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- 645993 (1)
Defined aggregates of polymers such as polymeric micelles are of great importance in the development of pharmaceutical formulations. The amount of drug that can be formulated by a drug delivery system is an important issue, and most drug delivery systems suffer from their relatively low drug-loading capacity. However, as the loading capacities increase, i.e., promoted by good drug–polymer interactions, the drug may affect the morphology and stability of the micellar system. We investigated this effect in a prominent system with very high capacity for hydrophobic drugs and found extraordinary stability as well as a profound morphology change upon incorporation of paclitaxel into micelles of amphiphilic ABA poly(2-oxazoline) triblock copolymers. The hydrophilic blocks A comprised poly(2-methyl-2-oxazoline), while the middle blocks B were either just barely hydrophobic poly(2-n-butyl-2-oxazoline) or highly hydrophobic poly(2-n-nonyl-2-oxazoline). The aggregation behavior of both polymers and their formulations with varying paclitaxel contents were investigated by means of dynamic light scattering, atomic force microscopy, (cryogenic) transmission electron microscopy, and small-angle neutron scattering. While without drug, wormlike micelles were present, after incorporation of small amounts of drugs only spherical morphologies remained. Furthermore, the much more hydrophobic poly(2-n-nonyl-2-oxazoline)-containing triblock copolymer exhibited only half the capacity for paclitaxel than the poly(2-n-butyl-2-oxazoline)-containing copolymer along with a lower stability. In the latter, contents of paclitaxel of 8 wt % or higher resulted in a raspberry-like micellar core.
A series of polypeptoid homopolymers bearing short (C1–C5) side chains of degrees of polymerization of 10–100 are studied with respect to thermal stability, glass transition and melting points. Thermogravimetric analysis of polypeptoids suggests stability to >200 °C. The study of the glass transition temperatures by differential scanning calorimetry revealed two dependencies. On the one hand an extension of the side chain by constant degree of polymerization decrease the glass transition temperatures (Tg) and on the other hand a raise of the degree of polymerization by constant side chain length leads to an increase of the Tg to a constant value. Melting points were observed for polypeptoids with a side chain comprising not less than three methyl carbon atoms. X-ray diffraction of polysarcosine and poly(N-ethylglycine) corroborates the observed lack of melting points and thus, their amorphous nature. Diffractograms of the other investigated polypeptoids imply that crystalline domains exist in the polymer powder.
Starting off with solubility experiments of possible precursors, the present study reveals the whole development of a sol gel processing route for transparent p type semiconductive thin films with delafossite structure right to the fabrication of functional p-n junctions. The versatile sol formulation could successfully be modified for several oxide compositions, enabling the synthesis of CuAlO2, CuCrO2, CuMnO2, CuFeO2 and more. Although several differences in the sintering behaviour of powders and thin films could be observed, the powder experiments significantly contributed to the clearification of the intricate phase development during thermal annealing and also to optimization of the annealing sequence for thin film processing. Two different ternary systems turned out to be the most promising candidates for p-TCO application: Copper aluminum oxide for its high optical transmittance and copper chromium oxide for its low synthesis temperature, which allowed thin film deposition on low-cost borosilicate substrates. In order to combine the advantages of these two systems, the quaternary oxide composition CuAl1-xCrxO2 was investigated. With a higher optical transmittance than CuCrO2, a lower synthesis temperature than CuAlO2 and a lower resistivity than both parent systems, the optimum composition of the quaternary oxide is reached for x = 0.50. Compared to physical vapour deposition techniques, the undoped thin films presented here still need to make up some deficites in their optoelectronic performance. Although the best sol-gel samples are able to compete with RF sputtered samples or sampes deposited by PLD in transmittance, their resistivity is almost two orders of magnitude higher. The most probable reasons for this are the characteristic imperfections of sol-gel thin films like porosity and small crystallite size, which create barriers like grain boundaries and bottlenecks like barely connected particles. By additional effort such shortcomings can be repelled to a certain extend, but nevertheless the density of undoped sol-gel material always stays behind its pendants processed by physical vapour deposition.[246] Furthermore, such additional endeavour is likely to annihilate the advantage of sol-gel technique in processing costs. Extrinsic doping is a common method to decrease the resistivity of delafossite materials. Partially replacing the trivalent cations by divalent ones creates additional holes and thus generates additional charge carriers for p-type semiconductivity. This can improve the conductivity of delafossites by up to three orders of magnitude. Due to the compositorial flexibility of sol-gel processing, dopants could be introduced easily in this study by soluble precursors. However, improving the conductivity of CuAlO2 and CuAl0.5Cr0.5O2 via this method failed. Actually, this seems to be due to the fact that instead of being incorporated into the delafossite phase the dopant ions form intransparent phase impurities like spinels, which interfere with optical transmittance of the thin films. On the contrary, doping had a positive effect on the conductivity and the optical transmittance of copper chromium oxide, with magnesium being the most effective dopant. The resistivity could be decreased by more than three orders of magnitude, but in order to achieve this, much higher Mg concentrations than by other thin film deposition methods were necessary. This indicates a low doping efficiency in sol gel processed thin films, but also the ability of sol gel processing to incorporate more magnesium into the oxide than any other processing method. The extensive substitution of the chromium ions also increases the optical transmittance and allows sol gel processed thin films to draw level with thin films deposited by sputtering methods or PLD. Finally, the applicability of the delafossite thin films was proven by the asymmetric current voltage characteristics of heterojunctions between ITO and the delafossites. Shunting problems of the metallic contacts, on the other hand, reveal structural deficites of the delafossites, which should be the subject of further investigations.
In the framework of this thesis, new UV-patternable organic-inorganic hybrid polymers with higher refractive indices than reported in the literature for photonic applications were developed and studied with respect to their chemical structure, their optical properties, and their ability of being patterned by 1PP and 2PP. Particularly with 2PP, one could create 3D structures using the novel hybrid materials. The materials were prepared from hydrolysis and polycondensation reactions of · organo-alkoxysilanes and titanium alkoxide precursors, modified with and without CL and organo-alkoxysilanes precursors, and · organo-alkoxysilanes, titanium alkoxide and organophosphorus precursors. The major scope of this work was to increase the refractive index of ORMCER® materials based on only organo-alkoxysilanes. Thus, the parameters which influence the refractive index were investigated thoroughly. In particular, the synthesis parameters such as the introduction of titanium alkoxide and its concentration, the organo-alkoxysilanes, the catalyst concentration, the solvent used, but, also the processing parameters such as, the UV exposure dose, initiator concentration, and developer were investigated.
This work deals with the sintering of multi-material composites. It aims at the establishment of an alternative to the existing complex models for sintering. The development of the associated experimental procedure is also included in this work. The developed material model must be able to predict (i) the sintering kinetics and (ii) the viscous moduli of a material. An experimental approach with free sintering and hot-forging measurements is favoured in this work. The prediction of the sintering kinetics is addressed with the construction of a map of sintering kinetics data: the Master Sintering Diagram (MSD). The MSD is based on a generalized equation for solid-state diffusion, thus is suitable for any thermal activated diffusion. The MSD allows the prediction of sintering kinetics for a large range of temperatures and external loads. A novel approach to the determination of the viscous moduli is developed in this work: the cyclic unloading method. It is a hot-forging measurement (sintering under uniaxial compression) where the applied load is released for short periods. The measurements are carried out with continuous heating, so that the viscous moduli are determined over large ranges of temperatures and densities. The advantage of this method is the measurement of the viscous moduli in anisotropic microstructures. The material model is validated in two steps. Firstly, the predictions of sintering kinetics with the MSD are compared with experimental results: changes of thermal profile and changes of load are predicted with a maximum deviation of 10%. Secondly, the experimentally determined viscous moduli are used for the prediction of a bi-layer curvature using models for warpage from literature. The prediction is qualitatively good for a maximum deviation of 27%. The study of a sintering glass-ceramic tape on a rigid substrate is presented. It shows that this co-sintering problem can be qualitatively investigated with requirement of the material model. The formation of anisotropy intrinsic to the hot-forging experiments is also reported in this work. It appears to be a important point to address in the future for a better understanding of the cosintering.
The main focus of this work was to get a deeper understanding of the relationship between the structure of sol-gel films, their densification and their macroscopic cracking. First of all titania was chosen as model system. Therefore a synthesis route starting from the preparation of long-term stable amorphous redissoluble precursor powders based on acetylacetone as chelate ligand was utilized. The solubility and stability of the powders in various solvents can be determined by chemical synthesis and technological parameters. When dissolved in a solvent mixture of ethanol and 1,5-pentanediol, thin films can be easily prepared by dip-coating technique. Thereby the quality of the titania films enormously depends on the calcinations temperature and the solvent mixture is used. In order to investigate the influence of different solvents and solvent mixtures on the microstructure and densification of the precursors, the coating solutions were stripped off (sol powder) and analyzed as function of annealing temperature. It was pointed out that a high densification rate caused by the addition of 1,5-pentanediol, results in dense microstructure with trapped residual carbon. These impurities can retard the phase transformation of anatase to rutile. The analysis of so-called “film powders” scraped off multiple dip-coated substrates provides valuable information on the effect of air moisture and unidirectional densification during drying and aging on the structure of thin films. The high surface-to-volume ratio and access to air moisture determine the chemical composition of the as-prepared film, which controls shrinkage, crystallization and defect structure of the coatings. Further it was shown, that drying as a thin film results in the formation of closed pores and much denser microstructure than the respective sol powder. Without the addition of 1,5-pentanediol all –OEt moieties undergo hydrolysis reactions, which causes the formation of a rigid network. The presence of 1,5-pentanediol retards this hydrolysis reactions and provides some network plasticity. Generally the microstructure of thin films is comparatively close to the microstructure of the film powders. The addition of 1,5-pentandiol prevents hydrolysis and condensation reactions as like in the film powders. However even at 700 °C, thin films never transform to rutile, which was attributed to the tensile stresses in thin films. In thin films and in film powders as well a comparable amount of closed pores are formed during annealing. Further it was shown that most of the thin sol-gel films investigated form a dense crust on their tops during annealing. This explains why crack free films exhibit only closed pores. However, when cracks appear during thin film shrinkage in the coating, this crust is burst, which generates open porosity. The defect density in the coatings was determined by an automated analysis of surface images. The crack formation and quantity can be directly referred to tensile stresses in the coatings, which arise from hydrolysis and condensation during thin film drying and aging. Therefore when 1,5-pentanediol is added to the sol, thin film cracking was avoided, because hydrolysis and condensation reactions are retarded, which preserves a higher network flexibility. Furthermore the crack formation was significantly influenced by the atmospheric humidity that was used during the coating process, which was explained by different drying and condensation rates. Under certain chemical starting conditions water soluble precursor powders can be also obtained. In general the observations made with the water based coating solutions are mostly in agreement with the former results based on ethanol based coating solutions. For example the high surface-to-volume ratio of film powders compared to sol powders also significantly enhances film drying and densification. The addition of 1,5-pentanediol also clearly contributes to their densification behavior and phase evolution. As seen before in the case of ethanol based coatings, 1,5-pentanediol enhances the stability towards hydrolysis and condensation reactions and preserves some network plasticity. Therefore coatings prepared without the addition of 1,5-pentanediol already form cracks during film drying and aging because of tensile stresses. Thus, the addition of 1,5-pentanediol results in a reduction/prevention of crack formation. Nevertheless some differences were observed, i.e. the critical single coating film thickness of ethanol based coatings is nearly twice that of water based coatings. This was explained by the different surface tensions of the basis solvents, which during thin film drying causes significantly higher capillary forces and tensile stresses in water based coatings. When acetylacetone is replaced by triethanolamine as chelating ligand for titanium also re-dissolvable precursor powders can be synthesized. The film powders combine a high hydrolytic stability of the precursor with sufficient intermediate network flexibility. The different type of organics changes the drying and densification behavior: i.e. in contrast to film powders obtained from acetylacetone based precursor powders the structure of triethanolamine based film powders is unaffected by the thin film drying process. This high hydrolytic stability and plasticity of this precursor allows the preparation of defect free coatings up to single film thickness of 300 nm. However triethanolamine based thin films present at intermediary annealing temperatures a distinctively different microstructure compared to acetylacetone based films. The general validity of the conclusions was proved on the basis of zirconia coatings that were also prepared by the use of re-dissolvable precursor powders. In principle all conclusions concerning the interconnection of precursor chemistry, film formation, densification and structure were transferable to the respective zirconia coatings. Differences mainly arise only from differential material properties i.e. bulk density. Finally, it has been pointed out that the findings obtained on the densification behavior of thinsol-gel films are also a valuable tool for improved explanations of other important scientific questions concerning sol-gel films, i.e. scratch resistance of sol-gel coatings, fiber -bridging and – degradation of sol-gel coated fibers.