Global ETD Search

11	Einfluss variierender Substitutionsgrade amphiphiler Polysaccharide auf ihre physikochemischen Eigenschaften und deren potentielle Anwendung bei der Sticky-Kontrolle Genest, Sabine 24 October 2014 (has links) (PDF) Biological degradable polymers on a basis of renewable raw materials, such as polysaccharides, represent promising alternatives to synthetic polymers used as flocculant or stabilizing agents. Polysaccharides derived from potato starch and chitosan have been modified with benzyl- and the first one with additionally cationic hydroxypropyl-trimethylammonium groups of different degrees of substitution (DS). The aim of this work was to characterize the solution properties of these novel amphiphilic polysaccharides concerning the impact of their DS on charge density, particle size, dynamic surface tension and viscosity behaviour. The work is further focused on investigations on flocculation properties of these amphiphilic polyelectrolytes in dispersions of kaolin and silica to identify the interplay between charge density and hydrophobicity. Flocculation efficiency has been evaluated via joint analysis of charge density measurements (using polyelectrolyte titration), turbidity and TOC measurements, as well as dynamic surface tension measurements applying the drop profile analysis. Particle sizes and particle size distributions have been determined by dynamic light scattering and laser diffraction methods. In addition, these amphiphilic starch derivatives have been used to remove substances which impact negatively the paper production process when using recycled paper, so called stickies. Model suspensions have been studied using a multitude of different measurement techniques with the aim to predict a “sticky potential” and to reduce containing dissolved and colloidal substances such as micro stickies. The surface activity and viscometric behaviour have been studied of solely cationic and moderately and highly substituted, amphiphilic polysaccharides in salt-free and 0.05 M NaCl aqueous solution. For the first time dynamic surface tension measurement results have been correlated with particle sizes and apparent charge density. Rheological investigation of large concentration ranges (0.01–20 g/L) was used to discuss Huggins plots and typical polyelectrolyte behaviour for all polysaccharide derivatives could be found. Overlap concentration and, in dilute aqueous solution, intrinsic viscosity could be determined. For polysaccharide solution in dilute regime semi-empirical equations of Rao and Wolf have been applied, making it possible to get insights to polyelectrolyte conformation in dependence on the DS of both substituents. It is shown that for intrinsic viscosity a change of the impact of both substituents takes place when having derivatives with enhanced hydrophobicity. Data evaluation via the ratio of both DS values had been successfully utilized and thus, the applied method has been identified as being a promising tool to compare a multitude of starch derivatives with substituents of different polarity in various degrees of substitution to get tendencies regarding overall hydrophobicity. Moderate hydrophobic substitution was found to lead to a decrease of the efficient flocculant dose and to an increase of the flocculation window width. Amphiphilic starch derivatives with high DS of hydrophobic moieties showing strong hydrophobic association are effective only at significantly higher doses, but in a broader concentration range compared to cationic starch of the same DS. Joint analysis of adsorption isotherms and flocculation test data has revealed, that the surface coverage required to induce phase separation ranges between 10 and 25 % and is minimal for amphiphilic starch derivatives. This gave the evidence of the complex mechanism of flocculation via combination of electrostatic “charge patch” interactions and bridging. Concerning sticky reduction experiments by systematically studying the interactions between the novel amphiphilic starch derivatives and the model suspension it turned out, that dynamic surface tension is a very suitable property to characterize the surface active compounds in the model suspension giving additional information about the sticky potential of waste water, e.g. white water, being a new and sensitive method to describe the parameter “hydrophobicity”. Moderate cationic and hydrophobic starch derivatives have been proved to be the most effective ones for sticky removal. amphiphilic starch surface tension intrinsic viscosity flocculation sticky removal amphiphile Stärke Oberflächenspannung Grenzviskosität Flockung Sticky ddc:540 rvk:WD 5560
12	Analyse und Modellierung der Haftungsmechanismen bei der Beschichtung und Verklebung von Papierwerkstoffen Prístavok, Radovan 24 April 2006 (has links) Das Ziel der vorliegenden Arbeit war, über die gezielte Analyse, Messung und Bewertung, einen entscheidenden Beitrag für das grundlegende Verständnis der Haftungsmechanismen bei der Verklebung von verpackungsindustrienahen Modellsystemen zu leisten. Anhand einer Vielzahl von Untersuchungen zur Charakterisierung der Oberflächenmorphologie, -chemie, -beschaffenheit, der grenzflächenenergetischen und Benetzungseigenschaften konnten einige Ansätze für Korrelationen zwischen Stoff- und Verbundeigenschaften ermittelt werden. Dazu wurden einige neue messtechnische Erkenntnisse zur grenzflächenenergetischen Charakterisierung der Modellsysteme (Modellklebstoffe und -oberflächen) gewonnen. Es wurde allerdings gezeigt, dass bei den beiden untersuchten Klebstoffsystemen (Schmelz- und Dispersionskleber) die Haftmechanismen oft durch klebstoffspezifische Phänomene (Schmelzklebstoffe - Wachsseparation und Dispersionsklebstoffe - wässriger precursor film), welche aufgrund einer grenzflächenbedingten Phasenseparation des Klebstoffes zur Bildung einer &quot;Trennschicht&quot; führen, negativ verändert werden können. info:eu-repo/classification/ddc/620 ddc:620
13	Thermodynamic properties of intermetallics: Surfaces and interfaces Amirkhanyan, Lilit 12 September 2018 (has links) In this dissertation, intermetallic phases Fe2Al5, Fe5Al8, Al3FeSi2 have been studied using density functional theory (DFT). The theoretical methods allow for parameter-free predictions without any experimental input of thermodynamical data like specific heat or phase stabilities. Such information is of great interest to thermodynamical modelling. Another strength of DFT is the possibility to investigate chemical reactions as demonstrated in case of the formation of hercynite (Fe2AlO4) in a solid-state reaction of corundum (α - Al2O3) and iron. Further, the Al2O3 surface energies of various planes were investigated. In addition, interfaces, which are of experimental interest within CRC 920, were modelled: α - Al2O3 (0001) \|\| Al(111), TiO2 (rutile) \|\| MgTiO3 (geikielite) and α - Al2O3 (corundum). info:eu-repo/classification/ddc/540 ddc:540 Intermetallische Verbindungen Eisen Aluminium Silicium Dichtefunktionalformalismus Oberflächenspannung
14	Oberflaechen- und Grenzflaechenspannung in binaeren metallischen Entmischungssystemen Merkwitz, Markus 30 July 1997 (has links) Zu Beginn der Arbeit werden thermodynamische, strukturelle und statistische Grundlagen und Modelle wiedergegeben, die einerseits Entmischungssysteme und andererseits flüssige Ober- und Grenzflächen betreffen. Hieran schließt sich eine umfangreiche Darstellung der Meßmethode an, die die theoretischen Zusammenhänge für die Beschreibung der Formen flüssiger Grenzflächen sowie eine Darstellung aller experimentell möglichen Kraftmeßkurven und deren Auswertung beinhaltet. Weiterhin folgt die Darstellung der Dichte-, Dichtedifferenz-, und Grenzflächenspannungsmeßergebnisse separat für die Systeme Ga-Hg, Ga-Pb, Al-Pb und Al-In. Die Temperaturabhängigkeit und die Absolutwerte der Grenzflächenspannung werden mit den vorgestellten Modellen verglichen. Im Anschluß daran werden die Oberflächenspannungsmeßergebnisse für das System Ga-Pb vorgestellt, dies geschieht unter Bezugnahme auf Benetzungsphänomene, Adsorptionserscheinungen und Keimbildungsprozesse. In einem relativ selbständigen Kapitel am Ende der Arbeit werden experimentelle Ergebnisse zur Durchmischung und Entmischung wiedergegeben und mit theoretischen Ergebnissen zum diffusionsgesteuerten Durchmischungsprozeß verglichen. info:eu-repo/classification/ddc/530 ddc:530 info:eu-repo/classification/ddc/600 ddc:600 Diffusion Keimbildung Adsorption Benetzung Binäre Legierung Monotektische Legierung Grenzflächenspannung Oberflächenspannung Wetting Flüssiges Metall Entmischungssystem
15	Einfluss variierender Substitutionsgrade amphiphiler Polysaccharide auf ihre physikochemischen Eigenschaften und deren potentielle Anwendung bei der Sticky-Kontrolle Genest, Sabine 22 July 2014 (has links) Biological degradable polymers on a basis of renewable raw materials, such as polysaccharides, represent promising alternatives to synthetic polymers used as flocculant or stabilizing agents. Polysaccharides derived from potato starch and chitosan have been modified with benzyl- and the first one with additionally cationic hydroxypropyl-trimethylammonium groups of different degrees of substitution (DS). The aim of this work was to characterize the solution properties of these novel amphiphilic polysaccharides concerning the impact of their DS on charge density, particle size, dynamic surface tension and viscosity behaviour. The work is further focused on investigations on flocculation properties of these amphiphilic polyelectrolytes in dispersions of kaolin and silica to identify the interplay between charge density and hydrophobicity. Flocculation efficiency has been evaluated via joint analysis of charge density measurements (using polyelectrolyte titration), turbidity and TOC measurements, as well as dynamic surface tension measurements applying the drop profile analysis. Particle sizes and particle size distributions have been determined by dynamic light scattering and laser diffraction methods. In addition, these amphiphilic starch derivatives have been used to remove substances which impact negatively the paper production process when using recycled paper, so called stickies. Model suspensions have been studied using a multitude of different measurement techniques with the aim to predict a “sticky potential” and to reduce containing dissolved and colloidal substances such as micro stickies. The surface activity and viscometric behaviour have been studied of solely cationic and moderately and highly substituted, amphiphilic polysaccharides in salt-free and 0.05 M NaCl aqueous solution. For the first time dynamic surface tension measurement results have been correlated with particle sizes and apparent charge density. Rheological investigation of large concentration ranges (0.01–20 g/L) was used to discuss Huggins plots and typical polyelectrolyte behaviour for all polysaccharide derivatives could be found. Overlap concentration and, in dilute aqueous solution, intrinsic viscosity could be determined. For polysaccharide solution in dilute regime semi-empirical equations of Rao and Wolf have been applied, making it possible to get insights to polyelectrolyte conformation in dependence on the DS of both substituents. It is shown that for intrinsic viscosity a change of the impact of both substituents takes place when having derivatives with enhanced hydrophobicity. Data evaluation via the ratio of both DS values had been successfully utilized and thus, the applied method has been identified as being a promising tool to compare a multitude of starch derivatives with substituents of different polarity in various degrees of substitution to get tendencies regarding overall hydrophobicity. Moderate hydrophobic substitution was found to lead to a decrease of the efficient flocculant dose and to an increase of the flocculation window width. Amphiphilic starch derivatives with high DS of hydrophobic moieties showing strong hydrophobic association are effective only at significantly higher doses, but in a broader concentration range compared to cationic starch of the same DS. Joint analysis of adsorption isotherms and flocculation test data has revealed, that the surface coverage required to induce phase separation ranges between 10 and 25 % and is minimal for amphiphilic starch derivatives. This gave the evidence of the complex mechanism of flocculation via combination of electrostatic “charge patch” interactions and bridging. Concerning sticky reduction experiments by systematically studying the interactions between the novel amphiphilic starch derivatives and the model suspension it turned out, that dynamic surface tension is a very suitable property to characterize the surface active compounds in the model suspension giving additional information about the sticky potential of waste water, e.g. white water, being a new and sensitive method to describe the parameter “hydrophobicity”. Moderate cationic and hydrophobic starch derivatives have been proved to be the most effective ones for sticky removal. info:eu-repo/classification/ddc/540 ddc:540
16	The Mechanics of Mitotic Cell Rounding Stewart, Martin 11 July 2012 (has links) (PDF) During mitosis, adherent animal cells undergo a drastic shape change, from essentially flat to round, in a process known as mitotic cell rounding (MCR). The aim of this thesis was to critically examine the physical and biological basis of MCR. The experimental part of this thesis employed a combined optical microscope-atomic force microscope (AFM) setup in conjunction with flat tipless cantilevers to analyze cell mechanics, shape and volume. To this end, two AFM assays were developed: the constant force assay (CFA), which applies constant force to cells and measures the resultant height, and the constant height assay (CHA), which confines cell height and measures the resultant force. These assays were deployed to analyze the shape and mechanical properties of single cells trans-mitosis. The CFA results showed that cells progressing through mitosis could increase their height against forces as high as 50 nN, and that higher forces can delay mitosis in HeLa cells. The CHA results showed that mitotic cells confined to ~50% of their normal height can generate forces around 50-100 nN without disturbing mitotic progression. Such forces represent intracellular pressures of at least 200 Pascals and cell surface tensions of around 10 nN/µm. Using the CHA to compare mitotic cell rounding with induced cell rounding, it was observed that the intracellular pressure of mitotic cells is at least 3-fold higher than rounded interphase cells. To investigate the molecular basis of the mechanical changes inherent in mitotic cell rounding, inhibitors and toxins were used to pharmacologically dissect the role of candidate cellular processes. These results implicated the actomyosin cortex and osmolyte transporters, the most prominent of which is the Na+/H+ exchanger, in the maintenance of mechanical properties and intracellular hydrostatic pressure. Observations on blebbing cells under the cantilever supported the idea that the actomyosin cortex is required to sustain hydrostatic pressure and direct this pressure into cell shape changes. To gain further insight into the relationship between actomyosin activity and intracellular pressure, dynamic perturbation experiments were conducted. To this end, the CHA was used to evaluate the pressure and volume of mitotic cells before, during and after dynamic perturbations that included tonic shocks, influx of specific inhibitors, and exposure to pore-forming toxins. When osmotic pressure gradients were depleted, pressure and volume decreased. When the actomyosin cytoskeleton was abolished, cell volume increased while rounding pressure decreased. Conversely, stimulation of actomyosin cortex contraction triggered an increase in rounding pressure and a decrease in volume. Taken together, the dynamic perturbation results demonstrated that the actomyosin cortex contracts against an opposing intracellular pressure and that this relationship sets the surface tension, pressure and volume of the cell. The discussion section of this thesis provides a comprehensive overview of the physical basis of MCR by amalgamating the experimental results of this thesis with the literature. Additionally, the biochemal signaling pathways and proteins that drive MCR are collated and discussed. An exhaustive and unprecedented synthesis of the literature on cell rounding (approx. 750 papers as pubmed search hits on “cell rounding”, April 2012) reveals that the spread-to-round transition can be thought of in terms of a surface tension versus adhesion paradigm, and that cell rounding can be physically classified into four main modes, of which one is an MCR-like category characterized by increased actomyosin cortex tension and diminution of focal adhesions. The biochemical pathways and signaling patterns that correspond with these four rounding modes are catalogued and expounded upon in the context of the relevant physiology. This analysis reveals cell rounding as a pertinent topic that can be leveraged to yield insight into core principles of cell biophysics and tissue organization. It furthermore highlights MCR as a model problem to understand the adhesion versus cell surface tension paradigm in cells and its fundamentality to cell shape, mechanics and physiology. mitotische Zellabrundung Zellabrundung Mitose Rasterkraftmikroskopie AFM Zell-Biophysik Zellform Zellphysiologie Zell-Mechanik Zellvolumen intrazellulärer Druck Actomyosin Runden Kraft Zelle Oberflächenspannung Cortex Spannung Zelladhäsion mitotic cell rounding cell rounding mitosis AFM cell biophysics cell shape cell physiology cell mechanics cell volume intracellular pressure actomyosin rounding force cell surface tension cortex tension cell adhesion ddc:570 rvk:WE 2100
17	Dynamics and mechanics of compartment boundaries in developing tissues Aliee, Maryam 02 July 2013 (has links) (PDF) During development of tissues, cells collectively organize to form complex patterns and morphologies. A general feature of many developing epithelia is their distinct organization into cellular compartments of different cell lineages. The interfaces between these compartments, called compartment boundaries, maintain straight and sharp morphologies. The interfaces play key roles in tissue development and pattern formation. An important model system to study the morphology of compartment boundaries during development is the wing disc of the fruit fly. Two compartment boundaries exist in the fly wing disc, the anteroposterior (AP) boundary and the dorsoventral (DV) boundary. A crucial question is how compartment boundaries are shaped and remain stable during growth. In this work, we discuss the dynamics and mechanisms of compartment boundaries in developing epithelia. We analyze the general features of interfacial phenomena in coarse- grained models of passive and active fluids. We introduce a continuum description of tissues with two cell types. This model allows us to study the propagation of interfaces due to the interplay of cell dynamics and tissue mechanics. We also use a vertex model to describe cellular compartments in growing epithelia. The vertex model accounts for cell mechanics and describes a 2D picture of tissues where the network of adherens junctions characterizes cell shapes. We use this model to study the general physical mechanisms by which compartment boundaries are shaped. We quantify the stresses in the cellular network and discuss how cell mechanics and growth influence the stress profile. With the help of the anisotropic stress profile near the interfaces we calculate the interfacial tension. We show that cell area pressure, cell proliferation rate, orientation of cell division, cell elongation created by external stress, and cell bond tension all have distinct effects on the morphology of interfaces during tissue growth. Furthermore, we investigate how much different mechanisms contribute to the effective interfacial tension. We study the mechanisms shaping the DV boundary in wing imaginal disc at different stages during the development. We analyze the images of wing discs to quantify the roughness of the DV boundary and average cell elongation in its vicinity. We quantify increased cell bond tension along the boundary and analyze the role of localized reduction in cell proliferation on the morphology of the DV boundary. We use experimentally determined values for cell bond tension, cell elongation and bias in orientation of cell division in simulations of tissue growth in order to reproduce the main features of the time-evolution of the DV boundary shape. Gewebeentwicklung Grenzflächen Oberflächenspannung Rauheit von Grenzflächen Grenzflächenausbreitung Mechanismen der Grenzflächenform Epithelien Imaginalscheibe des Flügels Vertex-Modell Gewebemechanik Tissue development Interfaces interfacial tension roughness of interfaces compartment boundaries interface propagation mechanisms shaping interfaces epithelia wing imaginal disc vertex model tissue mechanics ddc:570 rvk:WD 2300
18	The Mechanics of Mitotic Cell Rounding Stewart, Martin 29 June 2012 (has links) During mitosis, adherent animal cells undergo a drastic shape change, from essentially flat to round, in a process known as mitotic cell rounding (MCR). The aim of this thesis was to critically examine the physical and biological basis of MCR. The experimental part of this thesis employed a combined optical microscope-atomic force microscope (AFM) setup in conjunction with flat tipless cantilevers to analyze cell mechanics, shape and volume. To this end, two AFM assays were developed: the constant force assay (CFA), which applies constant force to cells and measures the resultant height, and the constant height assay (CHA), which confines cell height and measures the resultant force. These assays were deployed to analyze the shape and mechanical properties of single cells trans-mitosis. The CFA results showed that cells progressing through mitosis could increase their height against forces as high as 50 nN, and that higher forces can delay mitosis in HeLa cells. The CHA results showed that mitotic cells confined to ~50% of their normal height can generate forces around 50-100 nN without disturbing mitotic progression. Such forces represent intracellular pressures of at least 200 Pascals and cell surface tensions of around 10 nN/µm. Using the CHA to compare mitotic cell rounding with induced cell rounding, it was observed that the intracellular pressure of mitotic cells is at least 3-fold higher than rounded interphase cells. To investigate the molecular basis of the mechanical changes inherent in mitotic cell rounding, inhibitors and toxins were used to pharmacologically dissect the role of candidate cellular processes. These results implicated the actomyosin cortex and osmolyte transporters, the most prominent of which is the Na+/H+ exchanger, in the maintenance of mechanical properties and intracellular hydrostatic pressure. Observations on blebbing cells under the cantilever supported the idea that the actomyosin cortex is required to sustain hydrostatic pressure and direct this pressure into cell shape changes. To gain further insight into the relationship between actomyosin activity and intracellular pressure, dynamic perturbation experiments were conducted. To this end, the CHA was used to evaluate the pressure and volume of mitotic cells before, during and after dynamic perturbations that included tonic shocks, influx of specific inhibitors, and exposure to pore-forming toxins. When osmotic pressure gradients were depleted, pressure and volume decreased. When the actomyosin cytoskeleton was abolished, cell volume increased while rounding pressure decreased. Conversely, stimulation of actomyosin cortex contraction triggered an increase in rounding pressure and a decrease in volume. Taken together, the dynamic perturbation results demonstrated that the actomyosin cortex contracts against an opposing intracellular pressure and that this relationship sets the surface tension, pressure and volume of the cell. The discussion section of this thesis provides a comprehensive overview of the physical basis of MCR by amalgamating the experimental results of this thesis with the literature. Additionally, the biochemal signaling pathways and proteins that drive MCR are collated and discussed. An exhaustive and unprecedented synthesis of the literature on cell rounding (approx. 750 papers as pubmed search hits on “cell rounding”, April 2012) reveals that the spread-to-round transition can be thought of in terms of a surface tension versus adhesion paradigm, and that cell rounding can be physically classified into four main modes, of which one is an MCR-like category characterized by increased actomyosin cortex tension and diminution of focal adhesions. The biochemical pathways and signaling patterns that correspond with these four rounding modes are catalogued and expounded upon in the context of the relevant physiology. This analysis reveals cell rounding as a pertinent topic that can be leveraged to yield insight into core principles of cell biophysics and tissue organization. It furthermore highlights MCR as a model problem to understand the adhesion versus cell surface tension paradigm in cells and its fundamentality to cell shape, mechanics and physiology. info:eu-repo/classification/ddc/570 ddc:570
19	Dynamics and mechanics of compartment boundaries in developing tissues Aliee, Maryam 22 April 2013 (has links) During development of tissues, cells collectively organize to form complex patterns and morphologies. A general feature of many developing epithelia is their distinct organization into cellular compartments of different cell lineages. The interfaces between these compartments, called compartment boundaries, maintain straight and sharp morphologies. The interfaces play key roles in tissue development and pattern formation. An important model system to study the morphology of compartment boundaries during development is the wing disc of the fruit fly. Two compartment boundaries exist in the fly wing disc, the anteroposterior (AP) boundary and the dorsoventral (DV) boundary. A crucial question is how compartment boundaries are shaped and remain stable during growth. In this work, we discuss the dynamics and mechanisms of compartment boundaries in developing epithelia. We analyze the general features of interfacial phenomena in coarse- grained models of passive and active fluids. We introduce a continuum description of tissues with two cell types. This model allows us to study the propagation of interfaces due to the interplay of cell dynamics and tissue mechanics. We also use a vertex model to describe cellular compartments in growing epithelia. The vertex model accounts for cell mechanics and describes a 2D picture of tissues where the network of adherens junctions characterizes cell shapes. We use this model to study the general physical mechanisms by which compartment boundaries are shaped. We quantify the stresses in the cellular network and discuss how cell mechanics and growth influence the stress profile. With the help of the anisotropic stress profile near the interfaces we calculate the interfacial tension. We show that cell area pressure, cell proliferation rate, orientation of cell division, cell elongation created by external stress, and cell bond tension all have distinct effects on the morphology of interfaces during tissue growth. Furthermore, we investigate how much different mechanisms contribute to the effective interfacial tension. We study the mechanisms shaping the DV boundary in wing imaginal disc at different stages during the development. We analyze the images of wing discs to quantify the roughness of the DV boundary and average cell elongation in its vicinity. We quantify increased cell bond tension along the boundary and analyze the role of localized reduction in cell proliferation on the morphology of the DV boundary. We use experimentally determined values for cell bond tension, cell elongation and bias in orientation of cell division in simulations of tissue growth in order to reproduce the main features of the time-evolution of the DV boundary shape. info:eu-repo/classification/ddc/570 ddc:570
20	Methodenentwicklung zur Simulation von Strömungen mit freier Oberfläche unter dem Einfluss elektromagnetischer Wechselfelder Beckstein, Pascal 16 February 2018 (has links) (PDF) Im Bereich der industriellen Metallurgie und Kristallzüchtung treten bei zahlreichen Anwendungen, wo magnetische Wechselfelder zur induktiven Beeinflussung von leitfähigen Werkstoffen eingesetzt werden, auch Strömungen mit freier Oberfläche auf. Das Anwendungsspektrum reicht dabei vom einfachen Aufschmelzen eines Metalls in einem offenen Tiegel bis hin zur vollständigen Levitation. Auch der sogenannte RGS-Prozess, ein substratbasiertes Kristallisationsverfahren zur Herstellung siliziumbasierter Dünnschichtmaterialien, ist dafür ein Beispiel. Um bei solchen Prozessen die Interaktion von Magnetfeld und Strömung zu untersuchen, ist die numerische Simulationen ein wertvolles Hilfsmittel. Für beliebige dreidimensionale Probleme werden entsprechende Berechnungen bisher durch eine externe Kopplung kommerzieller Programme realisiert, die für Magnetfeld und Strömung jeweils unterschiedliche numerische Techniken nutzen. Diese Vorgehensweise ist jedoch im Allgemeinen mit unnötigem Rechenaufwand verbunden. In dieser Arbeit wird ein neu entwickelter Methodenapparat auf Basis der FVM vorgestellt, mit welchem sich diese Art von Berechnungen effizient durchführen lassen. Mit der Implementierung dieser Methoden in foam-extend, einer erweiterten Version der quelloffenen Software OpenFOAM, ist daraus ein leistungsfähiges Werkzeug in Form einer freien Simulationsplattform entstanden, welches sich durch einen modularen Aufbau leicht erweitern lässt. Mit dieser Plattform wurden in foam-extend auch erstmalig dreidimensionale Induktionsprozesse im Frequenzraum gelöst. Metallurgie Kristallzüchtung Elektroprozesstechnik elektromagnetisches Prozessieren Optimierung Simulation RGS Ribbon-Growth on Substrate freie Oberfläche Interface-Tracking Induktion metallurgische MHD MHD Magnetodynamik Hydrodynamik Thermodynamik Magnetohydrodynamik OpenFOAM foam-extend Methodenentwicklung Softwareplattform Numerische Methoden Strömung mit freier Oberfläche Metalle Halbmetalle Silizium Wafer 3D METIS FVM Finite-Volumen-Methode elektromagnetische Wechselfelder zeitharmonische Anregung Frequenzraum Blockmatrizen diskontinuierliche Materialeigenschaften magnetische Permeabilität elektrische Leitfähigkeit eingebettete Diskretisierung GFM Ghost-Fluid-Methode Mehrfeldproblem Multi-Physics Biot-Savart Biot-Savart-Gesetz Biot-Savart-Induktoren überlagerte Gitter ALE Gitterbewegung Kopplung FAM Finite-Flächen-Methode RMF rotierendes Magnetfeld TMF wanderndes Magnetfeld Validierung Maxwell Maxwell-Gleichungen Navier-Stokes Navier-Stokes-Gleichung inkompressibel Schmelze Lorentz-Kraft Induktor Konduktor Induktionsspulen Wirbelströme Wirbelstromproblem PISO Oberflächenspannung semi-gekoppelter Lösungsalgorithmus Diskretisierung Skineffekt AC quasistatische Approximation Magneto-Quasistatik metallurgy crystal growth electromagnetic processing optimization Simulation RGS Ribbon-Growth on Substrate free-surface interface-tracking Induction metallurgical MHD MHD magnetodynamics hydrodynamics thermodynamics magnetohydrodynamics OpenFOAM foam-extend method development software platform numerical methods free-surface flow metals metalloids silicon wafer 3D METIS FVM Finite-Volumen-Method oscillating magnetic fields time-harmonic excitation frequency domain block-matrices discontinuous material properties magnetic permeability electrical conductivity embedded discretization GFM Ghost-Fluid-Method multi-physics Biot-Savart Biot-Savart-inductor overlapped meshes ALE mesh movement coupling FAM Finite-Area-Method RMF rotating magnetic field TMF traveling magnetic field validation Maxwell Maxwell-equations Navier-Stokes Navier-Stokes-equation incompressible melt melt flow Lorentz-force inductor conductor induction coil eddy-currents eddy-current problem PISO surface-tension semi-coupled solution discretization skin effect AC quasi-static approximation ddc:620 rvk:UF 4600

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