Global ETD Search

1	Cluster-based redox activity in Endohedral Metallofullerenes: Samoylova, Nataliya 07 November 2017 (has links) (PDF) Endohedral fullerenes are closed carbon shells encapsulating molecular or ionic species in their inner space. Obtained for the first time in 1985, endohedral metallofullerenes (EMFs) remain in focus of research for many years with a broad variety of metal atoms, endohedral cluster and cage sizes being reported. Electrochemical studies of endohedral metallofullerenes are of particular interest because of the more complex redox behavior in comparison to empty fullerenes. The EMF molecules can be considered as a combinations of positively charged cluster and negatively charged carbon shell “ligand”, and both constituents can be redox active. A cage-based electrochemical activity is more common, in particular, the most abundant nitride clusterfullerenes generally have redox-active cages. Cluster-based electrochemical activity is less common and can be revealed via unexpected redox behavior (e.g., shifted potential when compared to analogous molecules, potential metal dependence) and with the use of spectroscopic methods. Here we report electrochemical and EPR studies of three EMF families: (i) M2@C82-C3v and M2@C82-Cs dimetallofullerenes with a covalent bonding between two metal atoms, (ii) M2@C80(CH2Ph) dimetallofullerene derivatives with single-occupied metal-bonding orbital, and (iii) M2TiC@C80 EMFs with endohedral Ti(IV) (M is either Sc or Y or a lanthanide). For the first two families, the metal-metal bonding orbital has been found to be redox active: in M2@C82, the double-occupied M-M bonding orbital is involved in the first oxidation process, while in M2@C80(CH2Ph) the unoccupied component of single-occupied metal-bonding orbital acts as the LUMO, accepting one electron during the first reduction step. Thus, single electron transfer reactions in both cases lead to the changes in the magnetic properties of EMFs, which is especially well revealed by EPR spectroscopy. For the series of M2TiC@C80 EMFs, the first reduction predominantly occurs on internal Ti atom and can be described as TiIV/TiIII redox process. Due to the variation of the size of the Ti ion in different oxidation states, reduction changes the inner strain of the cluster, leading to a large variability of the TiIV/TiIII reduction potential in dependence on the size of the formally inert lanthanide metal in M2TiC@C80. Fullerene Fullerenes ddc:540 rvk:VE 8007 Fullerenes Electrochemistry EPR
2	Investigation into the Formation of Nanoparticles of Tetravalent Neptunium in Slightly Alkaline Aqueous Solution Husar, Richard 25 August 2015 (has links) (PDF) Considering the worldwide growing discharge of minor actinides and the current need for geological disposal facilities for radioactive waste, this work provides a contribution to the safety case concerning Np transport if it would be released from deep repository sites and moving from alkaline cement conditions (near-field) to more neutral environmental conditions (far-field). The reducing conditions in a nuclear waste repository render neptunium tetravalent, which is assumed to be immobile in aqueous environment due to the low solubility solution of Np(IV). For tetravalent actinide nuclides, the most significant transport should occur via colloidal particles. This work demonstrates the formation of intrinsic neptunium dioxide nanocrystals and amorphous Np(IV) silica colloids under environmentally relevant conditions. The dissociation of the initial soluble Np(IV) complex (i.e. [Np(IV)(CO3)5]6-) induces the intrinsic formation of nanocrystalline NpO2 in the solution phase. The resulting irregularly shaped nanocrystals with an average size of 4 nm exhibit a face-centered cubic (fcc), fluorite-type structure (space group ). The NCs tend to agglomerate under ambient conditions due to the weakly charged hydrodynamic surface at neutral pH (zetapotential ~0 mV). The formation of micron-sized agglomerates, composed of nanocrystals of 2-5 nm in size, and the subsequent precipitation cause immobilization of the major amount of Np(IV) in the Np carbonate system. Agglomeration of NpO2 nanocrystals in dependence on time was indicated by PCS and UV-vis absorption spectroscopy with the changes of baseline characteristics and absorption maximum at 742 nm. Hitherto, unknown polynuclear species as intermediate species of NpO2 nanocrystal formation were isolated from solution and observed by HR-TEM. These polynuclear Np species appear as dimers, trimers and hexanuclear compounds in analogy with those reported for other actinides. Intrinsic formation of NpO2 (fcc) nanocrystals under ambient environmental conditions is prevented by admixing silicic acid: amorphous Np(IV) silica colloids are formed when silicate is present in carbonate solution. Herein, the initial molar ratio of Si to Np in solution lead to the formation of Np(IV) silica particles of different composition and size where Si content determines the structure and stability of resulting colloids. Implications for different electronic structures of Np(IV) in dependence on Si content in the solid phase are given by the shift of the absorption maximum at 742 nm characteristic for Np(IV) colloids, silica excess of 5 times the magnitude of Si to Np reveal a redshift up to 6 nm in the colloidal UV-vis spectrum. Precipitation of Np(IV) particles in the ternary system results in a different coordination sphere of Np(IV) compared to the binary system, and the incorporation of Si into internal structure of Np(IV) silica colloids in coffinite-like structure is confirmed by EXAFS. TEM confirms different kinds of particle morphologies in dependence on the silica content. Silica-poor systems reveal porous particles in the micron-range which consist of irregular cross-linked hydrolyzed Np(IV) silica compartments with pores <15 nm. In contrast, long-term stabilized and silica-enriched systems are characterized by isolated particles with an average particle size of 45 nm. Agglomerates of such isolated Np(IV) silica particles appear as consolidated amorphous solids with a densely closed surface and exhibit no internal fractures. The latter mentioned morphology of Np(IV) silica particles might facilitate the migration behavior of Np(IV) in a stabilized colloidal form under environmental conditions. The silica-enriched particles with densely closed surface are long-term stabilized as colloidal dispersion (>1 year) due to repulsion effects caused by significant surface charge. Particles synthesized from Si/Np = 9/1 carry exclusively negative surface charge in nearly the whole pH range from pH 3 to pH 10 with zetapotential = (-) 5 to (-) 30 mV. The zeta potentials of all particle systems containing silica are significantly shifted to more negative values below pH 7 where the isoelectrical point shifts from pH = 8.0 to 2.6 effecting negative charge under ambient conditions which supports electrostatic stabilization of Np(IV) particles. Particle surface charge at the slipping plane, particle size and shape necessarily depend on the initial magnitude of Si content in solution during particle formation. Particular changes of the morphology and internal structure of different Np(IV) silica colloids by aging are indicated by TEM and XPS. The composition and the crystallinity state of the initially formed amorphous phases partially changed into well-ordered nanocrystalline units characterized with fcc structure. The presence of silicate under conditions expected in a nuclear waste repository significantly influences the solubility of Np(IV) and provoke the stabilization of waterborne Np(IV) up to concentrations of 10-3 M, exceeding Np´s solubility limit by a factor of up 10.000. Neptunium and silicate significantly interact with each other, and thereby changing their individual hydrolysis and polymerization behavior. Silicate prevents the intrinsic formation of NpO2 NCs in fcc-structure, and at the same time, Np(IV) prevents the polymerization of silicate. Both processes result in the formation of Np(IV) silica colloids which possibly influence the migration behavior and fate of Np in the waste repositories and surrounding environments. For tetravalent actinides in general, the most significant transport in the environment would occur by colloidal particles. Therefore, Np(IV) silica colloids could have a significant implication in the migration of Np, the important minor actinide in the waste repositories, via colloidal transport. Aktinide Neptunium Nanopartikel Kolloide Umweltchemie Actinides neptunium nanoparticles nanocrystals environmental chemistry ddc:540 rvk:VE 8007
3	Bildung von Kolloiden des tetravalenten Urans unter Einfluss von Silikat in neutralen und schwachalkalischen wässrigen Systemen Ulbricht, Isabell 09 November 2016 (has links) (PDF) Diese Arbeit umfasst die Präparation sowie Charakterisierung von neuartigen Uran(IV)-Kolloiden, die in nahneutralen pH-Bereichen und unter umweltrelevanten Bedingungen stabilisiert vorliegen. Rückschlüsse auf Stabilitätsverhalten und Partikelgrößenverteilungen wurden durch dynamische Lichtstreuung, Zetapotentialmessungen sowie Ultrafiltration und Ultrazentrifugation in Kombination mit Elementanalysen getroffen. UV-Vis- und Laserfluoreszenzspektroskopie bestätigten den tetravalenten Zustand des Urans bei den Experimenten. Anders als bisherige Untersuchungen vermuten lassen, ist es möglich langzeitstabile Uran(IV)-Kolloide in höheren Konzentrationen zu erzeugen. Durch Zusatz von geochemischen Komponenten, wie Carbonat und Silikat sind diese sedimentationsstabil und im nahneutralen bis basischen pH-Bereich über längere Zeiträume beständig. Dabei zeigte sich, dass gelöstes Silikat bei der Herstellung der Kolloide eine wesentliche Rolle spielt und Uran(IV) bis zu einer Konzentration von 10-3 mol/L, entsprechend 0,238 g/L in Lösungen stabilisieren kann. Diese Urankonzentration ist dabei ca. drei Potenzen höher als für bisher bekannte silikatfreie, wässrige Uran(IV)-Kolloide. Durch die Verwendung unterschiedlicher analytischer Methoden konnte gezeigt werden, dass die Durchmesser der entstandenen Uran(IV)-Kolloide im nanoskaligen Bereich von teilweise unter 20 nm liegen. Durch diesen kolloidalen Zustand kann eine hohe Mobilität in aquatischen Systemen unterstellt werden. Zusätzlich weisen Langzeituntersuchungen darauf hin, dass diese Kolloide in einem abgeschlossenen System über Jahre stabilisiert werden. Je höher dabei das Verhältnis zwischen Silikat- und Uran(IV)-Gehalt und je höher der pH-Wert der Lösung ist, desto kleiner und stabiler sind diese Partikel. Es ist anzumerken, dass sich keine Kolloide in Abwesenheit von Uran(IV) bilden. Silikat ist in der Lage, die negative Oberflächenladung der Uran(IV)-Kolloide im nahneutralen pH-Bereich zu erhöhen. Dies führt zu einer stärkeren elektrostatischen Abstoßung bzw. repulsiven Wechselwirkungen, womit eine bessere Stabilisierung gewährleistet wird. Der isoelektrische Punkt der erzeugten Partikel wird zu niedrigeren pH-Werten verschoben. Extended-X-ray-absorption-fine-structure-Untersuchungen zeigen, dass die innere Struktur der Kolloide durch den steigenden Silikatgehalt bei deren Bildung von U-O-U-Bindungen (entsprechend Uran(IV)oxyhydroxiden) zu U-O-Si-Bindungen verändert wird. Die Koordination in der benachbarten Region von U(IV) in den U(IV)-Silikat-Kolloiden ist vergleichbar mit der des Coffinits, USiO4. Dieses, für tetravalentes Uran noch nicht beschriebene Phänomen, wurde bereits bei silikatstabilisierten Eisen(III)- oder Mangan(III,IV)-Kolloiden beobachtet und als „Sequestrierung“ bezeichnet. Die silikatstabilisierten U(IV)-Kolloide sind in Laborexperimenten unter kontrollierten Bedingungen erzeugt worden, d.h. es ist noch nicht bekannt, ob diese Phasen in der Natur frei auftreten können. Die qualitative Zusammensetzung der Matrix der experimentellen Lösungen (H+, OH-, Na+, HCO3-/CO32-, Silikat) wurde ähnlich der geochemischen Natur von Grund- bzw. Porenwässern gewählt. Dadurch kann prinzipiell von einem Vorhandensein solcher Kolloide in Wässern natürlichen Ursprungs ausgegangen werden. Die Existenz solcher Partikel würde eine Erklärung für das beobachtete Auftreten von Uran(IV)-Kolloiden in anoxischen Porenwässern oder anoxischen Grundwässern liefern. Es ist jedoch zu beachten, dass experimentell die Reduktion von Uran(VI)-Phasen vorausgesetzt wurde und eine anschließende Verdünnung in Anwesenheit von Silikat erfolgt. Umweltbezogene Untersuchungen zur Mobilität und Stabilität in aquatischen Systemen dieser Kolloide waren nicht Gegenstand der Arbeit und so kann eine umweltrelevante Beurteilung dieser neuartigen Uran(IV)-Kolloide in Bezug auf den Eintrag in die Biossphäre noch nicht getroffen werden. Die hier präsentierten Ergebnisse bieten aber die Grundlage für weitere, intensive Untersuchungen zu Möglichkeiten der Mobilisierung und Stabilisierung verwandter Actinide und Schwermetalle und sollten Bestandteil der Sicherheitsanalyse bei der Lagerung radioaktiven Abfälle in tiefen geologischen Formationen sein. / This work includes the preparation and characterization of new uranium(IV) colloids which are formed and stabilized in the near neutral pH range and under environmentally relevant conditions. Conclusions on stability behavior and particle size distributions were drawn based on results obtained by dynamic light scattering, zeta potential measurements, as well as ultrafiltration and ultracentrifugation in combination with element analyzes. Spectroscopic methodes confirmed the tetravalent state of uranium in the experiments. Unlike empirical data, it is possible to generate long-term stable uranium(IV) colloids at higher concentrations. By addition of geochemical components such as carbonate and silicate, they are stable and resistant in the near neutral pH range over a long period. It was found that dissolved silica plays an essential role in the preparation of colloids. Colloid-borne uranium(IV) up to a concentration of 10-3 mol/L, corresponding to 0,238 g/L, is stabilized in solutions. This concentration is about three orders of magnitude higher than so far known silicate-free aqueous uranium(IV) colloids. Through the use of different analytical methods (invasive and non-invasive) it could be shown that the resulting uranium(IV) colloids are in the nanoscalar range. A high mobility can be assumed in aquatic systems. Evidence is provided by photon correlation spectroscopy, ultrafiltration, and ultracentrifugation that uranium(IV) can form silicate-containing colloids of a size lower than 20 nm. The particles are generated in near neutral to slightly alkaline solutions containing geochemical relevant components (carbonate, silicate, sodium ions). They remain stable in aqueous suspension over years. Electrostatic repulsion due to a negative zeta potential in the near-neutral to alkaline pH range caused by the silicate stabilizes the uranium(IV) colloids. The isoelectric point of the nanoparticles is shifted towards lower pH values by the silicate. The higher the silicate to uranium(IV) content ratio and the higher the pH of the solution are, the smaller and more stable (in terms of pH-changes) are the particles. It should be noted that no colloids were formed in absence of uranium(IV). The mechanism of the colloidal stabilization can be regarded as “sequestration” by silicate, a phenomenon well known from heavy metal ions of high ion potential such as iron(III) or manganese(III,IV), but never reported for uranium(IV) so far. Extended X-ray absorption fine structure (EXAFS) spectroscopy showed that U–O–Si bonds, which increasingly replace the U–O–U bonds of the amorphous uranium(IV) oxyhydroxide with increasing silicate concentration, make up the internal structure of the colloids. The next-neighbor coordination of uranium(IV) in the uranium(IV)-silica colloids is comparable with that of coffinite, USiO4. The assessment of uranium behavior in the aquatic environment should take the possible existence of uranium(IV)-silica colloids into consideration. Their occurrence might influence uranium migration in anoxic waters. The silicate-stabilized colloids have been generated in laboratory experiments under controlled conditions; i.e., it is not known yet whether these phases can occur in natural water. The qualitative composition of the matrix of the experimental solutions (H+, OH-, Na+, HCO3-/CO32-, silicate) was chosen similar to the geochemical nature of groundwater. Thereby, it can be assumed that such colloids are present in natural waters. The existence of such particles would provide an ex-planation for the occurrence of uranium(IV) colloids in anoxic pore waters or groundwaters. However, it should be noted that these results were observed by the reduction of uranium(VI) carbonate and dilution in the presence of silicate. Studies on the mobility and stability of these colloids in aquatic systems were not subject of this work and an environmental assessment of these novel uranium(IV) colloids with respect to the entry in the biosphere cannot be taken into account. But the possibilities of mobilization and stabilization can be applied to surrogate actinides and heavy metals, and point to the need for more intensive research in this area. Uran(IV) Mobilisierung Silikat Zetapotential Filtration EXAFS Uran(IV) mobilization silicate zetapotential filtration EXAFS ddc:540 rvk:VE 8007
4	Creation of crosslinkable interphases in polymer blends by means of novel coupling agents / Erzeugung von vernetzbaren Grenzschichten in Polymerblends durch Einsatz neuartiger Kopplungsagenzien Sadhu, Veera Bhadraiah 14 August 2004 (has links) (PDF) The goal of the work is to study possibilities for the modification of interface in immiscible polymer blends, which determine to a large degree of the blend properties. For this purpose novel coupling agents (named SCA) containing 2-oxazoline, 2-oxazinone, and hydrosilane reactive sites have been prepared. In blends of amino- functional and carboxylic acid terminated polymers the oxazoline and oxazinone units of the SCA react selectively with one of the polymers and, therefore, the SCA should locate at the interface. The remaining hydrosilane sites can now be used for further modification, e.g. for crosslinking. In the thesis we discussed the effect of the SCA on the morphology and thermal and rheological properties of blends based on carboxylic acid terminated polystyrene (PS) and amino-terminated polyamide 12 (PA) or poly(methyl methacrylate) (PMMA). The morphology of the blends and the location of the SCA strongly depends on the processing conditions. The crosslinkability of the interface could be proven by changes in the solubility behavior of the blends. Kopplungsagenzien Modification von Grenzschichten Polymerblends coupling agents interfacial modification polymer blends ddc:540 rvk:VE 8007 Dünne Schicht Polymer-Blend Vernetzung
5	Modifizierung und Verarbeitung von Poly(3-hydroxybuttersäure-co-3-hydroxyvaleriansäure) (PHBV) mit kugelförmigen Mikropartikeln Oberhoff, Ralph Wilhelm 23 December 2005 (has links) (PDF) Poly(3-hydroxybuttersäure-co-3-hydroxyvaleriansäure), PHBV, ist ein Copolyester, der auf biologischem Weg durch Bakterien herstellbar und ein steifes sowie relativ festes Polymer ist. Seine Biokompatibilität und biologische Abbaubarkeit weckt das Interesse für diverse Anwendungen in Pharmazie und Medizin. PHBV reagiert mit Abbau empfindlich auf zugleich thermische und mechanische Belastungen, was ein Problem für die Verarbeitung darstellt. Produkte aus PHBV aus einmal geschmolzenem und verarbeitetem Pulver sind hochkristallin. Daher ist das Material spröde. Ferner wirkt sich die hohe Kristallinität sowie eine große Änderung der Dichte beim Abkühlen der Schmelze nachteilig auf die Spinnbarkeit des Materials aus. Nach dem Passieren der Spinndüse ziehen sich die Spinnfäden zusammen, was die Gefahr eines Fadenrisses beim Spinnen erhöht. Aufgrund der relativ hohen Kristallinität des Materials und einer verzögerten Kristallisationskinetik bei gesponnenen Polymerfäden kommt es zur Nachkristallisation in einem erheblichen Ausmaß, die Fäden verkleben nach dem Aufwickeln auf den Galetten und reißen beim Abwickeln. Zur Behebung der Nachteile wurden Verarbeitungsbedingungen vor allem bei Schmelzspinnprozessen mit der Kolbenspinnanlage und bei Mischungsprozessen optimiert. Die Polymermischungen und ?verbundstoffe enthalten kugelförmige Mikropartikel verschiedener Morphologie, die zuvor synthetisiert und charakterisiert wurden. Vor allem mit Vinylgruppen modifizierte Silikat-Submikropartikel mindern die Sprödigkeit von PHBV. Mikropartikel PHBV Polymermischungen Verbundstoffe Verstärkung PHBV blends composites microparticles reinforcement ddc:540 rvk:VE 8007 Mikropartikel Polymergemisch Valeriansäurederivate Verbundwerkstoff
6	Investigation of Polymer Systems in Solutions with Electron Microscopy and Scattering Methods / Untersuchung von Polymersystemen in Lösung mittels Transmissionselektronenmikroskopie und Streumethoden Schellkopf, Leonard 21 May 2015 (has links) (PDF) This work is focused on the visualization and thus in the aid in finding explanations for the behavior of polymer structures as they exist in solution. For this aim, preparation and imaging techniques based on cryo-TEM protocols were developed for a large variety of polymeric specimens using new commercially available devices and the results were compared with the findings of other means of structural investigations. The systems used in this work were chosen, as their investigations can be adapted to other polymer systems by slight adaptation of the preparation procedures. Elektronenmikroskopie TEM Polymere Polymerbürsten Kryo-TEM electron microscopy TEM polymers polymer brushes Cryo-TEM ddc:540 rvk:VE 8007
7	Electrophoretic deposition of semiconducting polymer metal oxide nanocomposites and characterization of the resulting films Vu, Quoc Trung 17 December 2005 (has links) (PDF) Conducting polymer nanocomposites composed of metal oxides and polythiophene was synthesized by chemical polymerization in colloidal suspensions. The electrochemical and photoelectrochemical properties of such nanocomposites have been studied. For these investigations films of nanocomposites were prepared by an electrophoretic deposition process. The deposition process was studied in greater detail and kinetic details were determined. The high voltage electrophoretic deposition process was combined with a quartz crystal microbalance (QCM). Then the films were characterized by cyclic voltammetry (CV), electrochemical impedance spectroscopy (EIS) and photocurrent spectroscopy. Leitfähige Polymere Kern-Schale-Struktur Verbundwerkstoff Photostromspektroskopie Conducting Polymers core-shell structure nanocomposites photocurrent spectroscopy ddc:540 rvk:VE 8007 Kern-Schale-Struktur Leitfähige Polymere Photoelektronenspektroskopie Verbundwerkstoff
8	Self-assembly and functionality of polymer bottle brushes on surfaces Raguzin, Ivan 16 April 2015 (has links) (PDF) In the past decade there has been a growing interest in one-dimensional (1D) nanostructures, such as nanowires, nanotubes and nanorods, owing to their size-dependent optical and electronic properties and their potential application as building blocks, interconnects and functional components for assembling nanodevices. One of the ways to obtain such architectures is a template-directed synthesis which is practically a straightforward route to 1D nanostructures. In this approach, the template simply serves as a scaffold, within (or around) which a different material is generated in situ and shaped into a nanostructure with its morphology complementary to that of the template. It is generally accepted that template-directed synthesis provides a simple, high-throughput, and cost-effective procedure that also allows the complex topology present on the surface of a template to be duplicated in a single step. In the current work, utilization of the molecular bottle brushes as templates is proposed for the fabrication of conductive nanorods. Their non-spherical macromolecular geometries and lengths up to a few hundred nanometers allow the application of these structures in nanowire synthesis. The variety of molecular bottle brush architectures and their composition enables the adjustment of appropriate conditions for the preparation of conductive materials. Moreover, the ability of the brushes to assemble on a surface under certain conditions provides their usage as building blocks for the preparation of complex conductive networks. Here, the preparation, characterization, and applications of molecular bottle brushes are discussed. Two main goals were pursued. First, to deepen the knowledge in the synthesis of molecular bottle brushes, and to investigate their behavior on the surface. Second, to explore the application of the brushes as templates or building blocks for the formation of conductive nanowires. For the purpose, new ways of molecular brush synthesis by using the “grafting to” approach had to be developed. It was found that the reaction of nucleophilic addition based on pentofluorophenol chemistry and a coupling “click chemistry” reaction can be used to fabricate molecular brushes. Both methods showed efficient results and demonstrated high reactivity of the backbone with the end groups of the side chains. The “click chemistry” approach, however, demonstrated better results considering higher thicknesses of the brushes and, therefore, higher grafting density of the side chains. The “grafting to” together with the “grafting from” methods are very powerful synthetic tools, which can be used in the fabrication of any desired molecular bottle brush architectures. Additionally, complexation of oppositely charged bottle polymer brushes at a single-molecule level using AFM and CryoTEM was experimentally investigated. It was found that polyelectrolyte complexes have “scrambled-egg” morphology, where oppositely charged polymer chains are not oriented parallel to each other but cross each other. Furthermore, molecular bottle brushes were used as templates for the preparation of conductive nanowires. Three approaches for their fabrication were tested. It was found that brushes could easily be covered with various conductive materials, for example conductive polymers or metals. It was showed that for very small, tiny objects as molecular bottle brushes, one can use FIB in order to build up electrodes at its ends. The electrodes could be sputtered with an accuracy of 500 nm and further be used in the determination of the conductivity. The molecular bottle brushes covered with palladium showed the resistance of 50 MΩ, which, regarding the size of the brush, corresponds to a conductivity of one single molecule being ~1 S*cm-1. The obtained conductivity data were in good correlation with the data found in literature. We believe that the molecular bottle brushes have high potential applicability for the building of complex conductive networks. Future refinement of the synthetic methods, combined with improvements in structuring and positioning of objects at the nanoscale, could lead to their implementation in the construction of high-performance electronic devices. Molekulare Bottle Bürsten Leitfähige Bürsten Polyelektrolyt-Komplexe Grafting-from Molecular Bottle Brushes Conductive Brushes Polyelectrolyte Complexes Grafting-from ddc:540 rvk:VE 8007
9	Design of self-repairable superhydrophobic and switchable surfaces using colloidal particles Puretskiy, Nikolay 06 March 2014 (has links) (PDF) The design of functional materials with complex properties is very important for different applications, such as coatings, microelectronics, biotechnologies and medicine. It is also crucial that such kinds of materials have a long service lifetime. Unfortunately, cracks or other types of damages may occur during everyday use and some parts of the material should be changed for the regeneration of the initial properties. One of the approaches to avoid the replacement is utilization of self-healing materials. The aim of this thesis was to design a self-repairable material with superhydrophobic and switchable properties using colloidal particles. Specific goals were the synthesis of colloidal particles and the preparation of functional surfaces incorporated with the obtained particles, which would exhibit a repairable switching behavior and repairable superhydrophobicity. In order to achieve these goals, first, methods of preparation of simple and functional colloidal particles were developed. Second, the behavior of particles at surfaces of easy fusible solid materials, namely, paraffin wax or perfluorodecane, was investigated. Superhydrophobe Oberflächen kolloidale Partikel schaltbare Oberflächen Selbstheilung himbeer-ähnliche Partikel Superhydrophobic surfaces colloidal particles switchable surfaces self-healing raspberry-like particles ddc:540 rvk:VE 8007

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