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Showing 361 to 370 of 381 (0.1 seconds)Spelling suggestions: "subject:"burface codification"" "subject:"burface amodification""
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Optical Anisotropy and Molecular Orientation of CuPc Films and Optical Properties of Ultra-thin High-k FilmsDing, Li 15 October 2012 (has links) (PDF)
In the thesis CuPc thin films were investigated by (in situ) SE and RAS, which are employed to determine the out-of-plane and in-plane optical anisotropy and molecular orientation, respectively. CuPc is a promising candidate of organic semiconductors used in organic field effect transistors, organic light emitting diodes and organic solar cells. Vicinal Si(111) substrates are interesting due to the in-plane anisotropy caused by the steps and terraces on the surface. The strength of in-plane anisotropy of vicinal Si(111) is dependent on the offcut angle. The influence of offcut angle on out-of-plane and in-plane molecular orientation in CuPc thin films is explored. The in situ investigation of CuPc films suggests that structural changes occur during film growth. In addition, two different surface modification layers were utilized to examine the effect on CuPc molecular orientation: OTS monolayer with upright standing molecules and PTCDA layers with flat lying molecules. Metal-organic interface plays an important role in organic electronic devices. In-CuPc is chosen to be an example system investigated employing in situ SE and RAS. When In was thermally evaporated onto CuPc film, In atoms firstly diffuse into the CuPc film underneath and then aggregate to form clusters on top.
Hafnium dioxide (HfO2) is currently a hot topic to replace the conventionally used SiO2 as gate dielectrics in order to minimize leakage current when further scaling down microelectronic devices. Since HfO2 films are often crystalline, in order to obtain amorphous films which are beneficial to minimize leakage current, aluminum oxide (Al2O3) (k value: 9) which stays amorphous at much higher temperatures are combined to overcome this difficulty. Two series of ultra-thin samples were deposited by atomic layer deposition: mixed layers HfxAl1-xOz and bilayers HfO2 on Al2O3. Optical constants and bandgap are determined using SE in the energy range of 0.7-10 eV. It is found that the (effective) optical bandgap of both mixed layer and bilayer structures can be tuned by the film composition. Aging effect of high-k films was observed after storage of samples in air for two months, which is attributed to further oxidation of the dielectric films caused by the oxygen diffusion from ambient air to high-k films. / In dieser Arbeit werden dünne Schichten aus Kupferphthalozyanin (CuPc) mittels spektroskopischer (in-situ) Ellipsometrie (SE) und (in-situ) Reflektions-Anisotropie-Spektroskopie (RAS) untersucht, um die optische Anisotropie in einer Ebene parallel und senkrecht zur Schichtoberfläche und die molekulare Orientierung zu bestimmen. CuPc ist ein aussichtsreicher Kandidat als organischer Halbleiter in organischen Feldeffekt-Transistoren, organischen Leuchtdioden und organischen Solarzellen. Vizinale Si(111)-Substrate sind wegen der Anisotropie in der Substratebene interessant, die durch die Treppen und Terrassen auf der Oberfläche verursacht wird. Die Stärke der Anisotropie der vizinalen Si(111)-Oberfläche ist vom Schnittwinkel (Offcut) abhängig. Es wird der Einfluss des Offcut-Winkels auf die molekulare Orientierung in dünnen CuPc-Schichten parallel und senkrecht zur Substratoberfläche untersucht. Die in-situ Untersuchungen von CuPc-Schichten weisen darauf hin, dass strukturelle Veränderungen beim Wachstum auftreten. Darüber hinaus wurden zwei unterschiedliche Oberflächenmodifizierungsschichten, um deren Wirkung auf die molekulare Orientierung von CuPc zu untersuchen, verwendet: eine OTS-Monoschicht mit aufrecht stehenden Molekülen und PTCDA-Schichten mit flach liegenden Molekülen. Metall-organische Grenzflächen spielen eine wichtige Rolle in organischen elektronischen Bauelementen. In-CuPc wird als Beispiel für ein Metall-organisches System durch in-situ SE und RAS untersucht. Wenn In thermisch auf eine CuPc-Schicht aufgedampft wird, diffundieren In-Atome zunächst in die darunterliegende CuPc-Schicht und bilden dann Cluster auf der Schicht.
Hafniumdioxid (HfO2) ist ein heißer Kandidat für das Ersetzen des herkömmlich als Gate-Dielektrikum verwendeten SiO2 mit dem Ziel, die Leckströme bei der weiteren Verkleinerung mikroelektronischer Bauelemente zu minimieren. Um amorphe Schichten, die vorteilhaft zur Minimierung der Leckströme sind, zu erhalten, werden die HfO2-Schichten, die oft kristallin sind, mit Aluminiumoxid (Al2O3) (k-Wert: 9) kombiniert, das bei wesentlich höheren Temperaturen amorph bleibt. Zwei Serien von ultra-dünnen Proben wurden durch Atomlagenabscheidung hergestellt: Mischschichten HfxAl1-xOz und Doppelschichten HfO2 auf Al2O3. Die optischen Konstanten und Bandlücken wurden mittels SE im Energiebereich von 0,7 bis 10 eV bestimmt. Es hat sich gezeigt, dass die (effektive) Bandlücke der Misch- und Doppelschichten durch die Komposition abgestimmt werden kann. Nach Lagerung der High-k-Schichten für zwei Monate an Luft konnte ein Alterungseffekt beobachtet werden. Dieser wird auf die weitere Oxidation der dielektrischen Schichten, die durch Sauerstoffdiffusion aus der Umgebungsluft in die High-k-Schichten ermöglicht wird, zurückgeführt.
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Design and development of biomimetic surfaces and three-dimensional environments to study cell behaviorMarí Buyé, Núria 11 May 2012 (has links)
La biomimètica o biomimetisme són termes que simbolitzen el concepte “aprendre de la naturalesa”, és a dir, aprendre dels seus sistemes, processos i models, a fi d’utilitzar la natura com a font d’inspiració per solucionar problemes de l’home. El biomimetisme és actualment un concepte recurrent en l’àrea d’enginyeria de teixits i d’ell en sorgeixen idees per obtenir plataformes més elegants i sofisticades que puguin imitar millor les interacciones entre les cèl•lules i el seu ambient. Aquesta tesi pretén desenvolupar models, en dues i en tres dimensions, mitjançant la recreació d’un o més factors característics de l’ambient natural de la cèl•lula i que juguen un paper important en el comportament cel•lular.
Se sap que tant les propietats químiques com les mecàniques de la matriu extracel•lular influeixen sobre les funcions cel•lulars. És per això que es va dissenyar un nou film polimèric que pogués combinar un hidrogel, amb propietats mecàniques variables, amb un monòmer reactiu capaç d’immobilitzar biomolècules. Degut a la complexitat del polímer dissenyat, va ser necessari recórrer a una tècnica de polimerització superficial molt versàtil com és la deposició química iniciada en fase vapor (més coneguda pel seu acrònim en anglès iCVD). Els polímers varen ser àmpliament caracteritzats i es va corroborar que podien ser modificats amb petites biomolècules com ara pèptids senyalitzadors. Les superfícies resultants són bioactives i permeten l’adhesió de cèl•lules endotelials.
Unes altres superfícies biomimètiques, rellevants en l’àmbit de l’enginyeria de teixits d’os, es varen obtenir a partir d’una hidroxiapatita sintetitzada pel mètode de sol-gel submergint-la en diferents medis fisiològics. La dissolució i posterior reprecipitació dels ions proporcionen una capa d’apatita amb una composició similar a la que es troba in vivo. Els experiments evidencien la importància de partir d’un material relativament soluble. És per això que la hidroxiapatita pura no és capaç d’induir la precipitació d’aquesta apatita biomimètica in vitro. Diversos investigadors han relacionat la capacitat de formar apatita amb la bioactivitat del material, entenent bioactivitat com l’habilitat d’aquests materials de promoure la unió amb l’os.
Per a l’enginyeria de teixits, però, és necessari un ambient tridimensional per tal de generar un teixit artificial. S’ha desenvolupat un nou model basat en l’ús d’un gel molt tou per tal d’obtenir un teixit dur com el de l’os. Malgrat que aquests dos conceptes poden semblar contradictoris, les cèl•lules adquireixen l’habilitat d’allargar-se ràpidament i crear una densa xarxa cel•lular dins d’aquest ambient poc restrictiu des d’un punt de vista mecànic. La consegüent contracció del sistema acaba formant un constructe més petit i resistent. Aquest és un sistema biomimètic ja que promou una gran interacció cel•lular i també la condensació de les cèl•lules, esdeveniments que tenen lloc també durant el desenvolupament de l’os i el cartílag. El model es va caracteritzar extensament amb cèl•lules ostoprogenitores MC3T3-E1 que es diferenciaren amb inducció química. A més a més, es va demostrar que l’ambient tridimensional podia promoure l’expressió espontània de marcadors osteogènics. Degut a les interessants propietats del sistema, el mateix model es va utilitzar per induir la diferenciació condrogènica de fibroblastos dermals humans. Aquests tipus cel•lular no ha estat gaire explorat en l’àmbit de l’enginyeria de teixits, malgrat que ofereix un gran potencial en teràpia regenerativa. Aquest treball proporciona proves de la capacitat condrogènica d’aquestes cèl•lules en el sistema tridimensional prèviament desenvolupat. / La biomimètica o biomimetismo son términos que simbolizan el concepto “aprender de la naturaleza”, es decir, aprender de sus sistemas, procesos y modelos, y utilizarlos como fuente de inspiración para solucionar problemas del hombre. El biomimetismo es actualmente un concepto recurrente en el área de ingeniería de tejidos y de este surgen ideas para obtener plataformas más elegantes y sofisticadas que puedan mimetizar mejor las interacciones entre las células y su ambiente. La presente tesis se centra en desarrollar modelos, tanto en dos como en tres dimensiones, mediante la recreación de uno o más factores que caracterizan el ambiente natural de la célula y que tienen su rol importante en el comportamiento celular.
Se conoce que tanto las propiedades químicas como mecánicas de la matriz extracelular influyen en las funciones celulares. Debido a esto, se diseñó un nuevo film polimérico que pudiera combinar un hidrogel, con propiedades mecánicas variables, con un monómero reactivo, capaz de inmovilizar biomoléculas. Debido a la complejidad del polímero diseñado, fue necesario recurrir a una técnica de polimerización superficial muy versátil como es la deposición química iniciada en fase vapor (más conocida por su acrónimo en inglés iCVD). Los polímeros fueron ampliamente caracterizados y se corroboró que podían ser modificados con pequeñas biomoléculas como péptidos señalizadores. Las superficies resultantes son bioactivas y permiten la adhesión de células endoteliales.
Se obtuvieron otro tipo de superficies biomiméticas relevantes en el ámbito de la ingeniería de tejidos de hueso, a partir de una hidroxiapatita sintetizada por el método sol-gel sumergiéndolas en diferentes medios fisiológicos. La disolución y posterior reprecipitación de los iones proporcionan una capa de apatita con una composición similar a la que se encuentra in vivo. Los experimentos evidencian la importancia de partir de un material relativamente soluble. Precisamente debido a esto la hidroxiapatita pura no es capaz de inducir la precipitación de esta apatita biomimética in vitro. Varios investigadores han relacionado la capacidad de formar apatita con la bioactividad del material, entendiendo bioactividad como la habilidad de estos materiales de promover la unión con el hueso.
De todos modos, en ingeniería de tejidos, es necesario un ambiente tridimensional para generar un tejido artificial. Se ha desarrollado un nuevo modelo basado en el uso de un gel blando para obtener tejido duro como el del hueso. Aunque estos conceptos pueden parecer contradictorios, las células adquieren la habilidad de estirarse rápidamente y de formar una densa red celular dentro de este gel tan poco restrictivo desde un punto de vista mecánico. La consiguiente contracción del sistema acaba formando un constructo mucho más pequeño y resistente. Este es un sistema biomimético ya que promueve una gran interacción celular y también la condensación de las células, eventos que también ocurren durante el desarrollo de hueso y cartílago. El modelo se caracterizó extensamente con células osteoprogenitoras MC3T3-E1 que se diferenciaron bajo inducción química. Además, se demostró que el microambiente tridimensional podía promover la expresión espontánea de marcadores osteogénicos. Debido a las interesantes propiedades del sistema, el mismo modelo se usó para inducir la diferenciación condrogénica de fibroblastos dermales humanos. Este tipo celular no ha sido demasiado explorado en ingeniería de tejidos, a pesar de que puede tener un gran potencial en terapia regenerativa. Este trabajo proporciona pruebas de la capacidad condrogénica de estas células en el sistema tridimensional previamente desarrollado. / Biomimetics or biomimicry are terms that imply “learning from nature”, from its systems, processes and models, in order to use nature as inspiration to solve human problems. In tissue engineering, biomimetics is nowadays a recurrent term and a source of ideas to obtain more elegant and sophisticated platforms that could better mimic the interactions between cells and their environment. This thesis is focused on developing models both in two- and three-dimensions by recreation of one or more factors of the cell natural environment that are known to play an important role in cell behavior.
Since both the chemical and mechanical properties of the extracellular matrix are known to effectively influence cell function, an innovative polymeric thin film was designed combining a hydrogel with tunable mechanical properties and a reactive molecule, capable to immobilize biomolecules. Due to the complexity of the polymers, a versatile technique such as initiated chemical vapor deposition (iCVD) was required for the synthesis. Extensive characterization revealed that nanostructured hydrogels were obtained and that small biomolecules, such as signaling peptides, could be attached on the surface. The final surfaces are bioactive and support endothelial cell attachment.
Relevant biomimetic surfaces for bone tissue engineering could also be obtained from a sol-gel synthesized hydroxyapatite after immersion in different physiological media. The dissolution and posterior reprecipitation of the ions rendered a final apatite layer with a composition similar to that found in vivo. The experiments evidenced the importance of starting from a rather soluble material and, thus, pure hydroxyapatite was not able to promote apatite precipitation in vitro. This capacity has been related to the material bioactivity by many researchers in terms of its ability to bond to bone in tissue engineering applications.
However, for tissue engineering a three-dimensional environment is required to build tissue-like constructs. A new model was developed based on the use of a very soft gel to obtain hard tissue. Although the concepts might seem to work in opposite directions, cells gain the ability to rapidly elongate and form a dense cellular network within this unrestrictive environment. Subsequent contraction of the whole system rendered a smaller and stronger final tissue-like construct. This system was considered biomimetic as it promotes high cell-cell interaction and cellular condensation, which are events that occur in bone and cartilage development. This system was extensively characterized with osteoprogenitor MC3T3-E1 cells that could undergo full osteogenic differentiation under chemical induction. More interestingly, the three-dimensional microenvironment was also able to promote by itself spontaneous expression of bone-related markers. Due to the interesting properties of this system, the same model was used to induce chondrogenic differentiation of human dermal fibroblasts. This cell type has been poorly explored for tissue engineering applications, but it might have great potential in future therapeutic platforms. This work provides proof of concept of chondrogenic potential of these cells in this three-dimensional system.
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Single-Step Covalent Functionalization of Polylactide Surfaces / Nano Patterened Covalent Surface Modification of Poly(ε-caprolactone)Källrot, Martina January 2005 (has links)
<p>Degradable polymers have gained an increased attention in the field of biomedical applications over the past decades, for example in tissue engineering. One way of improving the biocompatibility of these polymers is by chemical surface modification, however the risk of degradation during the modification procedure is a limiting factor. In some biomedical applications, for example in nerve guides, a patterned surface is desired to improve the cell attachment and proliferation.</p><p>In this thesis a new non-destructive, single-step, and solvent free method for surface modification of degradable polymers is described. Poly(L-lactide) (PLLA) substrates have been functionalized with one of the following vinyl monomers; N-vinylpyrrolidone (VP), acrylamide (AAm), or maleic anhydride (MAH) grafts. The substrates were subjected to a vapor phase atmosphere constituted of a mixture of a vinyl monomer and a photoinitiator (benzophenone) in a closed chamber at very low pressure and under UV irradiation. Poly(ε-caprolactone) (PCL), poly(lactide-co-glycolide) (PLGA), and poly(trimethylene carbonate) (PTMC) have been surface modified with VP using the same procedure to show the versatility of the method. The wettability of all of the four substrates increased after grafting. The surface compositions were confirmed by ATR-FTIR and XPS. The VP grafted PLLA, PTMC and PLGA substrates have been shown to be good substrates for the normal human cells i.e. keratinocytes and fibroblasts, to adhere and proliferate on. The topography of substrates with well defined nano patterns was preserved during grafting, since the grafted layer is very thin. We have also shown that the method is useful for a simultaneous chemical and topographical modification of substrates by masked vapor phase grafting. The surface topography was determined with SEM and AFM.</p> / <p>Intresset för användningen av nedbrytbara polymerer till biomedicinska applikationer som till exempel vävnads rekonstruktion har ökat avsevärt de senaste decennierna. Ett sätt att öka biokompatibiliteten hos dessa polymerer är genom kemisk ytmodifiering, men risken för nedbrytning under själva modifieringen är en begränsande faktor. I vissa biomedicinska applikationer, till exempel nervguider, är det önskvärt att ha en väldefinierad ytstruktur för att öka vidhäftningen och tillväxten av celler.</p><p>I den här avhandlingen presenteras en ny ickeförstörande, lösningsmedelsfri enstegsprocess för ytmodifiering av nedbrytbara polymerer. Substrat av poly(L-laktid) (PLLA) har ytfunktionaliserats med var och en av följande vinylmonomerer, N-vinylpyrrolidon (VP), akrylamid (AAm) eller maleinsyraanhydrid (MAH). Substraten har exponerats för en gasfasatmosfär av en blandning av en vinylmonomer och en fotoinitiator (bensofenon) i en tillsluten reaktor vid mycket lågt tryck och under UV-strålning. Metodens mångsidighet har även påvisats genom att ytmodifiera substrat av poly(ε-kaprolakton) (PCL), poly(laktid-co-glykolid) (PLGA) och poly(trimetylen karbonat) (PTMC) med VP. Vätbarheten ökade för alla fyra materialen efter ympning med en vinylmonomer. Ytsammansättningen fastställdes med ATR-FTIR och XPS. De VP ympade filmerna av PLLA, PLGA och PTMC visade sig vara bra substrat för mänskliga celler, i detta fall keratinocyter och fibroblaster, att vidhäfta och växa på. Yttopografin hos filmer med väldefinierade nanomönstrade ytor kunde bevaras efter ympning, tack vare att det ympade lagret är så tunt. Gasfas metoden har också visat sig användbar för att simultant ytmodifiera både kemiskt och topografiskt genom maskad gasfasympning. Yttopografin bestämdes med SEM och AFM.</p>
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From Macro to Nano : Electrokinetic Transport and Surface ControlPardon, Gaspard January 2014 (has links)
Today, the growing and aging population, and the rise of new global threats on human health puts an increasing demand on the healthcare system and calls for preventive actions. To make existing medical treatments more efficient and widely accessible and to prevent the emergence of new threats such as drug-resistant bacteria, improved diagnostic technologies are needed. Potential solutions to address these medical challenges could come from the development of novel lab-on-chip (LoC) for point-of-care (PoC) diagnostics. At the same time, the increasing demand for sustainable energy calls for the development of novel approaches for energy conversion and storage systems (ECS), to which micro- and nanotechnologies could also contribute. This thesis has for objective to contribute to these developments and presents the results of interdisciplinary research at the crossing of three disciplines of physics and engineering: electrokinetic transport in fluids, manufacturing of micro- and nanofluidic systems, and surface control and modification. By combining knowledge from each of these disciplines, novel solutions and functionalities were developed at the macro-, micro- and nanoscale, towards applications in PoC diagnostics and ECS systems. At the macroscale, electrokinetic transport was applied to the development of a novel PoC sampler for the efficient capture of exhaled breath aerosol onto a microfluidic platform. At the microscale, several methods for polymer micromanufacturing and surface modification were developed. Using direct photolithography in off-stoichiometry thiol-ene (OSTE) polymers, a novel manufacturing method for mold-free rapid prototyping of microfluidic devices was developed. An investigation of the photolithography of OSTE polymers revealed that a novel photopatterning mechanism arises from the off-stoichiometric polymer formulation. Using photografting on OSTE surfaces, a novel surface modification method was developed for the photopatterning of the surface energy. Finally, a novel method was developed for single-step microstructuring and micropatterning of surface energy, using a molecular self-alignment process resulting in spontaneous mimicking, in the replica, of the surface energy of the mold. At the nanoscale, several solutions for the study of electrokinetic transport toward selective biofiltration and energy conversion were developed. A novel, comprehensive model was developed for electrostatic gating of the electrokinetic transport in nanofluidics. A novel method for the manufacturing of electrostatically-gated nanofluidic membranes was developed, using atomic layer deposition (ALD) in deep anodic alumina oxide (AAO) nanopores. Finally, a preliminary investigation of the nanopatterning of OSTE polymers was performed for the manufacturing of polymer nanofluidic devices. / <p>QC 20140509</p> / Rappid / NanoGate / Norosensor
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Influence of Chemical Coating on Droplet Impact DynamicsGupta, Rahul January 2016 (has links) (PDF)
Dynamic behavior of impacting water drops on superhydrophobic solid surfaces provides important details on the stability/durability of such solid surfaces. Multi-scale surface roughness combined with a layer of low energy chemical is an essential surface modification process followed to create superhydrophobic capabilities on solid surfaces. The present work aims at studying the effect of low energy surface coating on droplet impact dynamics by carrying out experiments of water drop impacts on rough solid surfaces with and without chemical modification. A group of six aluminium alloy (Al6061) surfaces (three pairs) are prepared. Roughness, characterized in terms mean surface roughness, Ra, is introduced to these metallic surfaces using sand-paper polishing, electric discharge machining (EDM), and chemical based surface etching process. Low energy surface layer is laid on the rough surfaces by coating NeverWet hydrophobic solution, octadecyl-trichloro-silane (OTS), and perfluorodecyltricholorosilane (FAS-17). The impact dynamics of water drops is analyzed by capturing high speed videos for a range of drop Weber number from 1 to 570 and the salient features of drop impact process on the coated rough surfaces are compared with the corresponding uncoated rough surfaces. A one-to-one comparison on the spreading, fingering, receding, and final equilibrium of impacting drops on the coated and uncoated target surfaces is presented.
Upon coating NeverWet, the original surface features of the base aluminium surface are completely covered by the hydrophobic coating material resulting in a fresh top surface layer. The outcomes as well as the bounce-off characteristics of impacting water drops on the coated surface are comparable to those observed on lotus leaf. The surface morphology features of rough aluminium surfaces coated with OTS and FAS-17 are comparable to those of the corresponding uncoated surfaces. The quantitative measurements on primary spreading and maximum spread factor of impacting drops are largely unaffected by the presence of low energy chemical coating. The dominant effect of surface coating is seen on the receding of impacting drops and hence the final drop configuration. This behavior is more prominently seen on EDM fabricated rough surface (larger Ra) combined with OTS coating than that on etching based rough surface (smaller Ra) combined with FAS-17 coating highlighting the dependence of coating effect with roughness features.
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Thiol-ene and Thiol-ene-epoxy Based Polymers for Biomedical MicrodevicesVastesson, Alexander January 2017 (has links)
Within healthcare there is a market pull for biomedical devices that can rapidly perform laboratory processes, such as diagnostic testing, in a hand-held format. For this reason, biomedical devices must become smaller, more sophisticated, and easier to use for a reasonable cost. However, despite the accelerating academic research on biomedical microdevices, and especially plastic-based microfluidic chips, there is still a gap between the inventions in academia and their benefit to society. To bridge this gap there is a need for new materials which both exhibit similar properties as industrial thermoplastics, and that enable rapid prototyping in academia. In this thesis, thiol-ene and thiol-ene-epoxy thermosets are evaluated both in terms of their suitability for rapid prototyping of biomedical microdevices and their potential for industrial manufacturing of “lab-on-chips”. The first part of the thesis focuses on material development of thiol-ene and thiol-ene-epoxy thermosets. Chemical and mechanical properties are studied, as well as in vitro biocompatibility with cells. The second part of the thesis focuses on microfabrication methods for both thermosets. This includes reaction injection molding, photostructuring, and surface modification. It is demonstrated how thiol-ene and thiol-ene-epoxy both provide advantageous thermo-mechanical properties and versatile surface modifications via “thiol-click chemistry”. In the end of the thesis, two applications for both polymer platforms are demonstrated. Firstly, thiol-ene is used for constructing nanoliter well arrays for liquid storage and on-demand electrochemical release. Secondly, thiol-ene-epoxy is used to enhance the biocompatibility of neural probes by tuning their flexibility. It is concluded that both thiol-ene and thiol-ene-epoxy thermosets exhibit several properties that are highly suitable for rapid prototyping as well as for scalable manufacturing of biomedical microdevices. / <p>QC 20171003</p>
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Plasma Surface Engineering - Studies On Nitride Coatings And Surface Modification Of PolymersGuruvenket, S 10 1900 (has links) (PDF)
No description available.
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Transportní, šumové a strukturální vlastnosti detektorů vysokoenergetického záření na bázi CdTe / Noise, Transport and Structural Properties of High Energy Radiation Detectors Based on CdTeŠik, Ondřej January 2016 (has links)
Poptávka ze strany vesmírného výzkumu, zdravotnictví a bezpečnostního průmyslu způsobila v posledních letech zvýšený zájem o vývoj materiálů pro detekci a zobrazování vysokoenergetického záření. CdTe a jeho slitina CdZnTe. jsou polovodiče umožnují detekci záření o energiích v rozsahu 10 keV až 500 keV. Šířka zakázaného pásma u CdTe / CdZnTe je 1.46 -1.6 eV, což umožňuje produkci krystalů o vysoké rezistivitě (10^10-10^11 cm), která je dostačující pro použití CdTe / CdZnTe při pokojové teplotě. V mé práci byly zkoumány detektory CdTe/CdZnTe v různých stádiích jejich poruchovosti. Byly použity velmi kvalitní spektroskopické detektory, materiál s nižší rezistivitou a výraznou polarizací, detektory s asymetrií elektrických parametrů kontaktů a teplotně degenerované vzorky. Z výsledků analýzy nízkofrekvenčního šumu je patrný obecný závěr, že zvýšená koncentrace defektů způsobí změnu povahy původně monotónního spektra typu 1/f na spektrum s výrazným vlivem generačně-rekombinačních procesů. Další výrazná vlastnost degenerovaných detektorů a detektorů nižší kvality je nárůst spektrální hustoty šumu typu 1/f se vzrůstajícím napájecím napětí se směrnicí výrazně vyšší než 2. Strukturální a chemické analýzy poukázaly, že teplotní generace detektorů způsobuje difuzi kovu použitého při kontaktování a stopových prvků hlouběji do objemu krystalu. Část mé práce je věnována modifikaci povrchu svazkem argonových iontů a jejímu vlivu na chemické složení a morfologii povrchu.
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Development of a multimodal nanoprobe for the comprehension of post-stroke inflammation / Développement d'une nanosonde multimodale pour la compréhension de l'inflammation après un accident vasculaire cérébraleKarpati, Szilvia 18 October 2019 (has links)
L’accident vasculaire cérébrale (AVC) ischémique est une des premières causes de mortalité dans le monde, par conséquent il constitue un véritable enjeu de santé publique. Cette pathologie résulte de l’obstruction d’une artère cérébrale par un caillot et déclenche une inflammation, pouvant majorer les lésions tissulaires du cerveau. À ce jour les traitements anti-inflammatoires appliqués en clinique se sont révélés inefficaces. Il est donc indispensable de développer de nouvelles approches diagnostiques pour une meilleure compréhension des mécanismes biologiques impliqués dans cette pathologie. Dans ce contexte, nous avons proposé la conception d’une nanoplateforme hybride multimodale comme agent de contraste adapté à trois techniques d’imagerie médicale. Ces nanoparticules au cœur inorganique, composé de GdF3 augmentent sensiblement le contraste en IRM et leur opacité procure un rehaussement de contraste pour le Scanner Spectral à Comptage Photonique (SPCCT), une technique de développement récent. La troisième modalité, la microscopie biphotonique procure une haute résolution et une très grande sensibilité, tout en permettant d’obtenir des images en temps réel. Grâce à un chromophore adapté, greffé à la surface de la particule, cette modalité devient également accessible. Ces particules inorganiques sont synthétisées par une méthode solvothermale originale, développée par notre équipe. La surface des nanoparticules est ensuite modifiée par différents ligands polyéthylène glycol (PEG) fonctionnalisés, qui rendent les particules de GdF3 stables en milieu physiologique (comme le sang), biocompatibles et furtives. Enfin, un chromophore spécialement développé au sein de notre laboratoire, pour des applications d’absorption biphotonique, a été greffé à la surface de la particule. Le couplage du chromophore a été effectué via une réaction click azoture-alcyne, activée thermiquement (sans catalyse par Cu(I)). La toxicité des particules a été évaluée par deux techniques différentes, appliquées sur des cellules d’origine humaine. À l’issue de ces tests aucun effet cytotoxique n’a été observé. Après avoir démontré les propriétés multimodales de ces nanoobjets, des expériences précliniques in vivo ont été menées. Nous avons montré, que lors de l’observation du cerveau de souris la nanosonde augmente efficacement le contraste en SPCCT, IRM et produit un signal intense en microscopie 2-photons intravitale. Les particules se sont révélées particulièrement stables dans le sang : grâce à leur furtivité elles restent dans la circulation longtemps, ce qui favorise leur passage à travers la barrière hémato-enchéphalique lésée. Elles sont également phagocytées par les cellules immunitaires activées. La dynamique spatio-temporelle de ces cellules marquées par les nanoparticules a pu être imagée / Ischemic stroke, as one of the most common causes of death, represents an important health issue. The pathology consists of the occlusion of an artery in the brain leading to an acute inflammatory process. Post-stroke inflammation usually results in irreversible secondary brain tissue damage. To date, the clinical application of anti-inflammatory treatments has been either negative or inconclusive. For a better understanding of this complex physiological process and development of efficient treatment, there is an urgent need to develop performant in-vivo diagnostic tools. In that context, we proposed to design a multimodal hybrid nanoprobe for enhancing the contrast in three different clinical and pre-clinical imaging modalities. The ability of this probe to enhance contrast in MRI (Magnetic Resonance Imaging) and a recently developed spectral photon counting scanner computed tomography (SPCCT) is intrinsic to the inorganic GdF3 core. The inorganic nanoparticle size and morphology was optimized for the biological application. The third modality, two-photon imaging, provides high spatial resolution, high sensitivity, and allows real-time imaging. To make GdF3 nanoparticles visible by two-photon microscopy, a specially designed organic moiety is added to the nanoplatform. The inorganic nanoparticles are synthesized by the original solvothermal method developed in our group. Surface modifications with different PEG derivatives confer to the GdF3 nanoparticles high stability in physiological media (such as blood), biocompatibility, and stealth. The two-photon active chromophore synthesized in our laboratory is grafted to the particle surface via a thermally activated (catalyst-free) alkyne-azide click reaction. Toxicity of the nanoobjects has been assessed by using two different tests on four human-derived cells, and no cytotoxic effect of the particles was found. After the demonstration of the multimodality of the particles, pre-clinical in vivo experiments were performed. We evidenced that the particles successfully enhance SPCCT, MRI contrast in the brain of the small animal via a T2-effect and provide a high-intensity two-photon signal for in-vivo microscopy. Besides, the nanoparticles revealed to be stable and long-circulating in the blood, which favored their cross through the altered blood-brain barrier. Their phagocytose by activated immune cells offered the possibility to follow cell-trafficking
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Optical Anisotropy and Molecular Orientation of CuPc Films and Optical Properties of Ultra-thin High-k Films: Optical Anisotropy and Molecular Orientation of CuPc Films and Optical Properties of Ultra-thin High-k FilmsDing, Li 25 September 2012 (has links)
In the thesis CuPc thin films were investigated by (in situ) SE and RAS, which are employed to determine the out-of-plane and in-plane optical anisotropy and molecular orientation, respectively. CuPc is a promising candidate of organic semiconductors used in organic field effect transistors, organic light emitting diodes and organic solar cells. Vicinal Si(111) substrates are interesting due to the in-plane anisotropy caused by the steps and terraces on the surface. The strength of in-plane anisotropy of vicinal Si(111) is dependent on the offcut angle. The influence of offcut angle on out-of-plane and in-plane molecular orientation in CuPc thin films is explored. The in situ investigation of CuPc films suggests that structural changes occur during film growth. In addition, two different surface modification layers were utilized to examine the effect on CuPc molecular orientation: OTS monolayer with upright standing molecules and PTCDA layers with flat lying molecules. Metal-organic interface plays an important role in organic electronic devices. In-CuPc is chosen to be an example system investigated employing in situ SE and RAS. When In was thermally evaporated onto CuPc film, In atoms firstly diffuse into the CuPc film underneath and then aggregate to form clusters on top.
Hafnium dioxide (HfO2) is currently a hot topic to replace the conventionally used SiO2 as gate dielectrics in order to minimize leakage current when further scaling down microelectronic devices. Since HfO2 films are often crystalline, in order to obtain amorphous films which are beneficial to minimize leakage current, aluminum oxide (Al2O3) (k value: 9) which stays amorphous at much higher temperatures are combined to overcome this difficulty. Two series of ultra-thin samples were deposited by atomic layer deposition: mixed layers HfxAl1-xOz and bilayers HfO2 on Al2O3. Optical constants and bandgap are determined using SE in the energy range of 0.7-10 eV. It is found that the (effective) optical bandgap of both mixed layer and bilayer structures can be tuned by the film composition. Aging effect of high-k films was observed after storage of samples in air for two months, which is attributed to further oxidation of the dielectric films caused by the oxygen diffusion from ambient air to high-k films. / In dieser Arbeit werden dünne Schichten aus Kupferphthalozyanin (CuPc) mittels spektroskopischer (in-situ) Ellipsometrie (SE) und (in-situ) Reflektions-Anisotropie-Spektroskopie (RAS) untersucht, um die optische Anisotropie in einer Ebene parallel und senkrecht zur Schichtoberfläche und die molekulare Orientierung zu bestimmen. CuPc ist ein aussichtsreicher Kandidat als organischer Halbleiter in organischen Feldeffekt-Transistoren, organischen Leuchtdioden und organischen Solarzellen. Vizinale Si(111)-Substrate sind wegen der Anisotropie in der Substratebene interessant, die durch die Treppen und Terrassen auf der Oberfläche verursacht wird. Die Stärke der Anisotropie der vizinalen Si(111)-Oberfläche ist vom Schnittwinkel (Offcut) abhängig. Es wird der Einfluss des Offcut-Winkels auf die molekulare Orientierung in dünnen CuPc-Schichten parallel und senkrecht zur Substratoberfläche untersucht. Die in-situ Untersuchungen von CuPc-Schichten weisen darauf hin, dass strukturelle Veränderungen beim Wachstum auftreten. Darüber hinaus wurden zwei unterschiedliche Oberflächenmodifizierungsschichten, um deren Wirkung auf die molekulare Orientierung von CuPc zu untersuchen, verwendet: eine OTS-Monoschicht mit aufrecht stehenden Molekülen und PTCDA-Schichten mit flach liegenden Molekülen. Metall-organische Grenzflächen spielen eine wichtige Rolle in organischen elektronischen Bauelementen. In-CuPc wird als Beispiel für ein Metall-organisches System durch in-situ SE und RAS untersucht. Wenn In thermisch auf eine CuPc-Schicht aufgedampft wird, diffundieren In-Atome zunächst in die darunterliegende CuPc-Schicht und bilden dann Cluster auf der Schicht.
Hafniumdioxid (HfO2) ist ein heißer Kandidat für das Ersetzen des herkömmlich als Gate-Dielektrikum verwendeten SiO2 mit dem Ziel, die Leckströme bei der weiteren Verkleinerung mikroelektronischer Bauelemente zu minimieren. Um amorphe Schichten, die vorteilhaft zur Minimierung der Leckströme sind, zu erhalten, werden die HfO2-Schichten, die oft kristallin sind, mit Aluminiumoxid (Al2O3) (k-Wert: 9) kombiniert, das bei wesentlich höheren Temperaturen amorph bleibt. Zwei Serien von ultra-dünnen Proben wurden durch Atomlagenabscheidung hergestellt: Mischschichten HfxAl1-xOz und Doppelschichten HfO2 auf Al2O3. Die optischen Konstanten und Bandlücken wurden mittels SE im Energiebereich von 0,7 bis 10 eV bestimmt. Es hat sich gezeigt, dass die (effektive) Bandlücke der Misch- und Doppelschichten durch die Komposition abgestimmt werden kann. Nach Lagerung der High-k-Schichten für zwei Monate an Luft konnte ein Alterungseffekt beobachtet werden. Dieser wird auf die weitere Oxidation der dielektrischen Schichten, die durch Sauerstoffdiffusion aus der Umgebungsluft in die High-k-Schichten ermöglicht wird, zurückgeführt.
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