Global ETD Search

131	Controlling Colloidal Stability using Highly Charged Nanoparticles Herman, David J. 27 February 2015 (has links) This dissertation focused on the potential use of highly charged nanoparticles to stabilize dispersions of weakly charged microparticles. The experimental components of the project centered on a model colloidal system containing silica microparticles at the isoelectric point where the suspensions are unstable and prone to flocculation. The stability of the silica suspensions was studied in the presence of highly charged nanoparticles. Initial experiments used polystyrene latex with either sulfate or amidine surface groups. Effective zeta potentials were measured with nanoparticle concentrations ranging from 0.001% to 0.5% vol. Adsorption levels were determined through direct SEM imaging of the silica microparticles, showing that the nanoparticles directly adsorbed to the microparticles (amidine more than sulfate), producing relatively large effective zeta potentials. However, stability experiments showed that the latex nanoparticles did not stabilize the silica but merely provided a reduction in overall flocculation rate. It was concluded that the zeta potential was an insufficient predictor of stability as there was still sufficient patchiness on the surface to allow for the silica surfaces to aggregate. Experiments using zirconia and alumina nanoparticles did achieve effective stabilization; both types stabilized the silica suspensions for longer than the observation period of approximately 15 hours. Stability was observed at concentrations of 10^-4% to 1.0% (zirconia) and 10^-2% vol. (alumina). These particles adsorbed directly to the microparticles (confirmed via SEM) and produced increasing effective zeta potentials with increasing nanoparticle concentrations. The adsorption resulted in significant electrostatic repulsion that was determined to be effectively irreversible using colloidal probe AFM. The improved stabilizing ability was attributed to the increased van der Waals attraction between the oxide nanoparticles (compared to polystyrene). Finally, an unexpected result of the CP-AFM force measurements showed that the repulsive forces between a nanoparticle-coated particle and plate lacked the normal dependence on the radius of the probe as predicted by the Derjaguin approximation. The forces observed in nanoparticle suspensions were virtually identical for 5 µm and 30 µm probes. Based on calculations of the shear rate in the gap, it was theorized that this phenomenon may have resulted from the shearing of adsorbed particles from the surfaces, which leads to similar interaction geometries for the two probe sizes. / Ph. D. Colloidal stability nanoparticle adsorption electrostatic forces van der Waals interactions atomic force microscopy
132	An investigation of the stickinness mechanism and the role of nodes in cribellar spider capture thread Campbell-Hawthorn, Anya 17 June 2003 (has links) Sticky prey capture threads are produced by many members of the spider Infraorder Araneomorphae. Cribellar threads are plesiomorphic for this clade, and adhesive threads are apomorphic. The surface of cribellar thread is formed of thousands of fine fibrils. Basal araneomorphs produce cylindrical fibrils, whereas more derived members produce fibrils with nodes. Cribellar fibrils snag and hold rough surfaces, but other forces are required to explain their adherence to smooth surfaces. Threads of Hypochilus pococki (Hypochilidae) that are formed of non-noded fibrils hold to a smooth acetate surface with the same force under low and high humidities. In contrast, threads of Hyptiotes cavatus and Uloborus glomosus (Uloboridae) that are formed of noded fibrils hold with greater forces to the same surface at intermediate and high humidities. Threads spun by eight species representing seven genera and four families with noded fibrils absorb water, while that of two families, represented by one species each with smooth fibrils, repel water, indicating increase hygroscopisity associated with the presence of nodes. Additionally, equations describing van der Waals and hygroscopic forces can predict the observed stickiness of these threads. This model supports the hypothesis that van der Waals forces allow non-noded cribellar fibrils to adhere to smooth surfaces, whereas noded fibrils employ van der Waals forces at low humidities and add hygroscopic forces at higher humidities. Thus, there appear to have been two major events in the evolution of spider prey capture thread: the addition of hydrophilic nodes to the fibrils of cribellar threads and the replacement of cribellar fibrils by glycoprotein glue. / Master of Science evolution of capture thread hygriscopic adhesion van der Waals spider silk cribellar thread
133	Surprises in theoretical Casimir physics : quantum forces in inhomogeneous media Simpson, William M. R. January 2014 (has links) This thesis considers the problem of determining Casimir-Lifshitz forces in inhomogeneous media. The ground-state energy of the electromagnetic field in a piston-geometry is discussed. When the cavity is empty, the Casimir pressure on the piston is finite and independent of the small-scale physics of the media that compose the mirrors. However, it is demonstrated that, when the cavity is filled with an inhomogeneous dielectric medium, the Casimir energy is cut-off dependent. The local behavior of the stress tensor commonly used in calculations of Casimir forces is also determined. It is shown that the usual expression for the stress tensor is not finite anywhere within such a medium, whatever the temporal dispersion or index profile, and that this divergence is unlikely to be removed by modifying the regularisation. These findings suggest that the value of the Casimir pressure may be inextricably dependent on the detailed behavior of the mirror and the medium at large wave vectors. This thesis also examines two exceptions to this rule: first, the case of an idealised metamaterial is considered which, when introduced into a cavity, reduces the magnitude of the Casimir force. It is shown that, although the medium is inhomogeneous, it does not contribute additional scattering events but simply modifies the effective length of the cavity, so the predicted force is finite and can be stated exactly. Secondly, a geometric argument is presented for determining a Casimir stress in a spherical mirror filled with the inhomogeneous medium of Maxwell's fish-eye. This solution questions the idea that the Casimir force of a spherical mirror is repulsive, but prompts additional questions concerning regularisation and the role of non-local effects in determining Casimir forces. 530.14
134	Mesure de l’interaction de van der Waals entre deux atomes de Rydberg / Measurement of the van der Waals interaction between two Rydberg atoms Beguin, Lucas 13 December 2013 (has links) Les atomes neutres sont des candidats prometteurs pour la réalisation et l’étude d’états intriqués à quelques dizaines de particules. Pour générer de tels états, une approche consiste à utiliser le mécanisme de blocage dipolaire résultant des fortes interactions dipôle-dipôle entre atomes de Rydberg.Suivant cette approche, cette thèse présente la conception et la caractérisation d’un dispositif expérimental permettant de manipuler des atomes de 87Rb individuels piégés dans des pinces op- tiques microscopiques, et à les exciter vers des états de Rydberg. Un environnement électrostatique stable et des électrodes de contrôle permettent une manipulation fine de ces états. Avec deux pinces optiques séparées de quelques microns, nous démontrons le blocage de Rydberg entre deux atomes, et nous observons leur excitation collective.Enfin, en opérant en régime de blocage partiel, nous développons une méthode permettant de mesurer l’interaction de van der Waals ∆E = C6 /R6 entre deux atomes séparés par une distance R contrôlée. Les coefficients C6 obtenus pour différents états de Rydberg sont en bon accord avec des calculs théoriques ab initio, et nous observons l’augmentation spectaculaire de l’interaction en fonction du nombre quantique principal n de l’état de Rydberg. / Neutral atoms are promising candidates for the realization of entangled states involving up to a few tens of particles. To generate such states, one approach consists in using the dipole blockade mechanism, which results from the strong dipole-dipole interactions between Rydberg atoms.Following this approach, this thesis describes the design and the characterization of an experimental apparatus allowing to manipulate single 87Rb atoms trapped in microscopic optical tweezers, and to excite them towards Rydberg states. A stable electrostatic environment and controlled electrodes enable the fine manipulation of these states. Using two optical tweezers separated by a few microns, we demonstrate the Rydberg blockade between two single atoms, and we observe their collective excitation.Finally, by operating in the partial blockade regime, we develop a method allowing to measure the van der Waals interaction ∆E = C6 /R6 between two atoms separated by a controlled distance R. The C6 coefficients obtained for various Rydberg states agree well with ab initio theoretical calculations, and we observe the dramatic increase of the interaction with the principal quantum number n of the Rydberg state. Simulation quantique Atome unique Pinces optiques Atomesde Rydberg Interaction dipôle-dipôle Interaction de van der Waals Blocage de Rydberg Intrication Quantum simulation Single atoms Optical tweezers Rydberg atoms Dipole-dipole interaction Van der Waals interaction Rydberg block- ade Entanglement 530.12
135	Development of tools for quantum engineering using individual atoms : optical nanofibers and controlled Rydberg interactions / Vers l’ingénierie quantique avec des atomes individuels : fabrication de fibres optiques nanométriques et contrôle des interactions entre atomes de Rydberg Ravets, Sylvain 18 December 2014 (has links) La plupart des objets quantiques individuels développés jusqu’à aujourd’hui ne permettent pas de satisfaire toutes les conditions nécessaires pour la construction d’un simulateur quantique. Une possibilité pour obtenir un système quantique robuste est de combiner plusieurs de ces approches. Dans cette thèse, nous décrivons les résultats obtenus sur deux systèmes expérimentaux développés dans ce but.La première partie de cette thèse décrit un système hybride d’atomes neutres couplés à des qubits supraconducteurs, en construction à l’Université du Maryland. La solution envisagée pour placer un ensemble d’atomes froids à proximité de la surface supraconductrice est de piéger les atomes dans le champ évanescent se propageant autour d’une fibre optique nanométrique. Nous avons développé un dispositif permettant la production de fibres optiques nanométriques de transmission optique supérieure à 99.95% dans le mode fondamental. Nous avons également optimisé la transmission de quelques modes d’ordres supérieurs, ce qui pourra s’avérer utile pour le piégeage d’atomes.La seconde partie de cette thèse décrit un système développé à l’Institut d’Optique et comprenant des atomes neutres piégés dans des matrices de pinces optiques. Dans ce cas, nous excitons les atomes dans des états de Rydberg afin de bénéficier de fortes interactions interatomiques. Nous avons caractérisé les interactions de van der Waals et les interactions résonantes entre deux atomes individuels, et démontré le caractère cohérent de l’interaction dipolaire. Nous avons enfin simulé la dynamique d’une chaine élémentaire de spins dans une matrice de trois atomes / Most platforms that are being developed to build quantum simulators do not satisfy simultaneously all the requirements necessary to implement useful quantum tasks. Robust systems can be constructed by combining the strengths of multiple approaches while hopefully compensating for their weaknesses. This thesis reports on the progress made on two different setups that are being developed toward this goal.The first part of this thesis focuses on a hybrid system of neutral atoms coupled to superconducting qubits that is under construction at the University of Maryland. Sub-wavelength diameter optical fibers allow confining an ensemble of cold atoms in the evanescent field surrounding the fiber, which makes them ideal for placing atoms near a superconducting surface. We have developed a tapered fiber fabrication apparatus, and measured an optical transmission in excess of 99.95% for the fundamental mode. We have also optimized tapered fibers that can support higher-order optical modes with high transmission, which may be useful for various optical potential geometries.The second part of this thesis focuses on a system of neutral atoms trapped in arrays of optical tweezers that has been developed at the Institut d’Optique. Placing the atoms in highly excited Rydberg states allows us to obtain strong interatomic interactions. Using two individual atoms, we have characterized the pairwise interactions in the van der Waals and resonant dipole-dipole interaction regimes, providing a direct observation of the coherent nature of the interaction. In a three-atom system, we have finally simulated the dynamics of an elementary spin chain Fibres optiques Transferts d’énergie résonants Physique quantique Atomes de Rydberg Forces de van der Waals Simulation quantique Optical fibers Resonant energy transfers Quantum physics Rydberg atoms Van der Waals forces Quantum simulators 530.12 539.754 621.384 11
136	Sterically flexible molecules in the gas phase Erlekam, Undine 24 October 2008 (has links) Für die makroskopischen Eigenschaften und Funktionen biologisch relevanter Materie spielen schwache, intra- und intermolekulare Wechselwirkungen dispersiver und elektrostatischer Natur auf molekularem Niveau eine große Rolle. Um diese schwachen Wechselwirkungen zu untersuchen, können Modellsysteme, isoliert in der Gasphase, herangezogen werden. Benzoldimer, ein schwach gebundener Van der Waals Komplex, kann beispielsweise als Modellsystem für dispersive Wechselwirkungen dienen. In der vorliegenden Arbeit werden die strukturellen Eigenschaften und die (interne) Dynamik des Benzoldimers mit Hilfe spektroskopischer Methoden in den Energiebereichen der Rotationen, Vibrationen und elektronischen Übergänge untersucht und im Kontext der Symmetrie diskutiert. Die in dieser Arbeit vorgestellten Experimente tragen zu einem tieferen Verständnis des Benzoldimers bei, jedoch zeigt das Experiment zur internen Dynamik auch, dass eine ausreichende theoretische Beschreibung des Benzoldimers nach wie vor eine Herausforderung darstellt. Schwingungsübergänge hochsymmetrischer Moleküle sind oft optisch inaktiv, können jedoch mit der hier vorgestellten Methode der Symmetrieerniedrigung durch Komplexierung zugänglich gemacht werden, wie am Beispiel des Benzols demonstriert wird. Außerdem wird ein Mechanismus vorgstellt, der kollisionsinduzierte Konformationsänderungen in einem Molekularstrahl beschreibt. Dieses Modell kann generell für Molekularstrahlexperimente an flexiblen Molekülen hilfreich sein, einerseits um die beobachtete Konformationsverteilung zu verstehen, andererseits um die experimentellen Parameter gezielt zu verändern und somit Konformerpopulationen zu manipulieren. Die in dieser Dissertation vorgestellten spektroskopischen Experimente liefern einerseits molekülspezifische Informationen und ermöglichen andererseits, Modelle, die von allgemeiner Bedeutung sind, zu entwickeln. / The macroscopically observable properties and functionalities of biological matter are often determined by weak intra- and intermolecular interactions on the microscopic level. Such weak interactions are for example hydrogen bonding and van der Waals interactions and can be investigated best on isolated model systems in the gas phase. The benzene dimer, for example, is a prototype system to investgate dispersive interactions. The spectroscopic experiments, covering the energy ranges of rotations, vibrations and electronic transitions, presented in this thesis, contribute to a deeper understanding of the benzene dimer. However, from the experiments investigating the internal dynamics it becomes clear that an appropriate theoretical description of the benzene dimer is still a challenge. Vibrational transitions of highly symmetric molecules, as for example of the benzene, are often optically inactive. Here, a method is presented, which exploits symmetry reduction upon complexation and thus allows one to access such modes. Furthermore, a model is proposed describing collision induced conformational interconversion in a molecular beam. This model can be helpful for molecular beam experiments of flexible molecules to understand the observed relative conformational population and to adapt the experimental conditions allowing for the manipulation of the relative conformer abundances. In this thesis, results are presented that allow one on the one hand to deduce molecular specific information and that on the other hand also give a broader insight into phenomena of general importance. Katalyse Spektroskopie Benzoldimer Molekularstrahl Van der Waals Wechselwirkung Wasserstoffbrückenbindung Symmetrie Permutations-Inversions Gruppentheorie Phenylalanin catalysis spectroscopy benzene dimer molecular beam van der Waals interaction hydrogen bonding symmetry permutation-inversion group theory phenylalanine 540 Chemie 30 Chemie ddc:540
137	Casimir-Polder interaction in second quantization Schiefele, Jürgen January 2011 (has links) The Casimir-Polder interaction between a single neutral atom and a nearby surface, arising from the (quantum and thermal) fluctuations of the electromagnetic field, is a cornerstone of cavity quantum electrodynamics (cQED), and theoretically well established. Recently, Bose-Einstein condensates (BECs) of ultracold atoms have been used to test the predictions of cQED. The purpose of the present thesis is to upgrade single-atom cQED with the many-body theory needed to describe trapped atomic BECs. Tools and methods are developed in a second-quantized picture that treats atom and photon fields on the same footing. We formulate a diagrammatic expansion using correlation functions for both the electromagnetic field and the atomic system. The formalism is applied to investigate, for BECs trapped near surfaces, dispersion interactions of the van der Waals-Casimir-Polder type, and the Bosonic stimulation in spontaneous decay of excited atomic states. We also discuss a phononic Casimir effect, which arises from the quantum fluctuations in an interacting BEC. / Die durch (quantenmechanische und thermische) Fluktuationen des elektromagnetischen Feldes hervorgerufene Casimir-Polder-Wechselwirkung zwischen einem elektrisch neutralen Atom und einer benachbarten Oberfläche stellt einen theoretisch gut untersuchten Aspekt der Resonator-Quantenelektrodynamik (cavity quantum electrodynamics, cQED) dar. Seit kurzem werden atomare Bose-Einstein-Kondensate (BECs) verwendet, um die theoretischen Vorhersagen der cQED zu überprüfen. Das Ziel der vorliegenden Arbeit ist es, die bestehende cQED Theorie für einzelne Atome mit den Techniken der Vielteilchenphysik zur Beschreibung von BECs zu verbinden. Es werden Werkzeuge und Methoden entwickelt, um sowohl Photon- als auch Atom-Felder gleichwertig in zweiter Quantisierung zu beschreiben. Wir formulieren eine diagrammatische Störungstheorie, die Korrelationsfunktionen des elektromagnetischen Feldes und des Atomsystems benutzt. Der Formalismus wird anschließend verwendet, um für in Fallen nahe einer Oberfläche gehaltene BECs Atom-Oberflächen-Wechselwirkungen vom Casimir-Polder-Typ und die bosonische Stimulation des spontanen Zerfalls angeregter Atome zu untersuchen. Außerdem untersuchen wir einen phononischen Casimir-Effekt, der durch die quantenmechanischen Fluktuationen in einem wechselwirkenden BEC entsteht. Hohlraum-Quantenelektrodynamik Bose-Einstein-Kondensation Casimir-Polder-Interaktion Vakuumschwankungen van der Waals-Kräfte cavity quantum electrodynamics Bose-Einstein condensation Casimir-Polder interaction vacuum fluctuations van der Waals forces Physics
138	Diffraction of Metastable Rare-Gas Atoms from Nanostructured Transmission Gratings / Beugung metastabiler Edelgasatome an nanostrukturierten Transmissionsgittern Walter, Christian 27 November 2002 (has links) No description available. 530 Physik Mathematics and Computer Science metastabile Edelgasatome Atombeugung Transmissionsgitter Siliziumnitrid van der Waals metastable rare-gas atoms atom diffraction transmission grating silicon nitride van der Waals dispersion force 33.30 RP
139	An Extension to Endoreversible Thermodynamics for Multi-Extensity Fluxes and Chemical Reaction Processes Wagner, Katharina 27 June 2014 (has links) (PDF) In this thesis extensions to the formalism of endoreversible thermodynamics for multi-extensity fluxes and chemical reactions are introduced. These extensions make it possible to model a great variety of systems which could not be investigated with standard endoreversible thermodynamics. Multi-extensity fluxes are important when studying processes with matter fluxes or processes in which volume and entropy are exchanged between subsystems. For including reversible as well as irreversible chemical reaction processes a new type of subsystems is introduced - the so called reactor. It is similar to endoreversible engines, because the fluxes connected to it are balanced. The difference appears in the balance equations for particle numbers, which contain production or destruction terms, and in the possible entropy production in the reactor. Both extensions are then applied to an endoreversible fuel cell model. The chemical reactions in the anode and cathode of the fuel cell are included with the newly introduced subsystem -- the reactor. For the transport of the reactants and products as well as the proton transport through the electrolyte membrane, the multi-extensity fluxes are used. This fuel cell model is then used to calculate power output, efficiency and cell voltage of a fuel cell with irreversibilities in the proton and electron transport. It directly connects the pressure and temperature dependencies of the cell voltage with the dissipation due to membrane resistance. Additionally, beside the listed performance measures it is possible to quantify and localize the entropy production and dissipated heat with only this one model. / In dieser Arbeit erweitere ich den Formalismus der endoreversiblen Thermodynamik, um Flüsse mit mehr als einer extensiven Größe sowie chemische Reaktionsprozesse modellieren zu können. Mit Hilfe dieser Erweiterungen eröffnen sich zahlreiche neue Anwendungsmöglichkeiten für endoreversible Modelle. Flüsse mit mehreren extensiven Größen sind für die Betrachtung von Masseströmen ebenso nötig wie für Prozesse, bei denen sowohl Volumen als auch Entropie zwischen zwei Teilsystem ausgetauscht werden. Für sowohl reversibel wie auch irreversibel geführte chemische Reaktionsprozesse wird ein neues Teilsystem - der "Reaktor" - vorgestellt, welches sich ähnlich wie endoreversible Maschinen durch Bilanzgleichungen auszeichnet. Der Unterschied zu den Maschinen besteht in den Produktions- bzw. Vernichtungstermen in den Teilchenzahlbilanzen sowie der möglichen Entropieproduktion innerhalb des Reaktors. Beide Erweiterungen finden dann in einem endoreversiblen Modell einer Brennstoffzelle Anwendung. Dabei werden Flüsse mehrerer gekoppelter Extensitäten für den Zustrom von Wasserstoff und Sauerstoff sowie für den Protonentransport durch die Elektrolytmembran benötigt. Chemische Reaktionen treten in der Anode und Kathode der Brennstoffzelle auf. Diese werden mit dem neu eingeführten Teilsystem, dem Reaktor, eingebunden. Mit Hilfe des Modells werden dann Wirkungsgrad, Zellspannung und Leistung einer Brennstoffzelle unter Berücksichtigung der Partialdrücke der Substanzen, der Temperatur sowie der Dissipation beim Protonentransport berechnet. Dabei zeigt sich, dass experimentelle Daten für die Zellspannung sowohl qualitativ als auch näherungsweise quantitativ durch das Modell abgebildet werden können. Der Vorteil des endoreversiblen Modells liegt dabei in der Möglichkeit, mit nur einem Modell neben den genannten Kenngrößen auch die abgegebene Wärme sowie die Entropieproduktion zu quantifizieren und den einzelnen Teilprozessen zuzuordnen. Endoreversible Thermodynamik Nichtgleichgewichtsthermodynamik Ideales Gas van der Waals Gas Brennstoffzelle Modellierung Kreisprozesse Chemische Reaktionen Wirkungsgrad Endoreversible Thermodynamics non-equilibrium thermodynamics ideal gas van der Waals gas fuel cell modeling cyclic process chemical reaction efficiency ddc:536 Thermodynamik Nichtgleichgewicht Wirkungsgrad Brennstoffzelle
140	Coalescence de gouttes dans l'air : du millimètre au nanomètre / Coalescence of drops in air : from millimeter to nanometer Incerti, Véronique 14 December 2017 (has links) La coalescence intervient dans de nombreuses situations physiques, naturelles ou industrielles, de la microphysique des nuages à la stabilité des émulsions ou l’assèchement des pétroles. Dans toutes ces situations, il est crucial de comprendre les mécanismes physiques en jeu, de manière pouvoir influencer la coalescence, la favoriser ou au contraire l’inhiber, selon les besoins. Dans cette thèse, nous étudions la coalescence dans l’air entre deux gouttes attachées et décomposons le processus global en quatre étapes : l’approche avec drainage du film d’air entre les gouttes, le perçage des interfaces, l’ouverture du pont résultant de ce perçage, les oscillations amorties conduisant à l’équilibre de la goutte résultante. Les théories décrivant les étapes 1, 2 et 4 font intervenir des modèles hydrodynamiques continus, se plaçant à une échelle macroscopique. Cependant, à l’articulation entre les deux premières étapes, intervient le perçage des interfaces, processus gouverné par des forces dont la portée correspond à une échelle de quelques dizaines de nanomètres. Une des difficultés les plus importantes dans l’étude de la coalescence est celle de l’intégration des processus ayant lieu à un niveau moléculaire, dans une théorie du continuum dont l’échelle caractéristique est bien supérieure. L’objectif est de faire le lien entre les différentes échelles : y a-t-il des interactions entre les processus se produisant à ces différentes échelles ? Pour répondre à cette question, nous développons trois axes de travail, engageant chacun une échelle caractéristique. L’un est l’étude, au niveau macroscopique du micromètre, de l’ouverture du pont liquide. Grâce à une caméra rapide, plusieurs régimes d’écoulement sont mis en évidence. Les modèles théoriques existants concernent essentiellement le régime visqueux, et aucun modèle complet ne décrit le régime purement inertiel. Nous explorons expérimentalement ce régime et décrivons la forme et la longueur du pont, à l’aide d’ondes capillaires. Nous mettons en évidence l’existence de deux lignes de très forte courbure, que nous appelons singularités, qui naissent sur le lieu de perçage des interfaces et se propagent presque sans déformation de part et d’autre. Ces singularités, conditionnées par la tension superficielle, moteur de la coalescence, façonnent la forme du pont liquide et donc l’écoulement dans ce dernier. Nous proposons un modèle simple d’écoulement inertiel, basé sur la forme du pont liée à ces singularités. Ce modèle permet de mieux comprendre les rôles des forces hydrodynamiques et de la courbure dans l’évolution temporelle de la largeur du pont. Un autre axe est une étude expérimentale par Microscope à Force Atomique, qui permet de décrire les forces responsables de la coalescence à l’échelle nanométrique, les déformations des gouttes intervenant à cette échelle et leur rôle dans la rupture des interfaces. Les mesures de forces entre goutte et flaque, puis entre deux gouttes sont effectuées avec un AFM principalement en mode dynamique de Modulation de Fréquence. Elles permettent de mettre en évidence une distance seuil de déclenchement de l’instabilité hydrodynamique responsable de la coalescence et de mesurer cette distance en fonction des propriétés physiques du liquide et du rayon des gouttes. Un diagramme de coalescence est proposé, qui permet de prévoir la valeur de la distance de déclenchement de la coalescence et le rôle des déformations d’interfaces à l’échelle nanométrique. Enfin, les oscillations du pont liquide, générées par la coalescence, sont étudiées, les modes et fréquences propres sont calculés numériquement par la méthode des éléments finis, puis comparés aux valeurs expérimentales mesurées à partir des films acquis par caméra rapide. / Coalescence is involved in numerous natural or man-made processes, from microphysics of clouds to emulsions stability, or water-crude oil separation processes. In these situations, it is crucial to understand the physics of coalescence of drops or bubbles, in order to influence the phenomenon, to enhance or inhibit the coalescence rate, depending on the needs. In this thesis, we study coalescence in air of two attached drops. We separate the coalescence process into four stages : the approach and drainage of the film between coalescing bodies, the interfaces breaking, the opening of the bridge resulting from this breaking, and the damped oscillations, generated by coalescence, leading to the equilibrium state of the resulting drop. The theoretical description of the stages 1, 2 and 4 are based on continuous hydrodynamic models, at a macroscopic scale. However, the transition between the first two stages is the interfaces break-up, controlled by short range interactions, at a nanometer scale. One of the most difficult issues is the integration of these nanoscale processes into a continuum hydrodynamic theory which length scale is much bigger. The purpose of this work is understand how the phenomenons occurring at the different scales are linked. We first study, at a macroscopic scale, the opening of the liquid bridge between the drops. Thanks to the experimental set-up, involving a high-speed camera, we explore different regimes of flow, by studying the shape and dimensions of the bridge. The existing hydrodynamic models mostly describe the viscous regime, and there exist no complete modeling of the inertial regime. We explore specifically this regime. The bridge shape is described by the mean of capillary waves. We focus on two lines of extremely high curvature on the free surface, that we call singularities, generated in the initial site of interfaces break-up, and propagating merely without deformation towards the extremities of the drops. We propose a model of inertial flow in the opening bridge, whose shape is linked to these "singularities", due to surface tension. This model allows to have a better understanding of the contribution of the hydrodynamic forces and surface tension regarding the time evolution of the length and radius of the bridge. The second area of investigation is a study at a nanometer scale. Atomic Force Microscopy (AFM) is used to measure van der Waals forces between the coalescing bodies and the nanoscale deformations leading to coalescence. We perform force measurements with an AFM, essentially in the Frequency Modulation Mode. Studying the interaction, first between a droplet and a bulk, then between two droplets, we measure the threshold distance below which the coalescence occurs, varying the physical properties of liquids and the drops radius. A coalescence diagram can be built, allowing to predict the threshold distance of coalescence and the part played by the nanoscale deformations in the process. The third point is the study of the weakly damped oscillations of the whole body, induced y coalescence. The eigen frequencies and modes are calculated using the finite elements method, and compared to the experimental results, measured by the mean of the high speed camera. Coalescence Microscopie à force atomique Interaction de van der Waals Déformations d'interfaces Modèle hydrodynamique inertiel Oscillations de pont liquide Coalescence Atomic force microscopy Van der Waals interaction Interface deformations Inertial hydrodynamic model Liquid bridge oscillations 530

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