Global ETD Search

21	Adsorption of polyhydroxyl based surfactants Matsson, Maria January 2005 (has links) Adsorption on solid surfaces from solution is a fundamental property of a surfactant. It might even be the most important aspect of surfactant behavior, since it influences many applications, such as cleaning, detergency, dispersion, separation, flotation, and lubrication. Consequently, fundamental investigations of surfactant adsorption are relevant to many areas. The main aim of this thesis has been to elucidate the adsorption properties, primarily on the solid/water interface, of a particular class of polyhydroxyl based surfactants: the alkyl glucosides. By the use of ellipsometry, the equilibrium and kinetic aspects of adsorption on titanium dioxide with respect to structural effects has been studied. Furthermore, the effects of small amounts of cationic surfactant additives on the adsorption on silica have been investigated. The results have been compared with similar studies for other nonionic surfactants. We have found that the surfactant structure has a strong effect on the adsorption properties. An increase in the surfactant chain length increases the cooperativity of the system. An increase in the head group polymerization decreases the cooperativity and the plateau adsorbed amount at equilibrium. The effect of surfactant structure on the adsorption kinetics depends on the concentration relative to the cmc, while the there is a decrease in the rate of desorption with increasing hydrophobic chain length independent of the concentration. The adsorption/desorption process is concluded to be diffusion driven, as suggested by the model used. When comparing these results with studies on ethylene oxide based surfactants, we conclude that the two types of surfactants exhibit similar trends on surfaces onto which they adsorb. Adsorption from binary surfactant solutions is even more interesting than adsorption from single surfactant solutions, since it brings us one step closer to the systems used in applications. In addition, adsorption from a mixture can be very different from adsorption from any of the single surfactants in the mixture. Alkyl glucosides alone do not adsorb on silica, but addition of small amounts of a cationic surfactant to the alkyl glucoside solution allows for adsorption on silica. A comparison between the adsorption and bulk properties has shown that mixed micellization explains most, but not all, effects of the coadsorption properties. Changing the pH in the mixed systems reveals that a surfactant with a pH-dependent charge and the ability to adapt its charge to the environment, e.g. a surface, enhances the adsorbed amount over a wider range of pH values than a purely cationic surfactant. It is well known that alkyl glucosides and ethylene oxides adsorb differently on different types of hydrophilic surfaces. As a consequence, replacing ethylene oxides with alkyl glucosides might not be all straight-forward; however, we have shown that the effect of the surface can be eliminated by the use of a cosurfactant. / <p>QC 20101018</p> Physical chemistry surface chemistry adsorption surfactant nonionic alkyl glucoside (APG) ellipsometry kinetics alkyl amine oxide (DDAO) alkyl ammonium bromide (DTAB) solid/liquid interface synergism coadsorption.
22	Multilayer Structures for Biomaterial Applications : Biomacromolecule-based Coatings Halthur, Tobias January 2005 (has links) The cellular response to a biomaterial, such as a dental implant, is mainly governed by the surface properties, and can thus be altered by the introduction of a surface coating. In this thesis the buildup of a biomacromolecule-based coating formed by layerby-layer (LbL) deposition of the charged polypeptides poly(L-lysine) (PLL) and poly(L-glutamic acid) (PGA) has been studied. In an attempt to make these coatings bioactive and useful for bone-anchored implants, an amelogenin protein mixture (EMD), has been immobilized in these thin polyelectrolyte multilayer (PEM) films. Multilayers were also built by LbL deposition of the natural biomacromolecules collagen (Col) and hyaluronic acid (HA). Multilayer films of these two extra-cellular biomacromolecules should be of interest for use as a scaffold for tissue engineering. The buildup of the multilayer films has been followed in situ, using ellipsometry, quartz crystal microbalance with dissipation (QCM-D), and dual polarization interferometry (DPI). The studied PLL/PGA multilayers were found to be highly hydrated, and to exhibit a two-regime buildup behavior, with an initial “slow-growing” regime, and a second “fast-growing” regime with a linear growth in film thickness and more than linear growth in mass. A net diffusion of polypeptides into the film during the buildup led to an increase in density of the films for each layer adsorbed. A change in density was also observed in the Col/HA film, where HA penetrated and diffused into the porous fibrous Col network. The formed PLL/PGA films were further found to be rather stable during drying, and post-buildup changes in temperature and pH, not losing any mass as long as the temperature was not raised too rapidly. The film thickness responded to changes in the ambient media and collapsed reversibly when dried. A swelling/de-swelling behavior of the film was also observed for changes in the temperature and pH. The EMD protein adsorbed to silica surfaces as nanospheres, and could by itself form multilayers. The adsorption of EMD onto PLL/PGA multilayer films increased at lower pH (5.0), and EMD could be immobilized in several layers by alternate deposition of EMD and PGA. / QC 20101019 multilayer layer-by-layer deposition physical chemistry surface chemistry adsorption ellipsometry QCM-D DPI protein adsorption polypeptides biomaterials biosurfaces amelogenin solid/liquid interface Surface and colloid chemistry Yt- och kolloidkemi
23	Multilayer Structures for Biomaterial Applications : Biomacromolecule-based Coatings Halthur, Tobias January 2005 (has links) <p>The cellular response to a biomaterial, such as a dental implant, is mainly governed by the surface properties, and can thus be altered by the introduction of a surface coating. In this thesis the buildup of a biomacromolecule-based coating formed by layerby-layer (LbL) deposition of the charged polypeptides poly(L-lysine) (PLL) and poly(L-glutamic acid) (PGA) has been studied. In an attempt to make these coatings bioactive and useful for bone-anchored implants, an amelogenin protein mixture (EMD), has been immobilized in these thin polyelectrolyte multilayer (PEM) films. Multilayers were also built by LbL deposition of the natural biomacromolecules collagen (Col) and hyaluronic acid (HA). Multilayer films of these two extra-cellular biomacromolecules should be of interest for use as a scaffold for tissue engineering.</p><p>The buildup of the multilayer films has been followed in situ, using ellipsometry, quartz crystal microbalance with dissipation (QCM-D), and dual polarization interferometry (DPI). The studied PLL/PGA multilayers were found to be highly hydrated, and to exhibit a two-regime buildup behavior, with an initial “slow-growing” regime, and a second “fast-growing” regime with a linear growth in film thickness and more than linear growth in mass. A net diffusion of polypeptides into the film during the buildup led to an increase in density of the films for each layer adsorbed. A change in density was also observed in the Col/HA film, where HA penetrated and diffused into the porous fibrous Col network.</p><p>The formed PLL/PGA films were further found to be rather stable during drying, and post-buildup changes in temperature and pH, not losing any mass as long as the temperature was not raised too rapidly. The film thickness responded to changes in the ambient media and collapsed reversibly when dried. A swelling/de-swelling behavior of the film was also observed for changes in the temperature and pH.</p><p>The EMD protein adsorbed to silica surfaces as nanospheres, and could by itself form multilayers. The adsorption of EMD onto PLL/PGA multilayer films increased at lower pH (5.0), and EMD could be immobilized in several layers by alternate deposition of EMD and PGA.</p> multilayer layer-by-layer deposition physical chemistry surface chemistry adsorption ellipsometry QCM-D DPI protein adsorption polypeptides biomaterials biosurfaces amelogenin solid/liquid interface Surface and colloid chemistry Yt- och kolloidkemi
24	Avaliação da tensão interfacial dinâmica em revestimentos epóxi do tipo DGEBA modificada com agentes de cura à base de amina. Friedrich, Leila Augusta January 2006 (has links) Submitted by Edileide Reis (leyde-landy@hotmail.com) on 2013-04-23T12:35:07Z No. of bitstreams: 1 Leila Friedrich.pdf: 945666 bytes, checksum: 6bd01ba22dfd6b6e880b4f9a131adaee (MD5) / Made available in DSpace on 2013-04-23T12:35:07Z (GMT). No. of bitstreams: 1 Leila Friedrich.pdf: 945666 bytes, checksum: 6bd01ba22dfd6b6e880b4f9a131adaee (MD5) Previous issue date: 2006 / As tubulações de aço carbono, para a produção e transporte de produtos químicos, apresentam limitações como resistência à ação da corrosão, sob ação do calor, causando desgaste. Por esse motivo se faz o uso de revestimentos que reduzem o contato da superfície com o meio corrosivo. No entanto, os revestimentos usados para o escoamento de fluídos têm ainda que apresentar uma menor interação com a superfície, uma menor tensão interfacial. Uma grande aplicação destes revestimentos é em dutos de petróleo, devido às obstruções ocasionadas à medida que o óleo escoa através do duto, pois este perde calor para o meio e conseqüentemente se dá à deposição de compostos parafínicos. Análises destes revestimentos com a técnica PLF-FI são de suma importância para avaliar a tensão interfacial dinâmica, pois esta técnica difere das tradicionais para a caracterização da superfície, por ser um método não destrutível e dinâmico. Para a confecção das amostras alguns tempos e temperaturas de cura foram aplicados. Neste presente trabalho, avaliamos quais as superfícies apresentam menor molhabilidade sob condições de fluxo com a superfície, visando um menor número de ocorrências de obstruções das tubulações e paradas para manutenções. Os valores de polarização máxima são verificados para as amostras curadas numa faixa de temperatura entre 120°C a 140°C e tempos de 6 a 10 horas, e sendo estes as variáveis de processo mais indicadas para a produção em alta escala. O presente trabalho foi organizado em 5 capítulos, apresentando-se no Capítulo 1 uma introdução do estudo realizado para a otimização do processo de cura em resinas epóxi modificada com agentes de cura a base de amina. No capítulo 2, apresenta-se uma revisão das tubulações, resina epóxi, a composição, e a cura dos revestimentos. No 12 capítulo 3, revisam-se as técnicas de análises e descrevem-se todas as técnicas experimentais realizadas. No capítulo 4, discutem-se os resultados adquiridos pelas técnicas utilizadas. No capítulo 5, relatam-se as conclusões deste trabalho. / Salvador Físico-química Polimeros Tecnica PLF-FI Tensão interfacial Termofixos Interface sólido-líquido Polymers Technique PLF-FI Interfacial tension Thermosets Solid-liquid interface
25	Sum Frequency Generation Vibrational Spectroscopic Study of Methacrylate-Based Monomers at the Solid-liquid Interface and Polymer Thin Films at Air-polymer and Polymer-liquid Interfaces Adhikari, Narendra M. 04 June 2019 (has links) No description available. Chemistry Materials Science Physical Chemistry Polymers Sum Frequency Generation Non-linear Spectroscopy Solid-liquid Interface Methacrylate Monomers Polymer Thin Films Vibrational Spectroscopy
26	Functional interfaces Reinhardt, Matthias 28 March 2014 (has links) Verankerte Polymere können die Funktionalität einer Oberfläche beeinflussen. Der Schwerpunkt dieser Arbeit liegt auf der Untersuchung von Polymerbürsten aus Polyacrylsäure (PAA) und Poly(N,N-dimethylaminoethyl methacrylat) (PDMAEMA). Auf Oberflächen, die mit PAA Bürsten beschichtet sind, können Proteine im nativen Zustand immobilisiert werden. Für PDMAEMA ist eine Reaktion auf externe Reize bekannt. So kann dessen untere kritische Lösungstemperatur (LCST) zur Einstellung der Hydrophobizität von Oberflächen verwendet werden. Erstmalig im Rahmen dieser Arbeit wurde untersucht, wie sich hydrostatischer Druck von bis zu 1000 bar auf die Funktionalität der verwendeten Polymerbürsten auswirkt. Aus Diblock-Kopolymeren wurden Langmuir-Filme unterschiedlicher Ankerdichte mit der Langmuir-Schäfer Technik auf feste Substrate übertragen. Die Funktionalität der PAA Bürsten wurde vor und nach der Adsorption von Rinderserumalbumin (BSA) in gepufferter D2O-Lösung mit Hilfe der Neutronenreflektometrie (NR) bei 1 bar und 900 bar an der fest-flüssig Grenzfläche untersucht. Es wurden Volumenfraktionsprofile der PAA Bürste und adsorbierten BSA extrahiert, woraus sich eine lineare Abhängigkeit zwischen Ankerdichte und Menge an adsorbiertem Protein feststellen ließ. Erhöhung des hydrostatischen Druckes auf 900 bar veränderte weder die PAA Volumenprofile noch die Immobilisierung von BSA. Die PDMAEMA Bürsten wurden mittels NR bei Temperaturen von 20-60 °C und Drücken von 1-1000 bar untersucht. Zur Analyse der Daten wurde ein neuartiges Dichteprofil-Modell verwendet. Temperaturerhöhung führt zur stetigen Abnahme der Bürstendicke. Dies lässt sich durch den LCST induzierten Phasenübergang der Polymere vom hydrophilen in einen hydrophoben Zustand erklären. Es wurde gefunden, dass eine Erhöhung des hydrostatischen Druckes diesem Prozess entgegenwirkt. Strukturänderungen der Polymerbürsten bei Erhöhung der Temperatur um 10 K ließen sich durch Erhöhung des Druckes um 1000 bar rückgängig machen. / The functionality of an interface can be modified by polymer brushes. The focus of this work is on brushes of either polyacrylic acid (PAA) or poly(N,N-dimethylaminoethyl methacrylate) (PDMAEMA). PAA brushes provide a soft interface that prevents the denaturation of adsorbed proteins. PDMAEMA is known to respond to external stimuli. The lower critical solution temperature (LCST) of PDMAEMA can be used to tune the hydrophobicity of the interface with temperature. For the first time, the effect of elevated hydrostatic pressure, up to 1000 bar, on the functionality of these systems is investigated. Planar PAA and PDMAEMA brushes are prepared from precursor diblock copolymer Langmuir layers with varied grafting density utilizing the Langmuir-Schäfer transfer technique. For solvent-swollen PAA brushes, neutron reflectivity (NR) measurements are conducted at the solid-liquid interface after incubation in buffered D2O and after the adsorption of bovine serum albumin (BSA) from the aqueous liquid phase at 1 bar and 900 bar. Detailed volume fraction profiles of the PAA brush and adsorbed BSA proteins are extracted. The amount of adsorbed BSA is found to scale linearly with grafting density. An elevated hydrostatic pressure of 900 bar is found to have no impact on the structure of the PAA brush and its capability to bind BSA proteins. The PDMAEMA brushes are investigated by NR at the solid-liquid interface in a temperature range of 20 to 60 °C for hydrostatic pressures from 1 to 1000 bar. A novel theoretical model of the brush density profile is used to fit the experimental NR data. Increasing the temperature causes a continuous decrease of the polymer brush thickness due to a hydrophobic coil to globule transition of the polymer chains when crossing the LCST. Hydrostatic pressure is found to act antagonistic to temperature. The hydrophobic collapse of the PDMAEMA brush caused by a temperature increase of 10 K is counterbalanced by a pressure increase of 1000 bar. Polymerbürste PAA PDMAEMA hydrostatischer Druck Neutronenreflektometrie BSA fest-flüssig Grenzfläche polymer brush PAA PDMAEMA hydrostatic pressure neutron reflectometry BSA solid-liquid interface 530 Physik 29 Physik, Astronomie UV 6000 VK 8007 ddc:530
27	Adsorption of polyhydroxyl based surfactants Matsson, Maria January 2005 (has links) <p>Adsorption on solid surfaces from solution is a fundamental property of a surfactant. It might even be the most important aspect of surfactant behavior, since it influences many applications, such as cleaning, detergency, dispersion, separation, flotation, and lubrication. Consequently, fundamental investigations of surfactant adsorption are relevant to many areas.</p><p>The main aim of this thesis has been to elucidate the adsorption properties, primarily on the solid/water interface, of a particular class of polyhydroxyl based surfactants: the alkyl glucosides. By the use of ellipsometry, the equilibrium and kinetic aspects of adsorption on titanium dioxide with respect to structural effects has been studied. Furthermore, the effects of small amounts of cationic surfactant additives on the adsorption on silica have been investigated. The results have been compared with similar studies for other nonionic surfactants.</p><p>We have found that the surfactant structure has a strong effect on the adsorption properties. An increase in the surfactant chain length increases the cooperativity of the system. An increase in the head group polymerization decreases the cooperativity and the plateau adsorbed amount at equilibrium. The effect of surfactant structure on the adsorption kinetics depends on the concentration relative to the cmc, while the there is a decrease in the rate of desorption with increasing hydrophobic chain length independent of the concentration. The adsorption/desorption process is concluded to be diffusion driven, as suggested by the model used. When comparing these results with studies on ethylene oxide based surfactants, we conclude that the two types of surfactants exhibit similar trends on surfaces onto which they adsorb.</p><p>Adsorption from binary surfactant solutions is even more interesting than adsorption from single surfactant solutions, since it brings us one step closer to the systems used in applications. In addition, adsorption from a mixture can be very different from adsorption from any of the single surfactants in the mixture. Alkyl glucosides alone do not adsorb on silica, but addition of small amounts of a cationic surfactant to the alkyl glucoside solution allows for adsorption on silica. A comparison between the adsorption and bulk properties has shown that mixed micellization explains most, but not all, effects of the coadsorption properties. Changing the pH in the mixed systems reveals that a surfactant with a pH-dependent charge and the ability to adapt its charge to the environment, e.g. a surface, enhances the adsorbed amount over a wider range of pH values than a purely cationic surfactant.</p><p>It is well known that alkyl glucosides and ethylene oxides adsorb differently on different types of hydrophilic surfaces. As a consequence, replacing ethylene oxides with alkyl glucosides might not be all straight-forward; however, we have shown that the effect of the surface can be eliminated by the use of a cosurfactant.</p> Physical chemistry surface chemistry adsorption surfactant nonionic alkyl glucoside (APG) ellipsometry kinetics alkyl amine oxide (DDAO) alkyl ammonium bromide (DTAB) solid/liquid interface synergism coadsorption. Surface and colloid chemistry Yt- och kolloidkemi
28	Adsorption of biopolymers and their layer-by-layer assemblies on hydrophilic surfaces Lundin, Maria January 2009 (has links) It is widely known that surfaces play an important role in numerous biological processes and technological applications. Thus, being able to modify surface properties provides an opportunity to control many phenomena occurring at interfaces. One way of controlling surface properties is to adsorb a polymer film onto the surface, for example through layer-by-layer (LbL) deposition of polyelectrolytes. This simple but versatile technique enables various polymers, proteins, colloidal particles etc. to be incorporated into the film, resulting in a multifunctional coating. Due to recent legislations and a consumer demand for more environmentally friendly products, we have chosen to use natural polymers (biopolymers) from renewable resources. The focus of this thesis has been on the adsorption of biopolymers and their layer-by-layer formation at solid-liquid interfaces; these processes have been studied by a wide range of techniques. The main method was the quartz crystal microbalance with dissipation monitoring (QCM-D), which measures the adsorbed mass, including trapped solvent and the viscoelastic properties of an adsorbed film. This technique was often complemented with an optical method, such as ellipsometry or dual polarization interferometry (DPI), which provided information about the “dry” polymer or protein adsorbed mass. From this combination, the solvent content and density of the layers was evaluated. In addition, the surface force apparatus (SFA), X-ray photoelectron spectroscopy (XPS), total internal reflection fluorescence (TIRF), and fluorescence resonance energy transfer (FRET) were utilized, providing further information about the film structure, chemical composition, and polymer inter-layer diffusion. Adsorption studies of the glycoprotein mucin, which has a key role in the mucousal function, showed that despite the net negative charge of mucin, it adsorbed on negatively charged substrates. The adsorbed layer was highly hydrated and the segment density on the substrate was low. We showed the importance of characterizing the mucin used, since differences in purity, such as the presence of albumin, gave rise to different adsorption behaviours in terms of both adsorbed amount and structure. The adsorbed mucin layer was to a large extent desorbed upon exposure to the anionic surfactant sodium dodecyl sulfate (SDS). In order to prevent desorption, we demonstrated that a protective layer of the cationic polysaccharide chitosan could be adsorbed onto the mucin layer and that the mucin-chitosan complexes resisted the desorption normally induced by association with SDS. Moreover, the association between chitosan and SDS was examined at the solid-liquid interface, in the bulk, and at the air-water interface. In all these environments chitosan-SDS complexes were formed and a net charge reversal of the complexes from positive to negative was observed when the concentration of SDS was increased. Furthermore, the LbL deposition method could be used to form a multilayer-like film by alternate adsorption of mucin and chitosan on silica substrates. The LbL technique was also applied to two proteins, lysozyme and β-casein with the aim of building a multilayer film consisting entirely of proteins. These proteins formed complexes at the solid-liquid interface, resulting in a proteinaceous layer, but the build-up was highly irregular with an increase in adsorbed amount per protein deposition cycle that was far less than a monolayer.Continuing with chitosan, known to have antibacterial properties we assembled multilayers with an anti-adhesive biopolymer, heparin, to evaluate the potential of this system as a coating for medical implants. Multilayers were assembled under various solution deposition conditions and the film structure and dynamics were studied in detail. The chitosan-heparin film was highly hydrated, in the range 60-80 wt-% depending on the deposition conditions. The adsorbed amount and thickness of the film increased exponential-like with the number of deposition steps, which was explained by inter-diffusion of chitosan molecules in the film during the build-up. In a novel approach, we used the distant dependent FRET technique to prove the inter-layer diffusion of fluorescent-labelled chitosan molecules within the film. The diffusion coefficient was insignificantly dependent on the deposition pH and ionic strength, and hence on the film structure. With the use of a pH sensitive dye buried under seven chitosan-heparin bilayers, we showed that the dye remained highly sensitive to the charge of the outermost layer. From complementary QCM-D data, we suggested that an increase in the energy dissipation does not necessarily indicate that the layer structure becomes less rigid. / Det är välkänt att ytor spelar en viktig roll i många biologiska processer och tekniska tillämpningar. Att kunna modifiera en ytas egenskaper ger därför en möjlighet att kunna kontrollera många fenomen som sker på ytor. Ett sätt att kontrollera ytegenskaperna är genom att adsorbera en polymerfilm på ytan, till exempel genom att växelvis adsorbera olika polyelektrolyter (LbL-teknik). Denna enkla men mångsidiga teknik möjliggör att många olika material kan införlivas i filmen, vilket resulterar i en multifunktionell beläggning. På grund av dagens lagstiftning och konsumenters ökade efterfrågan på miljövänliga material beslutade vi oss för att använda biologiska polymerer (biopolymerer) i detta projekt. Fokus i den här avhandlingen har varit på adsorption av biopolymerer och deras LbL-formation på gränsytan vätska-fast fas, där adsorptionsförloppet och det adsorberade skiktet bestående av biopolymerer studerats med en mängd olika tekniker. Huvudtekniken var kvartskristallmikrovåg med energidissipations-registrering (QCM-D), som mäter massan inklusive inkorporerat vatten, samt de viskoelastiska egenskaperna hos ett adsorberat skikt. Som komplement till denna teknik användes ofta optiska metoder, till exempel ellipsometri och ”dubbel polarisationsinterferometri (DPI)”, två tekniker som endast mäter massan av de adsorberade biopolymererna. Genom denna kombination av metoder kunde massan av inkorporerat vatten i filmen och filmens densitet bestämmas. Dessutom användes ytkraftsapparaten (SFA), röntgenfotoelektronspektrometri (XPS), och fluorescens-spektroskopiteknikerna TIRF och FRET i några undersökningar för att erhålla information om skiktens struktur, kemiska sammansättning och polymerernas diffusion inom skiktet.Adsorptionsstudier av glycoproteinet mucin, som har en central roll i funktionen av slemhinnan, avslöjade att trots att mucinet har en negativ nettoladdning adsorberade det ändå på negativt laddade substrat. Det adsorberade lagret var väldigt hydratiserat och hade en låg andel mucin i direkt kontakt med ytan. Vi påvisade vikten av att noga undersöka mucinet som användes, eftersom olika renhet, till exempel i form av förekomsten av albumin gav upphov till olika adsorptionsbeteende gällande både adsorberad mängd och struktur. En stor andel av det adsorberade mucinlagret desorberade när det exponerades för den anjoniska tensiden natriumdodecylsulfat, SDS. Vi visade att ett skyddande lager av den katjoniska polysackariden chitosan kunde adsorberas på mucinet och att mucin-chitosan-komplexen inte desorberade när SDS tillsattes. Därtill studerades växelverkan mellan chitosan och SDS på gränsytan vätska-fast fas, i bulken och på luft-vattengränsytan. Komplex av chitosan-SDS bildades i samtliga miljöer och en nettoladdningsomsvängning från positiv till negativ observerades när koncentrationen av SDS ökades.Vidare kunde LbL-tekniken nyttjas för att skapa ett multilagerlikt skikt genom att alternerande adsorbera mucin och chitosan på kiseldioxidsubstrat. Denna teknik användes även med två proteiner, lysozym och β-kasein, med målet att skapa ett multilager bestående av endast proteiner. Dessa proteiner bildade komplex på gränsytan vätska-fast fas i form av ett blandat proteinlager, men uppbyggnaden var väldigt oregelbunden med en ökning i adsorberad mängd per proteindeponeringscykel som var avsevärt mindre än ett monolager.Inom området för biomaterial utgör de antibakteriella och antihäftande egenskaperna hos chitosan respektive heparin en lovande blandning för beläggningar av medicinska implantat. Baserat på detta konstruerade vi multilagerfilmer av chitosan och heparin med olika deponeringslösningar och undersökte dynamiken och filmens struktur i detalj. Chitosan-heparin-filmen var starkt hydratiserad, bestående av cirka 60-80 vikt-% vatten beroende på deponeringsbetingelserna. Den adsorberade mängden och tjockleken på filmen ökade nästan exponentiellt med antal deponeringar, vilket förklarades med chitosanets förmåga att diffundera genom filmen under uppbyggnaden. Med ett nytt angreppssätt använde vi FRET för att bevisa diffusionen av fluorescerande färgmärkt chitosan i filmen under uppbyggnaden. Diffusionskoefficienten var i princip oberoende av pH och jonstyrka under deponeringen och följaktligen av filmens struktur. Genom att använda ett pH-känsligt färgämne begravt under sju biskikt av chitosan-heparin visade vi att färgämnet i hög grad påverkades av laddningen på det yttersta lagret. Från QCM-D-data lade vi fram teorin om att en ökning av energidissipationen för ett lager inte nödvändigtvis indikerar att lagrets struktur har blivit mindre styvt. / QC 20100729 Layer-by-layer multilayer adsorption biopolymers Chitosan Heparin Mucin Albumin Lysozyme β-casein SDS QCM-D Ellipsometri DPI TIRF FRET SFA layer structure solvent content vertical diffusion exponential growth solid-liquid interface deposition conditions Surface and colloid chemistry Yt- och kolloidkemi
29	Interfacial Phenomena at the Graphene-Liquid-Interface in Nanostructure Devices: Faradaic Effect, Edge-Gating and Van Der Waals Heterostructures Neubert, Tilmann Joachim 03 February 2022 (has links) In dieser Arbeit werden verschiedene Aspekte des Designs und der Funktionsweise von in Flüssigkeit betriebenen Graphen-basierten Sensoren untersucht, wodurch neue Einblicke in grundlegende Prozesse an der Graphen-Flüssigkeits-Grenzfläche gewonnen werden. Zunächst wird die Wirkung redoxaktiver Moleküle in der Elektrolytlösung in elektrochemisch gesteuerten Graphen-FETs untersucht. Während des Betriebs kann ein heterogener Elektronentransfer stattfinden, der zu Faradayschen Strömen am Graphenkanal führt. Diese führen zu Verschiebungen der Transferkurve von Graphen, da die Graphen-Flüssigkeits-Grenzfläche eine nur teilweise polarisierbare Elektrode darstellt. Dies wird als „Faradayscher Effekt“ bezeichnet. Er unterscheidet sich grundlegend von typischen Transduktionsmechanismen. Parameter, die den Faradayschen Effekts beeinflussen, werden detailliert untersucht. So sind die Verschiebungen z.B. abhängig von der Graphenkanalfläche. Der zweite Abschnitt konzentriert sich auf die Kante von Graphen, die einen nanoskopischen eindimensionalen Defekt des zweidimensionalen Materials darstellt. In dieser Arbeit wird ein neuer Graphen-FET vorgestellt, der auf der Steuerung von Graphen nur über die elektrochemische Doppelschicht an der Kante basiert. Um dies zu erreichen, wird der basale Teil des Graphens durch eine Passivierung vollständig von der Elektrolytlösung abgeschirmt. Des Weiteren wird gezeigt, dass die Kante des Graphens durch elektrochemische Modifizierung kovalent funktionalisiert werden kann, wodurch die Ladungsdichte an der Graphenkanten-Flüssigkeits-Grenzfläche effektiv verändert wird. Dabei bleiben die vorteilhaften Eigenschaften der Devices erhalten. Schließlich wird ein neuartiger Ansatz zu Untersuchungen an der Graphenkante in Form von mit hexagonalem Bornitrid-verkapseltem Graphen-Elektroden verfolgt. Die elektroanalytische Detektion von Ferrocenmethanol und Dopamin an der Graphenkante mittels zyklischer Voltammetrie wird an diesen Elektroden gezeigt. / Several aspects of the design and function of sensors based on graphene operated in liquid have been investigated in this thesis, providing new insight into fundamental processes at the graphene-liquid-interface. First, the effect of the presence of redox active molecules in the analyte solution of electrochemically gated graphene FETs is explored. During operation, heterogeneous electron transfer may occur at relevant potentials leading to Faradaic currents at the graphene channel. These lead to doping-like shifts of the transfer curve of graphene, as the graphene-liquid-interface represents a partially polarizable electrode. Due to the origin of the shifts, this observation is termed “Faradaic effect”. It is fundamentally different from typically discussed transduction mechanisms. Parameters influencing the direction and magnitude of the Faradaic effect are discussed in detail, e.g. the shifts are the stronger, the larger the area of the graphene channel. The second part focuses on the edge of graphene, which represents a nanoscopic one-dimensional defect of the two-dimensional material. Here, a new type of graphene FET is introduced based on electrochemical gating of graphene exclusively via the electrical double layer at its edge. To achieve edge-gating, the basal part of graphene is passivated by a photoresist and shielded entirely from interaction with the solution. It is demonstrated that the edge of graphene can be functionalized covalently via electrografting. This changes the charge density at the graphene edge-liquid-interface effectively, while maintaining the favorable transfer characteristics of the devices. Finally, a novel approach towards graphene edge devices was pursued in the form of hexagonal boron nitride encapsulated graphene. The electrochemical detection of ferrocene methanol and dopamine was demonstrated in standard and fastscan cyclic voltammetry at the edge of graphene in these devices. Graphen Feldeffektransistor Fest-Flüssig-Grenzflächen Graphenkante Elektroanalytik Graphene field-effect transistor solid-liquid interface graphene edge electroanalysis 543 Analytische Chemie VK 7720 VG 8007 VG 6847 VE 7007 ddc:543
30	The rate-limiting mechanism for the heterogeneous burning of iron in normal gravity and reduced gravity Ward, Nicholas Rhys January 2007 (has links) This thesis presents a research project in the field of oxygen system fire safety relating to the heterogeneous burning of iron in normal gravity and reduced gravity. Fires involving metallic components in oxygen systems often occur, with devastating and costly results, motivating continued research to improve the safety of these devices through a better understanding of the burning phenomena. Metallic materials typically burn in the liquid phase, referred to as heterogeneous burning. A review of the literature indicates that there is a need to improve the overall understanding of heterogeneous burning and better understand the factors that influence metal flammability in normal gravity and reduced gravity. Melting rates for metals burning in reduced gravity have been shown to be higher than those observed under similar conditions in normal gravity, indicating that there is a need for further insight into heterogeneous burning, especially in regard to the rate-limiting mechanism. The objective of the current research is to determine the cause of the higher melting rates observed for metals burning in reduced gravity to (a) identify the rate-limiting mechanism during heterogeneous burning and thus contribute to an improved fundamental understanding of the system, and (b) contribute to improved oxygen system fire safety for both ground-based and space-based applications. In support of the work, a 2-s duration ground-based drop tower reduced-gravity facility was commissioned and a reduced-gravity metals combustion test system was designed, constructed, commissioned and utilised. These experimental systems were used to conduct tests involving burning 3.2-mm diameter cylindrical iron rods in high-pressure oxygen in normal gravity and reduced gravity. Experimental results demonstrate that at the onset of reduced gravity, the burning liquid droplet rapidly attains a spherical shape and engulfs the solid rod, and that this is associated with a rapid increase in the observed melting rate. This link between the geometry of the solid/liquid interface and melting rate during heterogeneous burning is of particular interest in the current research. Heat transfer analysis was performed and shows that a proportional relationship exists between the surface area of the solid/liquid interface and the observed melting rate. This is confirmed through detailed microanalysis of quenched samples that shows excellent agreement between the proportional change in interfacial surface area and the observed melting rate. Thus, it is concluded that the increased melting rates observed for metals burning in reduced gravity are due to altered interfacial geometry, which increases the contact area for heat transfer between the liquid and solid phases. This leads to the conclusion that heat transfer across the solid/liquid interface is the rate-limiting mechanism for melting and burning, limited by the interfacial surface area. This is a fundamental result that applies in normal gravity and reduced gravity and clarifies that oxygen availability, as postulated in the literature, is not rate limiting. It is also established that, except for geometric changes at the solid/liquid interface, the heterogeneous burning phenomenon is the same at each gravity level. A conceptual framework for understanding and discussing the many factors that influence heterogeneous burning is proposed, which is relevant to the study of burning metals and to oxygen system fire safety in both normal-gravity and reduced-gravity applications. metal combustion microgravity reduced gravity normal gravity oxygen fire safety metal flammability burning iron heterogeneous burning cylindrical rod heat transfer model rate-limiting mechanism rate-limiting step solid/liquid interface melting interface regression rate of the melting interface melting rate surface tension microanalysis test methods drop tower

Search results