoretical and experimental questions involving nanobiosensors of AFM tips still obscure until now, such as, the number of functional enzymes attached on the AFM tip, the number of the active sites available to interact after immobilization process, the consequences of the enzyme immobilization as well as the substrate and theoretical adhesion between AFM tip and substrate were analyzed here. / Este trabalho teve como objetivo principal desenvolver o protótipo de um novo nanobiossensor de alta especificidade por intermédio do estudo e desenvolvimento de modelos teóricos específicos para a Microscopia de Força Química (MFQ). Para o sensoriamento foram utilizadas técnicas de Modelagem Molecular Computacional (MMC) e resultados experimentais de MFQ, do qual a ponta do Microscópio de Força Atômica (AFM, do inglês Atomic Force Microscopy) foi funcionalizada com enzimas Acetil-coA Carboxilase (ACC). O nanobiossensor foi utilizado para detectar especificamente substratos de herbicidas específicos e não-específicos. O nanobiossensor explora as características de inibição enzimática específica da enzima ACC pelo herbicida Diclofop revertendo esse processo aplicando-se uma força numa determinada direção. Essa força foi calculada teoricamente por intermédio de cálculos de técnicas de Dinâmica Molecular e associada à força de adesão experimental. Os resultados experimentais validaram os modelos teóricos de forma inequívoca. Questões teóricas e experimentais envolvendo nanobiossensores de ponta de AFM não respondidas até o momento (número de enzimas úteis na ponta do AFM que podem interagir com o substrato, o número de sítios ativos disponíveis, consequências da imobilização das enzimas e do substrato, força de adesão teórica entre a ponta do AFM e o substrato de herbicidas, etc.) foram solucionadas neste trabalho. Modelagem Molecular Computacional Microscopia de Força Química (MFQ) biossensores nanobiossensor dinâmica molecular Docking Molecular Acetil-coA Carboxilase Diclofop funcionalização de Superfícies nanobiosensor molecular modeling Atomic Force Microscopy Chemical Force Microscopy Molecular Dynamics Diclofop Surface Functionalization CIENCIAS EXATAS E DA TERRA::QUIMICA
903	Restauração de imagens de AFM com o funcional de regularização de Tikhonov visando a avaliação de superfícies metálicas / Restoration of AFM images with functional Tikhonov regularization for evaluating metallic surfaces Alexander Corrêa dos Santos 29 August 2008 (has links) Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Problemas durante o processo de aquisição de imagens de AFM têm feito com que pesquisas na área de nanotecnologia busquem a utilização de ferramentas para minimizar esses efeitos degenerativos. Neste sentido, foram desenvolvidas ferramentas computacionais de restauração destas imagens degradadas. Neste trabalho é utilizado o método baseado na Regularização de Tikhonov, cuja aplicação está concentrada principalmente em restaurações de imagens biológicas. A proposta deste trabalho é a utilização deste regularizador também em imagens de interesse em engenharia. Em alguns casos, um pré-processamento anteriormente à aplicação do algoritmo, apresenta boa resposta na restauração das imagens. Na fase de préprocessamento foram utilizados alguns filtros como, filtro de média, filtro de mediana, filtro laplaciano e filtro de média pontual. Com a aplicação deste regularizador em imagens foi possível obter perfis de distribuição dos pixels onde é mostrado que na medida em que se aumenta a carga de dissolução de ferro puro em ácido sulfúrico, percebe-se que a razão de aspecto aumenta e características de superfície ficam mais visíveis. / Problems during the process of acquisition of images of AFM have been doing with that research in the nanotechnology searchs the use of tools to minimize those degenerative effects. Computational tools for restoration of these degraded images have developed, in this work the method is used based on Regularization of Tikhonov. This method is usually used for restoration of biological images. It is proposed the use of this regularization functional also in images of interest in engineering. In some cases, a previously processing to the application of the algorithm, it presents good answer in the restoration of the images. The previously processing phase some were used filters as, average filter, median filter, laplacian filter and filter of punctual average, besides combination of filters. With the application of this regularizator it was possible to obtain profiles of distribution of the pixels where is shown that in the measure in that he increases the dissolution charge of iron in sulphuric acid, it is noticed that the aspect reason increases and surface characteristics are more visible. Microscópio e microscopia Materiais Processamento de imagens Tikhonov, A.N. (Andrei Nikolaievitch) Restauração de imagens Microscopia de força atômica Regularização de Tikhonov Image processing - digital techniques Microscope and microscopy Materials - image processing Tikhonov, A.N. (Andrei Nikolaievitch) Image restoration Atomic force microscopy Tikhonov regularization MODELOS ANALITICOS E DE SIMULACAO
904	Química da parte úmida em processo de fabricação de papel - interações em interfaces sólido-líquido. / Wet end chemistry in papermaking - interactions in solid-liquid interfaces. Deusanilde de Jesus Silva 02 March 2010 (has links) Um polieletrólito catiônico (poliamina), com baixo peso molecular e elevada densidade de carga, normalmente aplicado como agente coagulante do lixo aniônico, foi usado para estudos de retenção e drenagem na fabricação de papel. O uso do carboximentil celulose de sódio para simulação do teor de lixo aniônico e seu efeito na retenção de cargas minerais foi uma característica importante para este trabalho. Pode ser observado que o aumento da dosagem do polímero catiônico tanto melhora a retenção de cargas minerais, avaliada pela turbidez do filtrado, quanto melhora a drenagem do sistema, avaliada pela velocidade de escoamento. Entretanto, elevadas dosagens deste polímero comprometeram os resultados destes parâmetros devido à inversão de carga do sistema. Pode também ser confirmado que forças de cisalhamento excessivas prejudicam a retenção de cargas minerais. Ademais, um polianfótero, com peso molecular e densidade de carga elevados, contendo grupos positivo (N-[3-(N,N-dimetilamino)propil]acrilamida), negativo (ácido metileno butanodióico) e nulo (acrilamida) na mesma cadeia, foi testado como agente de resistência a seco do papel. Todos os estudos em nível molecular sobre o comportamento do polianfótero em solução e o seu comportamento de adsorção sobre superfícies modelos carregadas, em diferentes condições de pH e de força iônica, foram importantes para explicar tanto dos fenômenos de adsorção, envolvendo fibras celulósicas e polianfótero, quanto o seu efeito na resistência mecânica do papel. Foi observado que a solubilidade do polímero aumenta à medida que o pH se distancia do seu ponto isoelétrico, pHPIE 7,3, e reduz para valores de pH próximos ao pHPIE. O tamanho das estruturas do polianfótero depende do pH do meio de dispersão. As características de tamanho do polianfótero tanto sob a forma de cadeias individuais ou quanto sob a forma de agregados, foram medidas através da técnica de espalhamento dinâmico de luz. As propriedades viscoelásticas das camadas adsorvidas e a quantidade de polímero adsorvida foram medidas através da técnica da balança microgravimétrica com dissipação de energia. Estas duas determinações, associadas às imagens no microscópio de força atômica, foram importantes para o entendimento dos resultados práticos do uso do polianfótero como agente de resistência a seco do papel. Maiores resultados de resistência do papel, avaliada através da resistência à tração, foram alcançados para valores de pH próximos ao ponto isoelétrico onde foram encontrados o seguinte: (1) maiores tamanhos para as estruturas do polímero em solução, (2) maior quantidade de massa nas camadas adsorvidas e (3) a formação de camadas mais viscoelásticas. O fenômeno de separação de fases, associado à mudança da solubilidade do polímero em solução devido ao balanço dos grupos positivos e negativos ionizados ao longo da faixa de pH estudada, foi considerado o principal aspecto para a variação em tamanho dos agregados. Embora este polímero tenha apresentado comportamento antipolieletrólito devido à expansão da sua cadeia e ao aumento da densidade de carga com o aumento da força iônica, considerando o efeito da força iônica para pH 4,3, o comportamento de adsorção do polianfótero foi avaliado como o comportamento de um polieletrólito monocarregado de alta densidade de carga. Maiores e menores quantidades de massas adsorvidas foram encontradas para valores intermediários e extremos de força iônica, respectivamente. As interações eletrostáticas foram consideradas as principais responsáveis pela adsorção do polímero sobre superfícies carregadas. Entretanto, a blindagem de cargas foi considerada a explicação para os baixos valores de massa adsorvida para valores mais elevados de força iônica. / A cationic polyelectrolyte (polyamine), with low molecular weight and high charge density, usually applied as anionic trash coagulant, was used for the retention and drainage studies in the papermaking. The use of sodium carboxymethyl cellulose to simulate the anionic trash content and its effect on the filler retention was an important feature of the work. It could be noted that the increasing of the cationic polymer dosage improves both the filler retention, evaluated by the turbidity of the filtrate, and the system drainage, evaluated by the flow speed. However, high dosages of this polymer compromised the results of these parameters due to the reversal of the system charge. It can also be confirmed that excessive shear forces affect the filler retention. Furthermore, a polyampholyte, with high molecular weight and charge density, containing positive (N-[3-(N,N- dimethylamino)propyl]acrylamide), negative (methylene butanedioic acid), and neutral (acrylamide) groups in the same chain, was tested as a dry strength agent. All of the studies at molecular level concerning to the polyampholyte behavior in the solution and its adsorption behavior on charged model surfaces at different conditions of pH and ionic strength, were important to explain both the adsorption phenomena, involving cellulosic fibers and polyampholyte, and its impact on the paper strength. It was observed that the polymer solubility increases as the pH moves away from its isoelectric point, pHIEP 7.3, and decreases when the pH approaches close to pHIEP. The sizes of the structures of the polyampholytes depend on the pH of the dispersion medium. Also the size characteristics of polyampholyte, both in individual and aggregated forms, were measured by dynamic light scattering technique. The viscoelastic properties of adsorbed layers, as well as the amount of the adsorbed polymer, were measured by quartz crystal microbalance technique with energy dissipation. These two measurements, associated with the atomic force microscopy images, were important to understand the practical results of polyampholyte usage as a dry strength agent. Best results of paper strength, evaluated by paper strength index, were achieved at pH close to the isoelectric point on which one were found the following features: (1) larger sizes of the polymer structures in solution, (2) higher amount of mass in the adsorbed layers, and (3) the formation of more viscoelastic layers. The phase separation phenomenon, associated with the change in the solubility of the polymer due to the balance of the positive and negative groups throughout the studied pH range, was considered the main aspect for the variation in size of the aggregates. Although this polymer shows antipolyelectrolyte behavior due to the expansion of the its chain and the increasing in charge density with the ionic strength, considering the effect of ionic strength at pH 4.3, the adsorption behavior of polyampholyte was evaluated as a monocharged polyelectrolyte behavior with high charge density. Major and minor amounts of adsorbed masses were found for intermediates and extremes values of ionic strength, respectively. The electrostatic interactions were considered the main cause of the adsorption on charged surfaces. However, the electrostatic screening was considered the explanation for the low values of adsorbed mass at higher values of ionic strength. Agente de resistência a seco do papel Espalhamento dinâmico de luz Interações eletrostáticas Microscopia de força atômica Nanotecnologia Polianfótero Polieletrólito Polímeros sintéticos Química coloidal Retenção e drenagem Atomic force microscopy Colloidal chemistry Dynamic light scattering Electrostatic interactions Nanotechnology Paper dry strength agent Polyampholyte Polyelectrolyte Retention and drainage Synthetic polymers
905	Condutividade de películas finas de PEDOT:PSS. / On the conductivity of PEDOT:PSS thin films. Alexandre Mantovani Nardes 18 December 2007 (has links) As interessantes propriedades eletrônicas, mecânicas e óticas dos materiais orgânicos conjugados fizeram emergir diversas aplicações tecnológicas e comerciais em dispositivos baseados nesses materiais, tais como sensores, memórias, células solares e diodos emissores de luz poliméricos (LEDs). Neste sentido, o tema central desta tese é o estudo das propriedades elétricas e morfológicas e os mecanismos de transporte eletrônico de cargas no PEDOT:PSS, uma blenda polimérica que consiste de um policátion condutivo, o poli(3,4- etilenodioxitiofeno) (PEDOT) e do poliânion poli(estirenosulfonado) (PSS). PEDOT:PSS é amplamente usado como material de eletrodo em aplicações na área de eletrônica plástica, como mencionado anteriormente. Apesar da condutividade elétrica dos filmes finos de PEDOT:PSS possa variar várias ordens de grandeza, dependendo do método pela qual é processado e transformado em filme fino, as razões para este comportamento é essencialmente desconhecido. Esta tese descreve um estudo detalhado do transporte eletrônico de cargas anisotrópico e sua correlação com a morfologia, as condições e as dimensões da separação de fase entre os dois materiais, PEDOT e PSS. Antes de abordar as propriedades do PEDOT:PSS, uma camada de filme fino inorgânica usada para aumentar o tempo de vida de dispositivos orgânicos é descrita no Capítulo 2. Um importante mecanismo de degradação em LEDs poliméricos é a fotooxidação da camada ativa. Assim, isolar a camada ativa da água, oxigênio e luz, torna-se crucial para o aumento do tempo de vida. Um sistema de deposição química a partir da fase de vapor estimulada por plasma (PECVD) é usado para depositar filmes finos de nitreto de carbono em baixas temperaturas, menores que 100 °C, sobre PLEDs com a intenção de aumentar o tempo de vida destes dipositivos e diminuir a fotodegradação do poli[2-metoxi-5- (2-etil-hexiloxi)-p-fenileno vinileno] (MEH-PPV) em ambiente atmosférico. O filme fino de nitreto de carbono possui as características de um material que pode bloquear a umidade e que tem espessura e flexibilidade adequados para a nova geração de PLEDs flexíveis. As características dos filmes finos de nitreto de carbono e MEH-PPV foram investigadas usando-se técnicas de espectroscopia ótica, com particular ênfase no processo de degradação do MEHPPV sob iluminação. Os resultados mostraram que o filme fino de nitreto de carbono protege o filme polimérico e diminui consideravelmente a fotooxidação. Para avaliar o efeito do encapsulamento em dispositivos reais, LEDs poliméricos foram fabricados e pelas curvas de corrente-tensão um aumento no tempo de vida é confirmado quando a camada de nitreto de carbono é presente. O tempo de vida desejado, maior que 10.000 horas, para aplicações comerciais não foi atingido, entretanto, o encapsulamento pode ser melhorado otimizando as propriedades da camada de nitreto de carbono e combinando-as com camadas de outros materiais orgânicos e inorgânicos. Os capítulos seguintes deste trabalho aborda os estudos realizados com o PEDOT:PSS, uma vez que é amplamente usado em eletrônica orgânica, mas relativamente tem recebido pouca atenção com respeito ao transporte eletrônico de cargas, bem como sua correlação com a morfologia. No Capítulo 3, experimentos com microscopia de varredura por sonda (SPM, Scanning Probe Microscopy) e medidas de condutividade macroscópica são utilizados para estudar e obter um modelo 3D morfológico completo que explica, qualitativamente, a condutividade anisotrópica observada nos filmes finos de PEDOT:PSS depositados pela técnica de spin coating. Imagens topográficas de microscopia de varredura por tunelamento (STM) e imagens da seção transversal observadas com o microscópio de forca atômica (X-AFM) revelaram que o filme fino polimérico é organizado em camadas horizontais de partículas planas ricas em PEDOT, separadas por lamelas quasi-contínuas de PSS. Na direção vertical, lamelas horizontais do isolante PSS reduzem a condutividade e impõe o transporte eletrônico a ser realizado por saltos em sítios vizinhos próximos (nn-H, nearest-neighbor hopping) nas lamellas de PSS. Na direção lateral, o transporte eletrônico via saltos 3D em sítios a longas distâncias (3D-VRH, variable range hopping) ocorre entre as ilhas ricas em PEDOT que são separadas por barreiras muito mais finas de PSS, causando um aumento da condutividade nesta direção. Esta discussão é estendida ao Capítulo 4 com uma descrição quantitativa do transporte eletrônico de cargas predominantes. Particularmente, é demonstrado que o transporte de cargas via saltos 3D em sítios a longas distâncias ocorre entre ilhas ricas em PEDOT e não entre segmentos isolados de PEDOT ou dopantes na direção lateral, enquanto que na direção vertical o transporte de cargas via saltos em sítios vizinhos próximos ocorre dentro das lamelas do quasi-isolante PSS. Em algumas aplicações, faz-se necessário usar PEDOT:PSS com alta condutividade elétrica. Isso pode ser feito adicionando-se sorbitol à solução aquosa de PEDOT:PSS. Após um tratamento térmico, e dependendo da quantidade de sorbitol adicionado, a condutividade aumenta várias ordens de grandeza e as causas e consequências de tal comportamento foram investigadas neste trabalho. O Capítulo 5 investiga as várias propriedades tecnológicas do PEDOT:PSS altamente condutivo tratado com sorbitol, tais como a própria condutividade, os efeitos dos tratamentos térmicos e exposição à umidade. É observado que o aumento da condutividade elétrica, devido à adição de sorbitol na solução aquosa, é acompanhado por uma melhoria na estabilidade da condutividade elétrica em condições atmosféricas. Surpreendentemente, a condutividade elétrica do PEDOT:PSS, sem tratamento com sorbitol (~ 10-3 S/cm), aumenta mais de uma ordem de grandeza sob ambiente úmido de 30-35 % umidade relativa. Este efeito é atribuido a uma contribuição iônica à condutividade total. Análise Temogravimetrica (TGA), espectrometria de massa com sonda de inserção direta (DIP-MS) e análise calorimétrica diferencialmodulada (MDSC) foram usadas como técnicas adicionais para o entendimento dos estudos deste Capítulo. No Capítulo 6, microscopia de varredura por sonda-Kelvin (SKPM) foi empregada para medir o potencial de superfície dos filmes finos de PEDOT:PSS tratados com diferentes concentrações de sorbitol. Mostra-se que a mudança no potencial de superfície é consistente com uma redução de PSS na superfície do filme fino. Para estudar o transporte eletrônico nos filmes finos de PEDOT:PSS altamente condutivos tratados com sorbitol, o Capítulo 7 usa medidas de temperatura e campo elétrico em função da conduvitidade correlacionados com analises morfológicas realizadas por STM. É observado que o transporte eletrônico por saltos, na direção lateral, muda de 3D-VRH para 1D-VRH quando o PEDOT:PSS é tratado com sorbitol. Esta transição é explicada por uma auto-organização das ilhas ricas em PEDOT em agregados 1D, devido ao tratamento com sorbitol, tornando-se alinhadas em domínios micrométricos, como observado pelas imagens de STM. / Employing the unique mechanical, electronic, and optical properties of the conjugated organic and polymer materials several technological and commercial applications have been developed, such as sensors, memories, solar cells and light-emitting diodes (LEDs). In this respect, the central theme of this thesis is the electrical conductivity and mechanisms of charge transport in PEDOT:PSS, a polymer blend that consists of a conducting poly(3,4-ethylenedioxythiophene) polycation (PEDOT) and a poly(styrenesulfonate) polyanion (PSS). PEDOT:PSS is omnipresent as electrode material in plastic electronics applications mentioned above. Although the conductivity of PEDOT:PSS can vary by several orders of magnitude, depending on the method by which it is processed into a thin film, the reason for this behavior is essentially unknown. This thesis describes a detailed study of the anisotropic charge transport of PEDOT:PSS and its correlation with the morphology, the shape, and the dimension of the phase separation between the two components, PEDOT and PSS. Before addressing the properties of PEDOT:PSS, a new barrier layer is described in Chapter 2 that enhances the lifetime of organic devices. An important degradation mechanism in polymer LEDs is photo-oxidation of the active layer. Hence, isolating the active layer from water and oxygen is crucial to the lifetime. Plasma-enhanced chemical vapor deposition (PECVD) is used to deposit a thin layer of carbon nitride at low deposition temperatures, below 100 °C, on a polymer LED that uses poly[2-methoxy-5-(2´-ethylhexyloxy)-1,4- phenylene vinylene] (MEH-PPV) as active layer. A thin layer of carbon nitride acts as barrier for humidity, but is still sufficiently bendable to be used in flexible polymer LEDs. The characteristics of carbon nitride and MEH-PPV films have been investigated using optical spectroscopy, with particular emphasis on the degradation process of MEH-PPV under illumination. The measurements show that the carbon nitride coating indeed protects the polymer film and diminishes the photo-oxidation considerably. To study the effect of the encapsulation in real devices, polymer LEDs were made and their current-voltage characteristics confirm the enhanced lifetime in the presence of a carbon nitride barrier layer. However, the target, a lifetime of more than 10,000 hours for commercial applications, was not achieved. The remaining chapters of this thesis describe the investigations of PEDOT:PSS. PEDOT:PSS is widely used in organic electronics. So far, relatively little attention has, been paid to the mechanisms of charge transport in this material and the correlation of those properties to the morphology. In Chapter 3, scanning probe microscopy (SPM) and macroscopic conductivity measurements are used to obtain a full 3D morphological model that explains, qualitatively, the observed anisotropic conductivity of spin coated PEDOT:PSS thin films. Topographic scanning probe microscopy (STM) and cross-sectional atomic force microscopy images (X-AFM) reveal that the thin film is organized in horizontal layers of flattened PEDOT-rich particles that are separated by quasi-continuous PSS lamella. In the vertical direction, the horizontal PSS insulator lamellas lead to a reduced conductivity and impose nearest-neighbor hopping (nn-H) transport. In the lateral direction, 3D variable-range hopping (3D-VRH) transport takes place between PEDOT-rich clusters which are separated by much thinner barriers, leading to an enhanced conductivity in this direction. This discussion is extended in Chapter 4, where a quantitative description of the length scales of the predominant transport is obtained. Particularly, it is demonstrated that the hopping process takes place between PEDOT-rich islands and not between single PEDOT segments or dopants in the lateral direction, whilst in the vertical direction the current limiting hopping transport occurs between dilute states inside the quasi-insulating PSS lamellas. By a post-treatment it is possible to modify PEDOT:PSS to raise its conductivity, by orders of magnitude. Typically, the addition of sorbitol to the aqueous dispersion of PEDOT:PSS that is used to deposit thin films via spin coating leads to an enhancement of the conductivity after thermal annealing. The causes and consequences of such behavior were investigated in detail. Chapter 5 describes the various properties of the highly conductive sorbitol-treated PEDOT:PSS, such as the conductivity itself, and the effects of thermal annealing and exposure to moisture. It is found that the conductivity enhancement upon addition of sorbitol is accompanied by a better environmental stability. Surprisingly, the electrical conductivity of PEDOT:PSS thin films without sorbitol treatment is increased by more than one order of magnitude in an environment with more than 30-35 % relative humidity. This effect is attributed to an ionic contribution to the overall conductivity. Thermal gravimetric analysis (TGA), direct insert probe-mass spectrometry (DIP-MS) and modulation differential scanning calorimetry (MDSC) were used as additional tools to demonstrate that, after thermal treatment, the concentration of sorbitol in the final PEDOT:PSS layer is negligibly small. In Chapter 6, scanning Kelvin probe microscopy (SKPM) is employed to measure the surface potential and work function of this PEDOT:PSS films that were deposited from water with different sorbitol concentrations. It is shown that work function of PEDOT:PSS is reduced with increasing sorbitol concentration. This shift can be explained by and is in agreement with- a reduction in the surface enrichment with PSS of the film. To study the charge transport properties of the highly conductive sorbitoltreated PEDOT:PSS films, temperature dependent and electric field dependent measurements are correlated with morphological analysis by STM in Chapter 7. It is found that by sorbitol treatment the hopping transport changes from 3DVRH to 1D-VRH. This transition is explained by a sorbitol-induced selforganization of the PEDOT-rich grains into 1D aggregates that are aligned within micrometer sized domains, as observed in STM images. Anisotropia Condutividade elétrica Deposição de vapor químico Diodos emissores de luz Eletrônica orgânica Encapsulamento Microscopia de força atômica Microscopia eletrônica de varredura Polímeros Anisotropy Atomic force microscopy Chemical vapor deposition Conducting polymers Electrical conductivity Encapsulation Hopping conduction Light-emitting diodes Organic electronics Scanning tunneling microscopy
906	Análise do potencial de calibração da força óptica através de dispositivos de microscopia de força atômica / Analysis of the calibration potential of optical force through atomic force microscopy devices Marques, Gustavo Pires, 1978- 20 August 2018 (has links) Orientador: Carlos Lenz Cesar / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-20T14:50:59Z (GMT). No. of bitstreams: 1 Marques_GustavoPires_M.pdf: 1771357 bytes, checksum: 8ee6919633e2615608f25b33bec98e96 (MD5) Previous issue date: 2005 / Resumo: O microscópio de força atômica é uma ferramenta que possibilita a medida de forças precisamente localizadas com resoluções no tempo, espaço e força jamais vistas. No coração deste instrumento está um sensor a base de uma viga (cantilever) que é responsável pelas características fundamentais do AFM. O objetivo desta pesquisa foi usar a deflexão deste cantilever para obter uma calibração rápida e precisa da força da armadilha da pinça óptica, assim como testar e comparar com os método tradicionalmente utilizados para este propósito. Para isso, foi necessário analisar e entender o condicionamento de sinais utilizados no AFM. Foram estudados cantilever tradicionais, cujo sistema de detecção é baseado na deflexão de um feixe laser em conjunto com fotodetectores, bem como cantilevers piezoresistivos. Cantilevers piezoresistivos fornecem uma alternativa simples e conveniente aos cantilevers ópticos. A integração de um elemento sensorial dentro do cantilever elimina a necessidade de um laser externo e de um detector utilizados na maioria dos AFMs. Isto elimina a etapa delicada de alinhamento da laser ao cantilever e fotodetector que normalmente precede uma medida com AFM, uma simplificação que expande o potencial do AFM para o uso em meios adversos, como câmaras de ultra alto vácuo ou, como no caso específico das Pinças Ópticas, onde existem esferas em solução líquida e também restrições de dimensão / Abstract: The atomic force microscope (AFM) is a tool that enables the measurement of precisely localized forces with unprecedented resolution in time, space and force. At the heart of this instrument is a cantilever probe that sets the fundamental features of the AFM. The objective of this research has been using the deflection of this cantilever to get a fast and accurate calibration of optical tweezers trap force, as well as testing and comparing to the traditionally used methods of calibration for this purpose. For that it was necessary to resolve and understand the sensors signals conditioning used in the AFM. Traditional cantilevers, whose detection system is based on the deflection of a laser beam in addition with a photodetector, as well as piezoresistive cantilevers has been studied. Piezoresistive cantilevers provide a simple and convenient alternative to optically detected cantilevers. Integration of a sensing element into the cantilever eliminates the need for the external laser and detector used in most AFMs. This removes the delicate step of aligning the laser to the cantilever and photodetector which usually precedes an AFM measurement, a simplification which expands the potential of the AFM for use in difficult environments such as ultrahigh vacuum chambers or, as in Optical Tweezers specific case, where there are spheres into a liquid solution as well as dimensional constraints / Mestrado / Física / Mestre em Física Calibração Detectores Lasers Fotodetectores Microscopia de força atômica Pinças óticas Força ótica Cantilever de silício Cantilever piezoresistivo Piezoresistividade Condicionamento de sinais Baixa relação sinal ruído Calibration Sensors Lasers Photon detectors Atomic force microscopy Optical tweezers Optical force Silicon cantilever Piezoresistive cantilever Piezoresistivity Signal conditioning Low signal to noise ratio
907	Fonctionnement tribologique des articulations synoviales pathologiques : Rôle des interfaces phospholipidiques / Tribological operation of pathological synovial joints : Role of phospholipidic interfaces Corneci, Magdalena Carla 21 September 2012 (has links) Afin d’améliorer l’efficacité des traitements des pathologies articulaires, en tenant compte de leur complexité et de leur ampleur, des études récentes ont mis en évidence le rôle des assemblages lipidiques associés à la structure discontinue du fluide synovial dans le contrôle du fonctionnement tribologique articulaire. Ceci à conduit à la mise au point d’un modèle tribologique ex vivo (thèse AM Sfarghiu, 2006), proposant un « motif élémentaire » de la biolubrification articulaire, constitué de l’empilement d’interfaces phospholipidiques et de couches aqueuses. En utilisant ce modèle, l’objectif de ce travail a été d’étudier l’évolution des interfaces phospholipidiques du fluide synovial en présence de pathologies. Pour ce faire, une méthodologie nano-bio-tribologique alliant des analyses biochimiques, physicochimiques, nano-mécaniques et tribologiques a été utilisée. Les résultats de ces analyses montrent : l’influence de la faible rugosité des surfaces frottantes caractérisant les stades précoces des pathologies et celle des propriétés des interfaces phospholipidiques (liées à la variation de leur composition) sur la résistance mécanique, l’évolution au cours du frottement et la dégradation in situ des assemblages lipidiques des fluides synoviaux pathologiques. Le comportement des assemblages lipidiques est accentué par l’action des enzymes associées aux pathologies. Par conséquent, le fonctionnement articulaire dépend de la résistance mécanique des interfaces phospholipidiques et pour obtenir des coefficients de frottement très bas, l’accommodation de vitesse doit s’effectuer au niveau des couches d’hydratation qui entourent les ions présents dans la couche aqueuse. Ces résultats permettront de comprendre à court terme l’évolution des interfaces phospholipidiques dans les pathologies articulaires et, à plus long terme le bon enchaînement cause/conséquence responsable d’une pathologie articulaire afin de développer des traitements plus efficaces, ciblés et non prothétiques. / In order to improve the effectiveness of joint diseases’ treatments, given their complexity and magnitude, recent studies have highlighted the role of lipid assemblies associated with the discontinuous structure of the synovial fluid (SF) in the tribological performance of joint operation. Thus, an ex vivo tribological model (AM Sfarghiu, PhD thesis, 2006) providing a "basic pattern" for joint biolubrification was developed. It consists of the stack of phospholipidic interfaces and aqueous layers. Using this model, the objective of this work was to study the evolution of phospholipidic interfaces of SF within pathological state. Therefore, a nano-bio-tribological methodology combining biochemical, physicochemical, nano-mechanical and tribological analysis was used. The results of these analyses show: the influence of even small rubbing surfaces’ roughness characteristics of early stage illness and that of phospholipidic interfaces’ properties (related to their composition change) on the mechanical strength, changes in friction and in situ degradation of lipidic assemblies of pathological SF. The tribological operation is highlighted by enzymes’ associated with diseases. Thus, joint operation depends on the mechanical strength of phospholipidic interfaces and to obtain very low friction coefficients, velocity accommodation must be done at the level of hydration layers surrounding ions in the aqueous solution. These results would therefore allow better understanding of the evolution of phospholipidic interfaces in joint diseases and of the proper cause/consequence sequence responsible for a joint disease in order to develop more effective, targeted and non prosthetic treatments. Biosciences Biomécanique Nano-bio-tribologie Analyse lipidomique Articulation synovial pathologique Fluide synovial Assemblage lipidique Lubrification par couche Triplet bio-tribologique Modèle ex vivo Phospholipides Coefficient de rétrodiffusion Microscopie optique en fluorescence Microscopie de Force Atomique Biosciences Biomechanics Nanobiotribology Lipidomics Pathological synovial joint Synovial fluid Lipids assemblies Lubrication layers Biotribological triplets Ex vivo model Phospholipids Frictions Fluorescence optical microscopy Atomic force microscopie 571.407 2
908	Relaxation des contraintes dans les couches de chromine développées sur alliages modèles (NiCr et Fe47Cr) : apport de la diffraction in situ à haute température sur rayonnement Synchrotron à l’étude du comportement viscoplastique : effets d’éléments réactifs / Stress release in chromia scales formed on model alloys (NiCr and Fe47Cr) : contribution of in situ diffraction at high temperature using Synchrotron radiation in investigating their viscoplastic behaviour : effects of reactive elements Rakotovao, Felaniaina Nirisoa 30 November 2016 (has links) L’intégrité des couches protectrices d’oxyde thermiques se développant à haute température à la surface des matériaux métalliques dépend des niveaux de contraintes générées et de leurs mécanismes de relaxation. Le comportement des films de chromine formés sur les alliages modèles NiCr et Fe47Cr a ici été étudié. Les contraintes résiduelles générées après oxydation des substrats à différentes températures (700°C-1000°C) et durées d’oxydation (3h et 18h) ont été déterminées par spectroscopie Raman. Ces contraintes évoluent avec les conditions d’oxydation de manière monotone (système Ni30Cr/Cr2O3) ou non (système Fe47Cr/Cr2O3). Les variations de déformation à l’échelle du grain ont aussi été suivies par AFM. Pour le premier système, relaxation non destructive par fluage de l’oxyde et délamination sont plus ou moins activées en bon accord avec l’évolution des contraintes résiduelles. Dans le second cas, un mode supplémentaire de relaxation des contraintes par fissuration doit également entrer en jeu. Les propriétés viscoplastiques des couches de chromine formées sur Ni30Cr et Ni28Cr ont pu être caractérisées par diffraction in situ à haute température sur rayonnement Synchrotron, en découplant les effets liés à l’activation thermique de ceux liés à la taille de grain. Le type de fluage intervenant dans la relaxation des contraintes générées dans les couches de chromine a pu être mis en évidence en confrontant les résultats obtenus à un modèle théorique de fluage diffusion. La valeur de l’énergie d’activation associée (130 kJ/mol) a montré, par comparaison avec les données de la littérature, que ce mode non destructeur de relaxation est gouverné par le transport des anions d’oxygène aux joints de grains de l’oxyde. L’ajout d’un élément réactif (Y ou Zr) au substrat Ni28Cr provoque, avec l’augmentation de la quantité introduite, un ralentissement croissant de la cinétique de formation des films de chromine. Cependant, cette quantité introduite ne semble exercer aucun effet significatif sur les niveaux de contraintes résiduelles. A l’échelle microscopique, on constate en général une diminution de la taille des grains avec la présence d’éléments réactifs, une double distribution ayant aussi été observée pour les quantités élevées. Les résultats issus des mesures par diffraction in situ et ceux obtenus par AFM (glissement aux joints de grains de l’oxyde) ont montré que la capacité des films de chromine à relaxer les contraintes grâce à leur comportement viscoplastique pourrait être retardée et/ou diminuée en présence des éléments yttrium et zirconium. Toutefois, ce mécanisme pourrait opérer pour des épaisseurs plus faibles des films de chromine. / Integrity of protective oxide scales developing at the metallic alloys surface at high temperature depends on the stress generation and their relaxation mechanisms. In this work, the behaviour of chromia scales formed on NiCr and Fe47Cr model alloys has been investigated. Raman spectroscopy was used to determine the residual stress level in chromia thin films after oxidation at different temperatures (700°C-1000°C) for 3 h and 18 h. A monotonous evolution of residual stresses with oxidation conditions was noted for the Ni30Cr/Cr2O3 system but not for the Fe47Cr/Cr2O3 one. The strain variations at microscopic scale was also determined by using atomic force microscopy. For the first studied system, non destructive relaxation by creep of the oxide and buckling can be more or less activated, in agreement with the residual stresses evolution. And a third additional stress release mode by intra film cracking could take place for the second system. In situ high temperature oxidation coupled with Synchrotron X-rays diffraction was also used to characterize the viscoplastic properties of chromia scales grown on Ni30Cr and Ni28Cr, with dissociating the effects related to thermal activation and grain size. The creep mechanism responsible of stress release in chromia scales has been evidenced by comparing experimental results with a diffusional creep model. Confrontation of the obtained activation energy (130 kJ.mol-1) with literature results has shown that this non destructive relaxation mode was likely governed by grain boundary transport of oxygen species. When a reactive element (Y or Zr) was added to the metallic substrate Ni28Cr, an important decrease of the oxidation rate was noted when increasing the amount of introduced element. No significant effect of this quantity on the residual stress level was however observed. At microscopic scale, a reduction of grain size has been also noted and two distinguished grains distribution appeared for the higher quantities. Results of in situ Synchrotron diffraction measurements and those of atomic force microscopy (grain boundary sliding) showed that the ability of chromia films to release stress thanks to their viscoplastic properties could be delayed and/or decreased with the presence of an active element. However, this mechanism could operate for smaller chromia films thicknesses. Oxydation à haute température Ni3OCr Fe47Cr Couche de chromine Éléments réactifs Spectroscopie Raman Contraintes résiduelles Diffraction sur Rayonnement Synchrotron Fluage diffusion Microscopie à force atomique Glissement aux joints de grains High temperature oxidation Ni3OCr Fe47Cr Chromia scale Reactive element Raman spectroscopy Residual stresses Synchrotron Radiation Diffusion creep Atomic force microscopy Grain boundary sliding
909	Growth Monitoring of Ultrathin Copper and Copper Oxide Films Deposited by Atomic Layer Deposition / Untersuchungen zum Wachstum ultradünner Kupfer- und Kupferoxid Schichten mittels Atomlagenabscheidung Dhakal, Dileep 25 October 2017 (has links) (PDF) Atomic layer deposition (ALD) of copper films is getting enormous interest. Ultrathin Cu films are applied as the seed layer for electrochemical deposition (ECD) of copper in interconnect circuits and as the non-magnetic material for the realization of giant magnetoresistance (GMR) sensors. Particularly, Co/Cu multi-layered structures require sub 4.0 nm copper film thickness for obtaining strong GMR effects. The physical vapor deposition process for the deposition of the copper seed layers are prone to non-conformal coating and poor step coverage on side-walls and bottoms of trenches and vias, and presence of overhanging structures. This may cause failure of interconnections due to formation of voids after copper ECD. ALD is the most suitable technology for the deposition of conformal seed layers for the subsequent ECD in very high aspect ratio structures, also for the technology nodes below 20 nm. Surface chemistry during the ALD of oxides is quite well studied. However, surface chemistry during the ALD of pure metal is rather immature. This knowledge is necessary to optimize the process parameters, synthesize better precursors systems, and enhance the knowledge of existing metal ALD processes. The major goal of this work is to understand the surface chemistry of the used precursor and study the growth of ultrathin copper films using in-situ X-ray photoelectron spectroscopy (XPS). Copper films are deposited by ALD using the precursor mixture consisting of 99 mol% [(nBu3P)2Cu(acac)], as copper precursor and 1 mol% of Ru(η5 C7H11)(η5 C5H4SiMe3), as ruthenium precursor. The purpose in having catalytic amount of ruthenium precursor is to obtain the Ru doped Cu2O layers for subsequent reduction with formic acid at temperatures below 150 °C on arbitrary substrates. Two different approaches for the growth of ultrathin copper films have been studied in this dissertation. In the first approach, direct thermal ALD of copper has been studied by using H2 as co-reactant on Co as catalytic substrate. In the second approach, Ru-doped Cu2O is deposited by ALD using wet-O2 as co-reactant on SiO2 as non-catalytic substrate. The Ru-doped Cu2O is successfully reduced by using either formic acid or carbon-monoxide on SiO2. / Atomlagenabscheidung (ALD) von Kupfer steht im Fokus der ALD Gemeinschaft. Ultradünne Kupferschichten können als Keimschicht für die elektrochemische Abscheidung (ECD) von Kupfer in der Verbindungstechnologie eingesetzt werden. Sie können ebenfalls für Sensoren, welche auf den Effekt des Riesenmagnetowiderstandes (GMR) basieren, als nicht-ferromagnetische Zwischenschicht verwendet werden. Insbesondere Multischichtstrukturen aus ferromagnetische Kobalt und Kupfer erfordern Schichtdicken von weniger als 4,0 nm, um einen starken GMR-Effekt zu gewährleisten. Das derzeit verwendete physikalische Dampfabscheidungsverfahren für ultradünne Kupferschichten, ist besonders anfällig für eine nicht-konforme Abscheidung an den Seitenwänden und Böden von Strukturen mit hohem Aspektverhältnis. Des Weiteren kann es zur Bildung von Löchern und überhängenden Strukturen kommen, welche bei der anschließenden Kupfer ECD zu Kontaktlücken (Voids) führen können. Für die Abscheidung einer Kupfer-Keimschicht ist die ALD besonders gut geeignet, da sie es ermöglicht, ultradünne konforme Schichten auf strukturierten Oberflächen mit hohem Aspektverhältnis abzuscheiden. Dies macht sie zu einer der Schlüsseltechnologien für Struckturgrößen unter 20 nm. Im Gegensatz zur Oberflächenchemie rein metallischer ALD sind die Oberflächenreaktionen für oxidische ALD Schichten sehr gut untersucht. Die Kenntnis der Oberflächenchemie während eines ALD Prozesses ist essenziel für die Bestimmung von wichtigen Prozessparametern als auch für die Verbesserung der Präkursorsynthese ansich. Diese Arbeit beschäftigt sich mit der Untersuchung der Oberflächenchemie und Charakterisierung des Wachstums von ultradünnen Metall-Cu-Schichten mittels In-situ XPS, welche eines indirekten (Oxid) bzw. direkten Metall-ALD Prozesses abgeschieden werden, wobei die Kupfer-Oxidschichten im Anschluss einem Reduktionsprozess unterworfen werden. Hierfür wird eine Präkursormischung bestehend aus 99 mol% [(nBu3P)2Cu(acac)] und 1 mol% [Ru(η5 C7H11)(η5-C5H4SiMe3)] verwendet. Die katalytische Menge an Ru, welche in der entstehenden Cu2O Schicht verbleibt, erhöht den Effekt der Reduktion der Cu2O Schicht auf beliebigen Substraten mit Ameinsäure bei Wafertemperaturen unter 150 °C. In einem ersten Schritt wird ein direkter thermisches Kupfer ALD-Prozess, unter Verwendung von molekularem Wasserstoff als Coreaktant, auf einem Kobalt-Substrat untersucht. In einem zweiten Schritt wird ein indirekter thermischer Cu2O-ALD-Prozess, unter gleichzeitiger Verwendung von Sauerstoff und Wasserdampf als Coreaktant, mit anschließender Reduktion durch Ameinsäure oder Kohlenstoffmonoxid zu Kupfer auf den gleichen Substraten betrachtet. Die vorliegende Arbeit beschreibt das Wachstum von ultradünnen und kontinuierlichen Kupfer-Schichten mittels thermischer ALD auf inerten- SiO2 und reaktiven Kobalt-Substraten. Atomlagenabscheidung (ALD) Kupferoxid (Cu2O) Kupfer Ruthenium Oberflächenchemie Röntgenphotoelektronspektroskopie (XPS) Atomic Layer Deposition (ALD) Cuprous Oxide (Cu2O) Copper Ruthenium Surface chemistry X-ray photoelectron spectroscopy (XPS) Low energy ion scattering (LEIS) and Atomic force microscopy (AFM) ddc:530 ddc:620 Kupfer Kupferoxide Metallisierungsschicht Reduktion ULSI
910	High speed bio atomic force microscopy : application à l'étude de la structure et dynamique d'assemblage supramoléculaires : étude des interactions au niveau de la cellule Ewald, Maxime 12 December 2011 (has links) Le microscope à force atomique (AFM) fait partie des microscopies de champ proche dites à sonde locale. De par sa versatilité, un grand nombre de domaines des nanosciences tant en physique, que chimie ou biologie utilisent cette technique. Cependant, le champ d’investigation de la microscopie AFM classique est restreint temporellement et spatialement. En effet, en raison de sa limite de vitesse d’acquisition d’image et sa limite de caractérisation des interactions en surface, des études de dynamique moléculaire ou d’éléments sub-surface ne sont pas envisageables. Nous montrons donc que la caractérisation en volume est permise en utilisant une méthode d’imagerie non destructive, la microscopie de champ proche holographique ultrasonore (SNFUH). Cette méthode développée pour étudier à l.air et en liquide, a fourni des informations localisées en profondeur avec une haute résolution spatiale, en utilisant des fréquences de résonance dans la gamme du MHz. Une calibration a été effectuée sur des échantillons de structures enterrées ou non, réalisés par lithographie e-beam. Ces échantillons ont été utilisés pour ajuster les fréquences de résonance et comprendre la formation des images en mode acoustique (profondeur investiguée et inversion de contraste). Cet outil non invasif et innovant de caractérisation a donc été développé. Il présente un énorme potentiel pour des échantillons biologiques en termes de résolution et d’information. Les microscopes AFMclassique et acoustique SNFUH sont soumis à des contraintes de temps. Pour s’en affranchir, un prototype, le microscope à force atomique haute-vitesse (HS-AFM) a été développé par l’équipe du Professeur T. Ando à l’Université de Kanazawa (Japon). Il autorise ainsi le balayage à vitesse vidéo, i.e. 25 images/s, en milieu liquide. Nous avons amélioré le prototype avec une nouvelle génération de boucle d’asservissement et augmenté la zone de caractérisation. La résolution dépend fortement du levier utilisé. De plus une qualité d’image supérieure est obtenue grâce à l’utilisation de surpointes en carbone sur ces mêmes leviers. Finalement, nous montrons des résultats obtenus avec ces deux techniques de microscopies sur différents édi.ces biologiques en milieu liquide. Ainsi, avec le microscope AFM haute-vitesse, des dynamiques biomoléculaires ont pu être visualisées (ex : structures protéine-ADN) avec une résolution nanométrique. Puis une étude des changements conformationnels intracellulaires de kératinocytes vivantes dans leur milieu physiologique a été réalisée par microscopie acoustique SNFUH et montre la dégradation du matériel biologique. L’ensemble de ces résultats ouvre un nouveau champ d’investigation dans le domaine de la biologie. / The atomic force microscope (AFM) made part of scanning near-field probe microscopy. Thanks to its versatility, many fields as physics, chemistry or biology use this technique. However, the field of investigation of the classical AFM microscope is limited temporally and spatially. Indeed, due to his scan speed limitation and surface interaction caracterisation limitation, studies of molecular dynamics and sub-surface elements are not possible. We show that the volume caracterisation is permitted using a non-destructive imaging method, called Scanning Near-Field by Ultrasound Holography (SNFUH). This tool developed for study in air and liquid has provided depth information as well as spatial resolution at the nanometer scale using resonant frequencies of about range of MHz. Calibration has been performed on samples of buried or not structures made by e-beam lithography and have been used to adjust the resonant frequency and understand the acoustic image formation (depth investigation and contrast in-version). We have developed a non-invasive and innovative tool of characterization for biology : he presents a huge potential for biological samples in terms of resolution and information. Classical AFM and acoustic SNFUH microscopes are time resolution limited. To overcome this time constraint, a prototype, High Speed Atomic Force Microscope (HS-AFM), has been developed by the team of Prof. T. Ando, Kanazawa University (Japan). It allows a scan rate at video speed, i.e. 25 frames/s, in liquid medium. We have improved the prototype, through a new generation of feedback control and increased the scan area. The resolution depends strongly of the probe used. Moreover a better image quality is obtained through the use of carbon tips on these cantilevers. Finally, we show our results obtained with these two microscopy techniques about biological buildings in liquid environment. Thereby, with the HS-AFM microscope, biomolecular dynamics have been visualized (e.g. protein-DNA structures) with nanometric resolution. Then a study about intracellular conformational changes of keratinocytes living cells in their physiological medium has been realized by acoustic microscopy SNFUH and show deterioration of biological components. All of these results provide new insights in biology field. Surpointes Cellules vivantes Assemblages supramoléculaires PDNA Nanofabrication EBD tips Living cells Supramolecular assemblies PDNA Nanofabrication 621.36

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