CHARGED POLYELECTROLYTE BRUSHES FOR VOLTAGE-CONTROLLED GATING OF NANOFLUIDIC CHANNEL: MOLECULAR DYNAMICS SIMULATION

Ouyang, Hui

19 May 2010

No description available.

Mechanical Engineering

Molecular Dynamics Simulation

Flow Regulating

Polyelectrolyte brushes

Nanofluidics

Nanovalve

Engineering Electromechanical Systems to Regulate Nanoscale Flows

Rangharajan, Kaushik Krishna

27 July 2018

No description available.

Mechanical Engineering

Nanoscience

Biomedical Engineering

Nanotechnology

Electromechanical Systems

Interfacial dynamics of ferrofluids in Hele-Shaw cells

Zongxin Yu (16618605)

20 July 2023

<p>Ferrofluids are remarkable materials composed of magnetic nanoparticles dispersed in a carrier liquid. These suspensions exhibit fluid-like behavior in the absence of a magnetic field, but when exposed to a magnetic field, they can respond and deform into a variety of patterns. This responsive behavior of ferrofluids makes them an excellent material for applications such as drug delivery for targeted therapies and soft robots. In this thesis, we will focus on the interfacial dynamics of ferrofluids in Hele-Shaw cells. The three major objectives of this thesis are: understanding the pattern evolution, unraveling the underlying nonlinear dynamics, and ultimately achieving passive control of ferrofluid interfaces. First, we introduce a novel static magnetic field setup, under which a confined circular ferrofluid droplet will deform and spin steadily like a `gear’, driven by interfacial traveling waves. This study combines sharp-interface numerical simulations with weakly nonlinear theory to explain the wave propagation. Then, to better understand these interfacial traveling waves, we derive a long-wave equation for a ferrofluid thin film subject to an angled magnetic field. Interestingly, the long-wave equation derived, which is a new type of generalized Kuramoto--Sivashinsky equation (KSE), exhibits nonlinear periodic waves as dissipative solitons and reveals fascinating issues about linearly unstable but nonlinearly stable structures, such as transitions between different nonlinear periodic wave states. Next, inspired by the low-dimensional property of the KSE, we simplify the original 2D nonlocal droplet problem using the center manifold method, reducing the shape evolution to an amplitude equation (a single local ODE). We show that the formation of the rotating `gear’ arises from a Hopf bifurcation, which further inspires our work on time-dependent control. By introducing a slowly time-varying magnetic field, we propose strategies to effectively control a ferrofluid droplet's evolution into a targeted shape at a targeted time. The final chapter of this thesis concerns our ongoing research into the interfacial dynamics under the influence of a fast time-varying and rotating magnetic field, which induces a nonsymmetric viscous stress tensor in the ferrofluid, requiring the balance of the angular momentum equation. As a consequence, wave propagation on a ferrofluid interface can be now triggered by magnetic torque. A new thin-film long-wave equation is consistently derived taking magnetic torque into account.</p>

Microfluidics and nanofluidics

Ferrohydrodynamics

Interfacial dynamics

Hele-Shaw cell

Nonlinear waves

Bifurcations

Electroosmotic Flow and DNA Electrophoretic Transport in Micro/Nano Channels

Chen, Lei

30 September 2009

No description available.

Mechanical Engineering

electroosmotic flow

electrokinetic transport

DNA sequencing

nanopore

nanonozzles

molecular transport

Poly(dimethylsiloxane) Based Micro- and Nanofluidic Device Fabrication for Electrophoresis Applications

Pussadee, Nirut

04 November 2010

No description available.

Biophysics

Materials Science

Polymers

PDMS

microfluidics

nanofluidics

nanochannels

sacrificial layer lithography

plasma etching

Non-Equilibrium Topographies: Surface Tension Driven Flows Reveal Polymer Properties at the Nanoscale

McGraw, Joshua D.

04 1900

<p>The most important results in this thesis are those concerned with the levelling of a stepped film’s height profile. Films are prepared such that their height profiles are well described by a Heaviside step function and to a good approximation, they are invariant in one dimension. The temporal dependence of the levelling gives rheological information about the molecules making up the stepped films. For the range of heights that is much larger that the typical size of molecules making up the film, we use classical hydrodynamics to model the flows in these stepped films. Having measured the temporal and geometric dependence of the energy dissipation in time, we find that the hydrodynamic models are in excellent agreement.</p> / Doctor of Philosophy (PhD)

polymer

thin films

experimental

nanofluidics

entanglement

condensed matter

Condensed Matter Physics

Fluid Dynamics

Condensed Matter Physics

Modelagem e caracterização de sistemas nanofluidos através de simulações moleculares em multiescala / Design and Characterization of Nanofluidic-Based Systems by Multiscale Molecular Simulations

Kirch, Alexsandro

10 August 2018

As propriedades físicas incomuns exibidas por fluidos confinados em meios porosos desempenham um papel importante em diversos processos químicos, geoquímicos e ambientais. Atualmente, muitos aspectos da estrutura e dinâmica dos fluidos espacialmente confinados ainda são pouco compreendidos. Nesse contexto, fenômenos interfaciais influenciam consideravelmente os processos que ocorrem em meios nanoporosos, podendo resultar em efeitos relevantes para o desenvolvimento dos dispositivos nanofluidicos. Esses sistemas multifásicos e com fenômenos multifísicos podem apresentar propriedades eletrônicos e dinâmicos envolvendo diferentes escalas de tamanho e tempo na interface sólido/fluido. Atualmente, uma única metodologia não é capaz de resolver toda a complexidade encontrada em tais sistemas pelo fato de cada qual estar restrita a uma escala ou demanda computacional específica. Além disso, as metodologias habitualmente aplicadas para investigar as fases bulk através da modelagem computacional, em geral, não são adequadas para acessar sistematicamente os efeitos de superfície que ocorrem na interface sólido/fluido. Os desafios impostos à modelagem molecular pelos sistemas nanofluídicos requerem iniciativas inovadoras (dentre as metodologias disponíveis) para acessar as propriedades de interface. Nessa tese, desenvolvemos e aplicamos novas abordagens computacionais em nível atômico a fim de modelar e caracterizar sistemas nanofluidicos. Nesse contexto, introduzimos um método multinível hierárquico top-down, que combina simulações de dinâmica molecular com cálculos ab initio de transporte eletrônico, para abordar fenômenos de multiescala. O potencial dessa implementação foi demonstrado em um estudo de caso envolvendo o fluxo de água e o transporte de íons através de um nanotubo de carbono tipo (6,6). Mostramos que o traço iônica pode representar uma mudança na condutância elétrica do nanocanal, e levar a uma medida indireta da corrente iônica. Também implementamos uma versão modificada da análise de rede de ligações de hidrogênio baseada em teoria de grafos, a fim de fazer o estudo das propriedades estruturais e dinâmicas em diferentes regiões do poro. Com essa abordagem, nós fomos capazes de explorar sistematicamente os efeitos de interface em fluidos espacialmente confinados. Combinando-se simulações de dinâmica molecular com a análise da rede de ligações de hidrogênio em camadas, nós pudemos avaliar a extensão dos efeitos de superfície nas propriedades dinâmicas e os detalhes da interface calcita/salmoura. Com a abordagem desenvolvida, conseguimos isolar os efeitos específicas dos íons da solução aquosa na rede de ligações de hidrogênio. Mostramos que a camada superficial exibe uma topologia de rede semelhante à observada em água pura, uma vez que a barreira eletrostática e física exibida por essa região, inibe a adsorção de íons na superfície da calcita. Fora dessa faixa, os íons influenciam consideravelmente a rede de ligações de hidrogênio: observamos a formação caminhos geodésicos mais extensos em relação àqueles observados em água pura. Esses ramos, que são formados por ligações de hidrogênio contíguas, podem conectar moléculas de baixa a alta dinâmica. Tal estrutura, pode explicar as propriedades mecânicas adesivas observadas em fluidos altamente confinados. Nossas principais contribuições decorrem na descrição da estrutura do solvente, dos íons da solução aquosa na interface calcita/fluido; e suas indicações físicas, e seu potencial significado nos processos de crescimento e dissolução de cristais. Nossas implementações fornecem contribuições interessantes para a compreensão atual dos processos que ocorrem em meios porosos. Especialmente, podendo contribuir para um desenvolvimento racional de novos dispositivos nanofluidicos. / The unusual physical properties exhibit by fluids within nanoscopic porous media play an important role in the plethora of chemical, geochemical and environmental processes. Currently, many aspects of the structure and dynamics of the spatially constrained fluids are still poorly understood. Additionally, the interfacial phenomena considerably influences the processes occurring in nanoporous media, which can have a major effect on nanofluidics devices. These multiphase systems and multi-physics phenomena occurs at solid/solution interfaces, with electronic and dynamic effects taking place across size and time scales. Currently, a single methodology is not capable to disentangle all the complexity find in such systems because it is restricted to a specific scale or computationally demand. In addition, the usual computational modeling methodologies applied to investigate bulk phases, they are, in general, not suitable to systematically access the surface effects occurring at solid/fluid interfaces. The challenges imposed by the nanofludics-based systems within the molecular modeling framework require innovative initiatives (among the available methodologies) to correctly access the interface properties. In this thesis, we develop and apply novel computational approaches to properly design and characterize nanofluidics-based systems at atomic level. In this context, we introduced an hierarchical top-down multilevel method by combining molecular dynamics simulations with first principles electronic transport calculations to address the multiscale phenomena problem. The potential of this implementation was demonstrated in a case study involving the water and ionic (Na, Li, and CL) flow through a (6,6) carbon nanotube. We showed that the ionic trace, observed on the electronic transmittance, it may handle an indirect measurement of the ionic current that is recorded as a sensing output. We implemented also a layered version of hydrogen bond network analysis based on graph theory. With this approach, we were able to properly explore interface effects arising on spatially confined fluids. By combining molecular dynamics simulations with the layered hydrogen bond network analysis, we evaluated the extension of surface effects on the fluids dynamics properties and the interaction details at calcite/brine interface. With the developed approach, we have been able to isolate the specific features of the aqueous solutions ions on the hydrogen bond network. We showed that the surface layer near the calcite/brine interface displays similar network topology as observed in pure water, since the electrostatic and physical barrier displayed by this layer inhibit the adsorption of ions on the calcite surface. Outside that region, these ions affect the hydrogen bond network. We observed a more extended geodesic paths with respect to that observed in pure water. Such hydrogen bond branches may connect low to high dynamics molecules across the pore and hence, it may explain the glue-like mechanical properties observed in confinement environment. Our main contributions in this work relies on describing the structure of solvent and electrolyte aqueous solution at calcite/fluid interface and their physical indications and potential significance on the crystal growth and dissolution processes. Our implementations provide interesting contributions to the current understanding of processes occurring in porous media. Specially, it may contribute on the rational design of novel nanofluidics devices.

abordagem multinível

hydrogen bond network analysis

modelagem molecular

molecular modeling

multilevel approach

nanofluídica

nanofluidics

Modelagem e caracterização de sistemas nanofluidos através de simulações moleculares em multiescala / Design and Characterization of Nanofluidic-Based Systems by Multiscale Molecular Simulations

Alexsandro Kirch

10 August 2018

As propriedades físicas incomuns exibidas por fluidos confinados em meios porosos desempenham um papel importante em diversos processos químicos, geoquímicos e ambientais. Atualmente, muitos aspectos da estrutura e dinâmica dos fluidos espacialmente confinados ainda são pouco compreendidos. Nesse contexto, fenômenos interfaciais influenciam consideravelmente os processos que ocorrem em meios nanoporosos, podendo resultar em efeitos relevantes para o desenvolvimento dos dispositivos nanofluidicos. Esses sistemas multifásicos e com fenômenos multifísicos podem apresentar propriedades eletrônicos e dinâmicos envolvendo diferentes escalas de tamanho e tempo na interface sólido/fluido. Atualmente, uma única metodologia não é capaz de resolver toda a complexidade encontrada em tais sistemas pelo fato de cada qual estar restrita a uma escala ou demanda computacional específica. Além disso, as metodologias habitualmente aplicadas para investigar as fases bulk através da modelagem computacional, em geral, não são adequadas para acessar sistematicamente os efeitos de superfície que ocorrem na interface sólido/fluido. Os desafios impostos à modelagem molecular pelos sistemas nanofluídicos requerem iniciativas inovadoras (dentre as metodologias disponíveis) para acessar as propriedades de interface. Nessa tese, desenvolvemos e aplicamos novas abordagens computacionais em nível atômico a fim de modelar e caracterizar sistemas nanofluidicos. Nesse contexto, introduzimos um método multinível hierárquico top-down, que combina simulações de dinâmica molecular com cálculos ab initio de transporte eletrônico, para abordar fenômenos de multiescala. O potencial dessa implementação foi demonstrado em um estudo de caso envolvendo o fluxo de água e o transporte de íons através de um nanotubo de carbono tipo (6,6). Mostramos que o traço iônica pode representar uma mudança na condutância elétrica do nanocanal, e levar a uma medida indireta da corrente iônica. Também implementamos uma versão modificada da análise de rede de ligações de hidrogênio baseada em teoria de grafos, a fim de fazer o estudo das propriedades estruturais e dinâmicas em diferentes regiões do poro. Com essa abordagem, nós fomos capazes de explorar sistematicamente os efeitos de interface em fluidos espacialmente confinados. Combinando-se simulações de dinâmica molecular com a análise da rede de ligações de hidrogênio em camadas, nós pudemos avaliar a extensão dos efeitos de superfície nas propriedades dinâmicas e os detalhes da interface calcita/salmoura. Com a abordagem desenvolvida, conseguimos isolar os efeitos específicas dos íons da solução aquosa na rede de ligações de hidrogênio. Mostramos que a camada superficial exibe uma topologia de rede semelhante à observada em água pura, uma vez que a barreira eletrostática e física exibida por essa região, inibe a adsorção de íons na superfície da calcita. Fora dessa faixa, os íons influenciam consideravelmente a rede de ligações de hidrogênio: observamos a formação caminhos geodésicos mais extensos em relação àqueles observados em água pura. Esses ramos, que são formados por ligações de hidrogênio contíguas, podem conectar moléculas de baixa a alta dinâmica. Tal estrutura, pode explicar as propriedades mecânicas adesivas observadas em fluidos altamente confinados. Nossas principais contribuições decorrem na descrição da estrutura do solvente, dos íons da solução aquosa na interface calcita/fluido; e suas indicações físicas, e seu potencial significado nos processos de crescimento e dissolução de cristais. Nossas implementações fornecem contribuições interessantes para a compreensão atual dos processos que ocorrem em meios porosos. Especialmente, podendo contribuir para um desenvolvimento racional de novos dispositivos nanofluidicos. / The unusual physical properties exhibit by fluids within nanoscopic porous media play an important role in the plethora of chemical, geochemical and environmental processes. Currently, many aspects of the structure and dynamics of the spatially constrained fluids are still poorly understood. Additionally, the interfacial phenomena considerably influences the processes occurring in nanoporous media, which can have a major effect on nanofluidics devices. These multiphase systems and multi-physics phenomena occurs at solid/solution interfaces, with electronic and dynamic effects taking place across size and time scales. Currently, a single methodology is not capable to disentangle all the complexity find in such systems because it is restricted to a specific scale or computationally demand. In addition, the usual computational modeling methodologies applied to investigate bulk phases, they are, in general, not suitable to systematically access the surface effects occurring at solid/fluid interfaces. The challenges imposed by the nanofludics-based systems within the molecular modeling framework require innovative initiatives (among the available methodologies) to correctly access the interface properties. In this thesis, we develop and apply novel computational approaches to properly design and characterize nanofluidics-based systems at atomic level. In this context, we introduced an hierarchical top-down multilevel method by combining molecular dynamics simulations with first principles electronic transport calculations to address the multiscale phenomena problem. The potential of this implementation was demonstrated in a case study involving the water and ionic (Na, Li, and CL) flow through a (6,6) carbon nanotube. We showed that the ionic trace, observed on the electronic transmittance, it may handle an indirect measurement of the ionic current that is recorded as a sensing output. We implemented also a layered version of hydrogen bond network analysis based on graph theory. With this approach, we were able to properly explore interface effects arising on spatially confined fluids. By combining molecular dynamics simulations with the layered hydrogen bond network analysis, we evaluated the extension of surface effects on the fluids dynamics properties and the interaction details at calcite/brine interface. With the developed approach, we have been able to isolate the specific features of the aqueous solutions ions on the hydrogen bond network. We showed that the surface layer near the calcite/brine interface displays similar network topology as observed in pure water, since the electrostatic and physical barrier displayed by this layer inhibit the adsorption of ions on the calcite surface. Outside that region, these ions affect the hydrogen bond network. We observed a more extended geodesic paths with respect to that observed in pure water. Such hydrogen bond branches may connect low to high dynamics molecules across the pore and hence, it may explain the glue-like mechanical properties observed in confinement environment. Our main contributions in this work relies on describing the structure of solvent and electrolyte aqueous solution at calcite/fluid interface and their physical indications and potential significance on the crystal growth and dissolution processes. Our implementations provide interesting contributions to the current understanding of processes occurring in porous media. Specially, it may contribute on the rational design of novel nanofluidics devices.

abordagem multinível

modelagem molecular

nanofluídica

hydrogen bond network analysis

molecular modeling

multilevel approach

nanofluidics

Écoulements liquide-gaz, évaporation, cristallisation dans les milieux micro et nanoporeux : études à partir de systèmes modèles micro et nanofluidiques / Liquid-gas flows, evaporation, crystallization in micro and nanoporous media : studies based on micro and nanofluidic devices

Naillon, Antoine

09 December 2016

Les écoulements en milieux poreux sont omniprésents tant dans la nature que dans l'industrie. Les travaux menés dans cette thèse ont pour objectif d’étudier ces écoulements en présence de liquide et de gaz. Cela correspond aux situations d'imbibition (ou invasion capillaire), de drainage (ou déplacement d'un fluide mouillant par la mise en pression d'un fluide non mouillant), et d'évaporation (ou de séchage). L'étude se base sur l'utilisation de systèmes modèles artificiels. Une première partie de ce travail se concentre sur les écoulements liquide-gaz dans les milieux dont la taille des pores est inférieure à 100 nm. Ces milieux sont dits nanoporeux. A cette échelle, différents phénomènes sont susceptibles de modifier les écoulements liquide-gaz par rapport à ce qui est observé à l’échelle micrométrique : accrochage de la ligne de contact, pression fortement négative en phase liquide ou cavitation par exemple. Des expériences sont donc nécessaires pour mieux caractériser ces écoulements. En parallèle, les récents progrès en nanofabrication permettent d’obtenir des systèmes dont la profondeur peut descendre jusqu’à quelques nanomètres. Cette approche, désormais classique à plus grande échelle, nous fournit un outil innovant pour étudier les écoulements dans des milieux nanoporeux modèles, en deux dimensions. Un atout évident de ce type de modèles est qu'ils permettent une visualisation directe des deux phases, liquide et gaz. Des dispositifs nanofluidiques en silicium-verre et à profondeur constante ont été réalisés dans la gamme 20-500 nm. Un nouveau procédé de nanofabrication basé sur une lithographie laser à niveau de gris a été développé afin d’obtenir des dispositifs à profondeurs variables en une seule étape. Les expériences d'imbibition et un modèle théorique ont mis en avant que la pressurisation du gaz accélère son transport dans le liquide. Ensuite, des expériences de drainage ont été réalisées dans des dispositifs nanofluidiques avec des pressions de l’ordre de 20 bars. Des simulations sur réseau de pores utilisant l’algorithme de percolation d'invasion ont montré que les motifs d'invasion expérimentaux correspondaient à ce qui était attendu à l’échelle micrométrique pour des écoulements à faible nombre capillaire. Enfin, l'évaporation en nanocanaux a révélé des cinétiques intéressantes d'apparition et de croissance de bulles dans le liquide. Une ouverture est faite sur l'intérêt de poursuivre ces études dans des systèmes déformables. La deuxième partie de cette thèse s'est focalisée sur la cristallisation du chlorure de sodium à l'échelle d’un pore micrométrique. Dans le cas particulier du séchage d'une solution de sel, l'évaporation amène à la cristallisation des espèces dissoutes. Ce phénomène est largement impliqué dans la problématique de la conservation des oeuvres d'arts ou de la détérioration précoce des édifices. Les mécanismes qui conduisent à la génération de contraintes par un cristal sur une paroi, appelée pression de cristallisation, ne sont pas encore admis tant à l’échelle macro que microscopique. Des déformations induites par la cristallisation du sel ont été observées dans des dispositifs microfluidiques verre-polymère (PDMS). La vitesse de croissance d’un cristal a été mesurée à haute cadence d'acquisition, aboutissant à une nouvelle valeur de la constante de cinétique de réaction, supérieure d'un à deux ordres de grandeur aux données de la littérature. Un modèle numérique prédit l'évolution du champ de concentration en sel dissous lors de la croissance du cristal. Complété par une analyse théorique qui a mis en avant un nombre de Damkhöler prenant en compte les propriétés de transport et la taille du pore, il a permis de construire un diagramme de phase qui traduit les conditions favorables à la génération de contraintes par un cristal sur une paroi. Enfin, un mécanisme de génération de contraintes négatives entraînant la fermeture du pore a été observé. / Flows in porous media are ubiquitous in nature and industry. The aim of this thesis work is to study these flows in presence of liquid and gas, relying on the use of artificial model systems. They correspond to imbibition (or capillary invasion), drainage (or the displacement of a wetting fluid by a non-wetting fluid), and evaporation (or drying). A first part of this work focuses on the liquid-gas flows in porous media whose pore size is lower than 100 nm. They are called nanoporous media. At this scale, several phenomenamight modify the liquid-gas flows in comparison with what is known at the micrometer scale: e.g. contact line pinning, high negative pressure in liquid or cavitation. Thus, experiments are needed to better characterize these flows. In parallel, recent progresses in nanofabrication allow fabricating devices whose depth drop down to few nanometers. This approach provide an innovative tool to study the flows in nanoporous model systems in two dimensions, as it has been already performed at larger scale. A clear advantage to this system is that it allows direct observation of different phases. Silicon-glass nanofluidic devices were fabricated with constant depth in the 20-500 nm range. A new fabrication process was developed to obtain nanochannel with non-uniform depth in one step. It is based on grayscale laser lithography. Imbibition experiments and a numerical model showed that the gas pressurization increased the gas transfer throw the liquid. Drainage experiments were performed in devices with pressure as high as 20 bars. Pore networks modeling with invasion percolation algorithmshowed that the experimental invasion patterns correspond to those expected at micrometer scale for low Capillary number. Evaporation in nanochannels revealed interesting kinetics of bubbles appearance and growth. A prospective study is shown at the end to argue the importance of pursuing these studies in deformable media. The second part of this work concentrates on the sodium chloride crystallization at the scale of a micrometer pore. In the specific case of the drying of a salt solution, evaporation leads to the crystallization of the dissolved species. This phenomenon is involved in the issue of art conservation or building salt weathering. The mechanisms which lead to a stress on wall induced by a crystal are not generally admitted both at macro and microscale. Deformations induced by crystal growth were observed in glass-polymer (PDMS) microfluidic devices. The crystal growth kinetics was measured at high acquisition rate and allowed giving a new value of the parameter of kinetics of crystal growth by reaction, one to two orders of magnitude higher than the ones used in literature. A numerical model was developed to predict the evolution of dissolved salt concentration during crystal growth. It allowed designing a phase diagram which gives the condition to favors the stress generation by a crystal on a wall. A theoretical analysis defined a Damkhöler number, taking into account transport properties and pore size. At last, a stress generation mechanism was observed, leading to the pore closure.

Nanofluidique

Ecoulements liquide-gaz

Imbibition

Drainage

Evaporation

Cristallisation

Milieu nanoporeux

Nanofluidics

Liquid-gas flows

Imbibition

Drainage

Evaporation

Crystallization

Nanoporous media

Development and Implementation of Acoustic Feedback Control for Scanning Probe Microscopy

Fernandez Rodriguez, Rodolfo

01 January 2012

A remote-sensing acoustic method for implementing position control feedback in Scanning Probe Microscopy (SPM) is presented. The capabilities of this feedback control using the new Whispering Gallery Acoustic Sensing (WGAS) method is demonstrated in a Shear-force Scanning Probe Microscope that uses a sharp probe attached to a piezoelectric Quartz Tuning Fork (QTF) firmly mounted on the microscope's frame. As the QTF is electrically driven its mechanical response reaches the SPM frame which then acts as a resonant cavity producing acoustic modes measured with an acoustic sensor strategically placed on the SPM head. The novelty of the WGAS resides in using an SPM frame with a perimeter closely matching the intervening acoustic wavelength to act as a resonant cavity. The whispering gallery cavity constitutes an acoustic amplifier for the mechanical motion of the QTF probe. The observed monotonic behavior of the whispering gallery acoustic signal as a function of the probe sample distance is exploited here for tip-sample distance control with nanometer sensitivity, thus allowing topographic characterization as the probe is scanned across the sample's surface. This thesis includes a description of a Labview based programming for the Field Programmable Gate Array (FPGA) card used in the automated control of the WGAS feedback microscope, a solution for improving the effective resolution of the Digital to Analog Converter (DAC) and initial results towards theoretically modeling the WGAS working principle.

Scanning probe microscopy

Acoustic imaging

Feedback control systems

Nanofluidics

Nanotechnology

Nanotribology

Atomic, Molecular and Optical Physics

Diagnosis

Medical Biophysics