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Návrh, výroba a testování grafenových biosenzorů / Design, fabrication and testing of graphene biosensorsTripský, Andrej January 2020 (has links)
Pokrok ve vývoji nanotechnologií nám poskytuje dobrou příležitost k vývoji nových špičkových zařízení. Tato práce si klade za cíl vyrobit, popsat a změřit grafenové pH senzory na dvou různých substrátech - polymeru parylenu C a SiO2. Tento pH senzor je prvním krokem ve vývoji nositelné náplasti monitorující stav kůže a možné infekce. Grafen je 2D materiál na bázi uhlíku se zajímavými vlastnosti a nadějnými aplikacemi. Úspěšně jsme provedli dva různé experimenty sloužící k charakterizaci grafenových senzorů a jejich odezvu na různé hodnoty pH. V prvním experimentu jsme použili horní elektrolytické hradlo k určení bodu neutrality (Diracův bod). Druhý experiment popsal změnu rezistence grafenu jako funkce pH. Dále jsme také funkcionalizovali grafen polyanilinem, abychom zlepšili jeho vlastnosti. Prokázali jsme citlivost grafenových senzorů na pH pro oba substráty a objevili jsme několik výzev jako potřebu kontroly iontové síly, experimentů samotných a destrukce grafenu.
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Modeling of Ion Transport for Micro/Nano Size Particles in Coulter Counter ApplicationQin, Zhenpeng 09 June 2009 (has links)
No description available.
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INVESTIGATION OF MECHANICAL PERFORMANCE AND FORMABILITY OF WELDED AND BRAZED SHEET MATERIALSShaker, Mohammed 11 1900 (has links)
In the last two decades or so, hybrid structures from dissimilar materials and/or sheet gauges have been developed to achieve weight reduction while maintaining or even improving structural performance such as stiffness, crash and impact behavior. In particular, welded and brazed sheet materials in the form of tailor blanks (TBs) are being increasingly used or considered for future applications in different applications such as automotive, aerospace and marine constructions as they offer attractive combination of strength and performance in applications where weight reduction is desirable. However, technical problems are often encountered during forming of TBs from dissimilar base sheet materials with different thickness and/or strength. These include weld line movement and non-uniform deformation. Additionally, there are premature weld failures due to the presence of softening zone (as in TBs made from advanced high strength steels), and brazed interface failure due to insufficient bonding and wetting (as in TBs made from steel and aluminum). These areas of forming of TBs need to be scientifically studied to advance the use of dissimilar materials.
The current research involves an understanding of deformation and forming behavior of steel-to-steel tailor welded blanks (TWBs) made from advanced high strength steel (AHSS) such as dual phase (DP780) steel. The research also involves a study of deformation behavior of steel-to-aluminum tailor brazed blanks (TBBs). TWBs have been successfully joined using a relatively new welding techniques such as defocused fiber laser welding. TBBs, on the other hand, have been successfully produced by fiber Laser/MIG hybrid brazing and Cold Metal Transfer brazing (CMT).
In addition, the formability of TWBs of different gauges and/or strengths was tested by using a new, simple and reproducible method of formability testing using a double-layer blank method. This method was devised and assessed for testing various steel combinations in different strain paths such that the weld line stayed in position with respect to forming tools and is subjected to the same stress and strain state as the parent material in the weld and its vicinity. Moreover, results from conventional stretch forming tests, single-layer blank, and the double-layer method were compared at the macroscopic level (such as weld line movement, forming limit etc.) as well as at the microscopic level (such as failure location within the weld and failure mode) to isolate the advantages of the proposed double-layer method.
With regard to TBBs made by fiber Laser/MIG and CMT brazing methods, a fundamental knowledge and understanding of the local deformation behavior and material plastic ow in and around the brazed steel-aluminum interfaces were obtained by conducting miniature tensile mechanical tests that focus on continuous observation of the brazed region under a high magnification optical microscope to assess the ductility of the brazed joint and its capacity to carry the load during a material shaping process. / Thesis / Doctor of Philosophy (PhD) / In the last two decades or so, hybrid structures from dissimilar materials and/or sheet gauges have been developed to achieve weight reduction while maintaining or even improving structural performance such as stiffness, crash and impact behavior. In particular, welded and brazed sheet materials in the form of tailor blanks (TBs) are being increasingly used or considered for future applications in different applications such as automotive, aerospace and marine constructions as they offer attractive combination of strength and performance in applications where weight reduction is desirable. However, technical problems are often encountered during forming of TBs from dissimilar base sheet materials with different thickness and/or strength. These include weld line movement and non-uniform deformation. Additionally, there are premature weld failures due to the presence of softening zone (as in TBs made from advanced high strength steels), and brazed interface failure due to insufficient bonding and wetting (as in TBs made from steel and aluminum). These areas of forming of TBs need to be scientifically studied to advance the use of dissimilar materials.
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Surface Forces in Thin Liquid FilmsHuang, Kaiwu 10 January 2020 (has links)
Thin liquid films (TLFs) of water are ubiquitous in daily lives as well as in many industrial processes. They can be formed between two identical phases, as in colloid films between two macroscopic surfaces and foam films between two air bubbles; and between two dissimilar phases, as in wetting films. Stability of the colloids, foams, and wetting films is determined by the surface forces in the TLFs. Depending on the nature of the surfaces involved, the stabilities can be predicted using combinations of three different forces, i.e., the van der Waals, electrical double layer (EDL), and hydrophobic forces. The objective of the present work is to study the roles of these forces in determining the stabilities of the TLFs of water confined between i) an air bubble and a hydrophobic surface and ii) an oil drop and a hydrophobic surface, with particular interest in studying the role of the hydrophobic force.
The first part of the study involves the measurement of the surface forces in the TLFs confined between bitumen drops and mineral surfaces. Deformation of bitumen drops has been monitored by interferometry while it approaches a flat surface. By analyzing the spatiotemporal film profiles, both the capillary and hydrodynamic forces have been calculated using the Young-Laplace equation and the Reynolds lubrication approximation, respectively, with the surface forces being determined by subtracting the latter from the former. The results are useful for better understanding the effects of electrolyte and pH on bitumen liberation and recovery by flotation and for developing a filtration model from first principles.
The second part of the study involves the surface force measurement in wetting (flotation) films. Surface forces in the TLFs of water on silica surfaces have been measured using the force apparatus for deformable surfaces (FADS) using an air bubble as a force sensor. The measurements have been conducted in the presence of various cationic surfactants such as dodecylamine hydrochloride (DAH), and alkyltrimethylammonium chloride (CnTACl), electrolytes, and polymers. The results show that film stability and hence the kinetics of film thinning can be greatly improved by the control of bubble ζ-potentials, whose role in flotation has long been neglected in flotation studies.
Force measurements have also been conducted in the TLFs of water confined between oil drops and hydrophobic surfaces. Stability of this type of film plays an important role in a process of using oil drops rather than air bubbles to collect hydrophobic particles from aqueous phase. The force measurements conducted in the present work show that hydrophobic forces are much stronger in water films formed between oil drops and hydrophobic surfaces than in water films formed between air bubbles and hydrophobic surfaces, which can be attributed to the differences in the Hamaker constants involved. / Doctor of Philosophy / When two macroscopic surfaces in water are brought to a close proximity, a thin liquid film (TLF) is formed in between, with its stability being determined by the surface forces present in the film. TLFs are ubiquitous in daily lives and play a decisive role in many industrial processes such as mineral flotation, food processing, oil extraction, heat transfer, etc. In the present work, the surface forces present in wetting films have been measured by approaching an air bubble (or an oil drop) slowly toward a flat surface while monitoring the curvature changes during film thinning by interferometry and calculating the capillary forces using the Young-Laplace equations. By analyzing the results in view of the Frumkin-Derjaguin isotherm and the extended DLVO theory, it was possible to determine the changes in the van der Waals, electrical double-layer (EDL), and hydrophobic forces during film thinning. The results show that both the EDL and the long-range component of the hydrophobic force control the kinetics of film thinning and rupture while the contact angle formation is controlled by the van der Waals force and the short-range hydrophobic force. It has been found also that n-alkane drops form substantially larger contact angles than air bubbles on a hydrophobic surface due to the fact that the van der Waals force is attractive in the drop-surface interactions while the same is repulsive in the bubble-surface interactions. These observations have a profound implication in flotation, that is, oil drops can recover hydrophobic particles from an aqueous phase better than air bubbles.
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An EKF-Based Performance Enhancement Scheme for Stochastic Nonlinear Systems by Dynamic Set-Point AdjustmentTang, X., Zhang, Qichun, Hu, L. 06 May 2020 (has links)
Yes / In this paper, a performance enhancement scheme has been investigated for a class of stochastic nonlinear systems via set-point adjustment. Considering the practical industrial processes, the multi-layer systematic structure has been adopted to achieve the control design requirements subjected to random noise. The basic loop control is given by PID design while the parameters have been fixed after the design phase. Alternatively, we can consider that there exists an unadjustable loop control. Then, the additional loop is designed for performance enhancement in terms of the tracking accuracy. In particular, a novel approach has been presented to dynamically adjust the set-points using the estimated states of the systems through extended Kalman filter (EKF). Minimising the entropy criterion, the parameters of the set-point adjustment controller can be optimised which will enhance the performance of the entire closed-loop systems. Based upon the presented scheme, the stochastic stability analysis has been given to demonstrate that the closed-loop tracking errors are bounded in probability one. To indicate the effectiveness of the presented control scheme, the numerical examples have been given and the simulation results imply that the designed systems are bounded and the tracking performance can be enhanced simultaneously. In summary, a new framework for system performance enhancement has been presented even if the loop control is unadjustable which forms the main contribution of this paper.
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Interfacial properties of calcium montmorillonite in aqueous solutions : Density functional theory and classical molecular dynamics studies on the electric double layerYang, Guomin January 2017 (has links)
The swelling properties of Bentonite are highly affected by clay content and the clay-water interactions that arise from the ion distribution in the diffuse double layer formed near the charged montmorillonite (or smectite) surfaces. Existing continuum models describing the electric double layers, such as classical Poisson-Boltzmann and DLVO theory, ignore the ion-ion correlations, which are especially important for multivalent ions at high surface charge and ionic strength. To better understand the clay-water interactions, atomistic models were developed using both density functional theory of fluids (DFT) as well as classical molecular dynamics (MD) methods. In order to increase our understanding of water-saturated, swelling smectite clays, a DFT, technique was initially developed that allowed more accurate predictions of important thermodynamic properties of the diffuse double layers. This DFT approach was then extended to handle systems with mixtures of different sizes and charges. The extended DFT model was verified against experiments and Monte-Carlo simulations. One practical application was to predict the ion exchange equilibria in Bentonite clays, which have wide practical usage in different areas. Nevertheless, in the DFT work it was realized that DFT demands that the particles, ions in this case, which are described as hard spheres, realistically cannot be described as such at low water loadings, when ion specific hydration forces govern the electric double layer properties. To study how the deformation of the hydration shells of Ca2+ influences the properties of compacted smectite clays, MD simulations using the CLAYFF forcefield were employed in order to account for the deformation of the hydration shells. Comparisons of DFT and MD modeling then allowed to demonstrate under which conditions DFT modeling becomes increasingly inaccurate and when it still can give accurate results. / Under senare år har mycket forskning ägnats åt att förstå egenskaperna hos svällande leror som används för att skydda mot läckage av föroreningar från kontaminerade områden och från framtida slutförvar av radionuklider. Den fria svällningen förorsakas av de starka osmotiska krafter som uppstår när vatten tränger in mellan de tunna elektriskt negativt laddade lermineralskikten och löser de laddningskompenserande jonerna i det diffusa dubbelskiktet. I flera arbeten användandes av sk. kontinuum-teori har vattenmolekylens form, specifika orientering och bindning till katjonerna i de nanometerstora utrymmen mellan lerpartiklarna ej beaktats samt ej heller hur de hydratiserade jonerna orienteras på de atomärt ojämna ytorna. Detta möjliggörs dock genom modellering av de enskilda atomernas och jonernas interaktioner med molekyldynamik simuleringar, MD. I detta arbete har programmet Gromacs använts tillsammans med kraftfältet CLAYFF för att studera dessa fenomen i montmorillonitleror med natrium- och kalciumjoner. Simuleringarna visar att natrium bildar transienta innersfärkomplex vilka orienterar sig i bi-triangulära fördjupningar på ytan, ungefär 3.8 Å från mitt-planet mellan lerytorna. Denna orientering observeras ända upp till att avståndet mellan ytorna ökat till större än motsvarande fem lager vattenmolekyler mellan lerpartiklarnas ytor. Detta sker inte med kalcium, oberoende av avståndet mellan ytorna. Natriumjoner koordineras med fyra vattenmolekyler och en syreatom på leran vid ett lager vatten mellan ytorna och med fem till sex vattenmolekyler, ortogonalt orienterade med ökande mängd vatten mellan ytorna, och med en hydratiserad jon-radie av 3.1 Å. Kalcium koordinerar till sju vattenmolekyler vid ett vattenlager mellan ytorna, men ökar till åtta ortogonalt orienterade vattenmolekyler med en jonradie på 3.3 Å vid större avstånd. Generellt visas att när avståndet mellan lerytorna är mindre än ca 10 Å, deformeras de annars symmetriskt hydratiserade jonerna. En jämförelse mellan MD simuleringar och med klassisk täthetsfunktionalteori, DFT, visar att den senare inte kan beskriva hur yttersfärkomplexen samverkar med laddningarna bundna närmast ytan, dvs i Stern-lagret. / <p>QC 20170403</p>
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Prise en compte du caractère discontinu du solvant dans la modélisation mécanique des argiles gonflantes / Taking into account of the discontinuous nature of the solvent in the mechanical modeling of swelling claysTran, Van Duy 25 April 2017 (has links)
Ce travail vise à améliorer la description à l'échelle du nanomètre des sols argileux expansifs en utilisant la théorie de la fonctionnelle de densité (DFT). L’eau n’est plus considérée comme un solvant continu mais comme un fluide de molécules polaires individuelles. L'objectif est de reproduire les résultats issus de l'expérience ou de la modélisation numérique tels que la présence de couches d'eau discrètes dans l'espace interfolaire ou la variation de la pression de disjonction avec la distance interfolaire dans le régime de gonflement cristallin. Différents phénomènes physiques de complexité croissante sont successivement étudiés. La taille finie des molécules d'eau est tout d'abord prise en compte en modélisant l'eau comme un fluide de sphères dures traité par la théorie fondamentale de la mesure. La nature polaire du solvant est ensuite implicitement considérée en utilisant un potentiel intermoléculaire de Lennard-Jones pour reproduire les différents types d'interactions de Van der Waals. La nature dipolaire de l'eau est ensuite explicitement modélisée par un fluide dipolaire de sphères dures. Ces deux derniers modèles utilisent une approche perturbative de la théorie de la fonctionnelle de densité dans laquelle les effets de corrélation entre les molécules du fluide sont incorporés. Les ions sont finalement ajoutés afin de compléter la description de la double couche électrique. En vue d'une application au génie civil, l'expression améliorée de la pression de disjonction à l'échelle nanométrique est incluse dans une forme modifiée du principe de Terzaghi appliqué aux argiles expansives non-saturées récemment développée dans notre groupe afin de simuler numériquement le comportement hydro-mécanique des argiles gonflantes lors d’essais d'infiltration d’eau / This work aims at improving the nanoscale description of expansive clayey soils using the Density Functional Theory (DFT). Water is no longer considered as a continuous solvent but as a fluid of individual polar molecules in order to recover existing experimental and modeling results such as the presence of discrete water layers in the interplatelet space or the variation of the disjoining pressure with the interplatelet distance at low hydration level. Different physical phenomena of increasing complexity are successively considered. The finite size of the water molecules is firstly taken into account by modeling water as a Hard Sphere fluid using the Fundamental Measure Theory. The polar nature of the water solvent is then implicitly taken into account through a Lennard-Jones potential averaging the different types of Van der Waals interactions. Next the polar nature of the solvent is explicitly modelized by considering water as a Dipolar Hard Sphere fluid. These two fluid models are studied in the framework of the Density Functional Perturbation Theory in which correlation effects between the fluid molecules are incorporated. Ions are finally added in order to complete the Electrical Double Layer description at the nanoscale. With the objective of an application to civil engineering, the improved expression of the disjoining pressure at the nanoscale is included in a modified form of Terzaghi's effective stress principle for unsaturated expansive clays recently developed by our group in order to numerically simulate the hydro-mechanical behavior of expansive clays during water uptake
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Étude et conception d’une plateforme microfluidique pour la détection de séquence ADN par spectroscopie d’impédance / Study and design of a microfluidic platform for DNA sequence detection by impedance spectroscopyBourjilat, Ayoub 17 November 2017 (has links)
L’objectif de cette thèse est la conception de biocapteurs capables de détecter la présence de séquences d’ADN sans utilisation de marqueurs chimiques ou de traitement préalable de l’échantillon. Le principe de mesure utilise la spectroscopie d’impédance pour la détection du changement provoqué par la présence de la séquence ADN sur le biocapteur. Notre étude s’appuie sur des simulations analytiques et numériques pour définir les dimensions des capteurs adaptés aux mesures en basse fréquence ainsi que le développement d’un modèle de circuit équivalent qui prend en considération les effets d'interfaces. La fabrication du capteur a été réalisée en plusieurs étapes. Dans un premier temps, la conception et la fabrication en salles blanches ont été optimisées pour des structures interdigitées avec différentes géométries et différents types de substrat (Verre, Si, SiO2). Après la validation du modèle, par des mesures sur des solutions de conductivité étalon et sur plusieurs concentrations d’ADN, l’analyse des résultats nous a conduits à proposer une nouvelle structure à électrodes concentriques mieux adaptée aux mesures d’impédance en basses fréquences pour des milieux liquides. Deux prototypes de taille micrométriques, l’un à électrode interdigitée et l’autre à électrode concentrique ont été développés pour une étude comparative / The objective of this thesis is the conception of a biosensor able to detect the presence of DNA sequences without any use of chemical markers or a prior treatment of the samples. The measurements are performed using impedance spectroscopy technique to detect the changes caused by the presence of DNA sequences on the biosensor. Our study is based on analytic and numeric simulations, which allows us to define the dimensions of the sensors adapted to low frequency measurements and to propose an equivalent circuit model taking into account the effects of the electrical double layer. The sensor was manufactured in several steps. Initially, clean room design and manufacturing were optimized for interdigitated structures with different geometries and substrate types (Glass, Si, SiO2). The data analysis of the measurement on standard conductivity and on several DNA concentrations using interdigitated electrode biosensor, allows us to propose a new design with concentric electrodes which is more adapted to low frequency impedance measurement according to a comparative study between interdigitated and concentric electrodes
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Desenvolvimento de material híbrido anódico para baterias de íons de Li baseado em carvão ativado e nanotubos de carbono decorados com prata / Development of hybrid anode material for Li ion batteries based on activated carbon and carbon nanotubes decorated with silver.Takahashi, Giuliana Hasegava 16 April 2015 (has links)
Neste trabalho, foi desenvolvido um material híbrido inédito carvão ativado/nanotubos de carbono/nanopartículas de prata para as aplicações em bateria de íons de lítio e capacitor eletroquímico de dupla camada. O compósito foi preparado por crescimento dos nanotubos de carbono diretamente sobre o carvão ativado via deposição química de vapor e depois nanopartículas de prata foram incorporadas no carvão ativado/nanotubos de carbono. A morfologia do compósito foi analisada por microscopia eletrônica de varredura. Investigação das propriedades de intercalação de lítio no carvão ativado (CA), carvão ativado/nanotubos de carbono (CA/NTC), carvão ativado/prata (CA/Ag) e carvão ativado/nanotubos de carbono/prata (CA/NTC/Ag) foi conduzida por voltametria cíclica e ciclos de carga/descarga, utilizando dois diferentes eletrólitos. Verificou-se que o ânodo de CA/NTC/Ag apresenta mais elevado valor de capacidade específica reversível que a grafita em eletrólito comercial, provavelmente devido à rede tridimensional com elevada condutividade eletrônica formada por nanotubos de carbono e nanopartículas de prata nos poros e nas rugosidades do substrato. Além disso, os nanotubos de carbono podem exibir elevada capacidade de armazenamento de lítio. Outra vantagem do CA/NTC/Ag é que a rede de nanotubos de carbono acomoda a expansão de volume das partículas de prata durante a ciclagem do eletrodo, mantendo-as bem adsorvidas na superfície do CA/NTC. Os resultados confirmaram a existência do sinergismo entre os componentes do CA/NTC/Ag, que promove características eletroquímicas superiores àquelas dos constituintes isolados. / In this work, an unpublished hybrid material activated carbon/carbon nanotubes/silver nanoparticles was developed for lithium ion battery and electrochemical double layer capacitor applications. The composite was prepared by growing carbon nanotubes directly on the activated carbon via chemical vapor deposition and after silver nanoparticles were incorporated on the activated carbon/carbon nanotubes. The composites morphology was analyzed by scanning electron microscopy. Investigation of lithium intercalation properties in activated carbon (AC), activated carbon/carbon nanotubes (AC/CNT), activated carbon/silver (AC/Ag) and activated carbon/carbon nanotubes/silver (AC/CNT/Ag) was carried out by cyclic voltammetry and charge/discharge cycles by making use of two different electrolytes. It was found that the AC/CNT/Ag anode presents higher reversible specific capacity value in comparison with graphite in commercial electrolyte, probably due to the three dimensional network with high electronic conductivity formed by carbon nanotubes and silver nanoparticles in the substrates pores and roughness. Furthermore, carbon nanotubes can exhibit high lithium storage capacity. Another advantage of the AC/CNT/Ag is that the network of carbon nanotubes accommodates volume expansion of the silver particles during electrode cycling, keeping them well adsorbed on the surface of the AC/CNT. The results confirmed the existence of synergism between the components of the AC/CNT/Ag, which promotes electrochemical characteristics that are higher than those of the individual constituents.
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Experimental Investigations of Wave Motion and Electric Resistance in Collisionfree PlasmasWendt, Martin January 2001 (has links)
No description available.
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