@article{MillerWintzheimerPrieschletal.2021, author = {Miller, Franziska and Wintzheimer, Susanne and Prieschl, Johannes and Strauss, Volker and Mandel, Karl}, title = {A Supraparticle-Based Five-Level-Identification Tag That Switches Information Upon Readout}, series = {Advanced Optical Materials}, volume = {9}, journal = {Advanced Optical Materials}, number = {4}, doi = {10.1002/adom.202001972}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-224469}, year = {2021}, abstract = {Product identification tags are of great importance in a globalized world with increasingly complex trading routes and networks. Beyond currently used coding strategies, such as QR codes, higher data density, flexible application as well as miniaturization and readout indication are longed for in the next generation of security tags. In this work, micron-sized supraparticles (SPs) with encoded information (ID) are produced that not only exhibit multiple initially covert identification levels but are also irreversibly marked as "read" upon readout. To achieve this, lanthanide doped CaF\(_{2}\) nanoparticles are assembled in various quantity-weighted ratios via spray-drying in presence of a broad-spectrum stealth fluorophore (StFl), yielding covert spectrally encoded ID-SPs. Using these as pigments, QR codes, initially dominated by the green fluorescence of the StFl, could be generated. Upon thermal energy input, these particle-based tags irreversibly switch to an activated state revealing not only multiple luminescent colors but also spectral IDs. This strategy provides the next generation of material-based security tags with a high data density and security level that switch information upon readout and can be, therefore, used as seal of quality.}, language = {en} } @phdthesis{Goetzendoerfer2010, author = {G{\"o}tzend{\"o}rfer, Stefan}, title = {Synthesis of Copper-Based Transparent Conductive Oxides with Delafossite Structure via Sol-Gel Processing}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-51601}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2010}, abstract = {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.}, subject = {Transparent-leitendes Oxid}, language = {en} } @phdthesis{Iuga2007, author = {Iuga, Maria}, title = {Ab Initio and Finite Element Simulations of Material Properties in Multiphase Ceramics}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-26246}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2007}, abstract = {In the present study numerical methods are employed within the framework of multiscale modeling. Quantum mechanics and finite element method simulations have been used in order to calculate thermoelastic properties of ceramics. At the atomic scale, elastic constants of ten different ceramics (Al2O3, alpha- and beta-SiC, TiO2-rutile and anatase, AlN, BN, CaF2, TiB2, ZrO2) were calculated from the first principles (ab-initio) using the density functional theory with the general gradient approximation. The simulated elastic moduli were compared with measured values. These results have shown that the ab-initio computations can be used independently from experiment to predict elastic behavior and can provide a basis for the modeling of structural and elastic properties of more complex composite ceramics. In order to simulate macroscopic material properties of composite ceramics from the material properties of the constituting phases, 3D finite element models were used. The influence of microstructural features such as pores and grain boundaries on the effective thermoelastic properties is studied through a diversity of geometries like truncated spheres in cubic and random arrangement, modified Voronoi polyhedra, etc. A 3D model is used for modeling the microstructure of the ceramic samples. The measured parameters, like volume fractions of the two phases, grain size ratios and grain boundary areas are calculated for each structure. The theoretical model is then varied to fit the geometrical data derived from experimental samples. The model considerations are illustrated on two types of bi-continuous materials, a porous ceramic, alumina (Al2O3) and a dense ceramic, zirconia-alumina composite (ZA). For the present study, alumina samples partially sintered at temperatures between 800 and 1320 C, with fractional densities between 58.4\% and 97\% have been used. For ZA ceramic the zirconia powder was partially stabilized and the ratio between alumina and zirconia was varied. For these two examples of ceramics, Young's modulus and thermal conductivity were calculated and compared to experimental data of samples of the respective microstructure. Comparing the experimental and simulated values of Young's modulus for Al2O3 ceramic a good agreement was obtained. For the thermal conductivity the consideration of thermal boundary resistance (TBR) was necessary. It was shown that for different values of TBR the experimental data lie within the simulated thermal conductivities. In the case of ZA ceramic also a good agreement between simulated and experimental values was observed. For smaller ZrO2 fractions, a larger Young's modulus and thermal conductivity was observed in the experimental samples. The discrepancies have been discussed by taking into account the effect of pressure. Considering the dependence of the thermoelastic properties on the pressure, it has been shown that the thermal stresses resulting from the cooling process were insufficient to explain the discrepancies between experimental and simulated thermoelastic properties.}, subject = {Finite-Elemente-Methode}, language = {en} } @phdthesis{Klukowska2004, author = {Klukowska, Anna}, title = {Switching hybrid polymers with physically and covalently entrapped organic photochromes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-11721}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {The aim of this work was to test and tailor new sol gel derived hybrid polymer coatings for the incorporation of photochromic spirooxazines and chromenes. The development and optimisation of work was performed via two different routes (dye and matrix ones), that led to photochromic multi-layer coating systems with coloration depth and photostabilities comparable to commercially available products. Hybrid sol-gel derived polymers were found to be suitable host materials for photochromic dyes. Matrix properties and the type of entrapment heavily influence the photochromic activity, as well as the degradation rate and the kinetics of incorporated dyes. Dyes incorporated within more polar and rigid matrices were found to show slower kinetics and higher coloration but associated with faster photodegradation. On the other hand, hosts with less polar sites, low residual water concentration and low rigidity are preferable in terms of photostability. Significant differences were found for physically incorporated and covalently grafted chromophores. Using silylated dyes that can participate in the sol-gel process, the photodegradation rate of the whole system can be decreased as compared to the physically entrapped systems. The higher photostability and slower kinetics for covalently bonded photochromes is probably due to sterical hindrance. Addition of proper stabilisers increases the photostability: The employment of UV light stabilisers, excited state quenchers and HALS was found to be beneficial but not sufficient. Besides the presence of stabilisers, also the reduction of oxygen migration into the coating (by a hard top coat and an inorganic anti reflective coating) strongly increases stability of photochromes. Finally, it was found that the separation of photochromes within two (or more) different layers leads to a further improvement of the coloration and fatigue behaviour of the whole coating stack, presumably by preventing the contact of dye molecules with excited states of other molecules or their degradation products. These latter findings are considered to pave the way for stable photochromic coatings based on hybrid polymers. Future development should be directed towards more photostable yellow and red switching dyes. The results of the present investigations should help to choose the most suitable molecular environments for the tested photochromes in terms of photostability, kinetics and activity, which is considered relevant with respect to potential applications, in particular in the ophthalmic sector. Furthermore, the interesting combination of properties of this type of materials offers a large potential with regard to many applications, such as coatings for sunglasses, radiation protectors, filters, sunroofs, reversible markings, printing applications and smart textiles.}, subject = {Metallorganische Polymere}, language = {en} } @phdthesis{Kahlenberg2004, author = {Kahlenberg, Frank}, title = {Structure-property correlations in fluoroaryl functionalized inorganic-organic hybrid polymers for telecom applications}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-9378}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {The development and in-depth characterization of new fluoroaryl functionalized ORMOCER® materials (inorganic-organic hybrid polymers) for optical waveguide applications in telecommunication is presented. The preparation of the materials included precursor silane synthesis, hydrolysis/polycondensation of organoalkoxysilane mixtures, and photolithographic processing of the resulting oligosiloxane resins in order to establish the inorganic-organic hybrid network. During all stages of ORMOCER® preparation, structure-property relations were deduced from characterization data, particularly with respect to low optical loss in the important near-infrared spectral region as well as refractive index. With the aid of molecular modeling, structural characteristics of oligomeric intermediates were visualized, which was found valuable in the fundamental understanding of the material class. The material development started with the syntheses of a variety of commercially unavailable fluorinated and unfluorinated arylalkoxysilanes by means of Grignard and hydrosilylation pathways, respectively. A survey of silane optical properties, particularly their absorptions at the telecom wavelengths 1310 nm and 1550 nm, gave an impulse to the choice of suitable precursors for the preparation of low-loss ORMOCER® resins. Accordingly, precursor silane mixtures and hydrolysis/polycondensation reaction conditions were chosen and optimized with regard to low contents of C-H and Si-OH functions. Thus, absorptions as low as 0.04 dB/cm at 1310 nm and 0.18 dB/cm at 1550 nm, respectively, could be obtained from an oligosiloxane resin based on pentafluorophenyltrimethoxysilane (1) mixed with pentafluorophenyl(vinyl)-dimethoxysilane (5). In order to improve the organic crosslinkability under photolithographic processing conditions, further resins on the basis of the aforementioned were prepared, which additionally incorporated the styrene-analogous precursor 4-vinyltetrafluorophenyl-trimethoxysilane (4). Thus, ORMOCER® resins with low optical losses of 0.28 dB/cm at 1310 nm and 0.42 dB/cm at 1550 nm, respectively, were prepared, which exhibited excellent photopatternability. The manufacture of micropatterns such as optical waveguide structures by UV-photolithography under clean room conditions was the final stage of material synthesis. The optimization of processing parameters allowed the preparation of test patterns for the determination of optical, dielectrical and mechanical properties. A low optical loss of 0.51 dB/cm at 1550 nm could be measured on a waveguide manufactured from a photopatternable fluoroaryl functionalized ORMOCER®. The structural characterization of liquid resins as well as cured ORMOCER® samples was accomplished chiefly with solution and solid state 29Si-NMR spectroscopy, respectively. Particularly for polycondensates incorporating species based on more than one precursor silane, the spectra showed a high degree of complexity. An additional challenge arouse from the partial loss of fluoroaryl groups during ORMOCER® condensation and curing, which resulted in even more condensation products. Thus, in order to provide a basis for resin analysis, first the hydrolysis/condensation reactions of the isolated precursors were investigated under reaction time-resolution with NMR spectroscopy at low temperature. Backed by signal assignments in these single-precursor systems, the respective species could also be identified in the complex resin spectra, allowing for their quantitative interpretation. The structural characterization was rounded out by IR spectroscopy and SAXS analyses. With the help of molecular modeling, the experimental data were finally transferred into a three-dimensional image of an organosiloxane oligomer, which is representative for a photopatternable fluoroaryl functionalized ORMOCER® resin. The combination of low-temperature NMR, which made the characterization of polycondensates possible, with oligomer modeling paved the way to a further understanding of ORMOCER® resin systems. On the basis of this visualization of structural characteristics, e.g. properties such as organic crosslinkability of oligomers were discussed in the light of steric features within the molecular structure. Thus, new possibilities were established for the systematic optimization of ORMOCER® formulations. Structure-property relations with respect to optical loss and refraction, as determined within this work, follow trends, which are in accordance with the literature. Particularly the direct comparison of data derived from analogous fluorinated and unfluorinated ORMOCER® resins showed that fluorination results in significant decrease in NIR optical loss. Additionally, different unfluorinated aryl functionalized systems with varying aliphatic C-H content were compared. In case of a lower aliphatic content, a widening effect on the 1310 nm window was found. This is due to a shift of arylic C-H vibrations (1145 nm) towards lower wavelengths compared to aliphatic C-H (1188 nm). Finally, on the basis of NIR spectra of analogous fluorinated resins with low and high silanol content, respectively, a significant impact of (Si)O-H groups on the 1550 nm window was demonstrated, while the 1310 nm window was unaffected. This is due to O-H vibrations with a maximum at 1387 nm and further bands at higher wavelength. The index of refraction was drastically lowered due to fluorination. Thus, the analogous fluorinated and unfluorinated ORMOCER® resins had indices of 1.497 and 1.570, respectively, in the VIS region. For the fluorinated systems, refraction did not change significantly during organic cross-connection and hardbake. In conclusion, the new fluoroaryl functionalized ORMOCER® systems represent low-loss materials for telecom applications. In addition, in-depth characterization during material development allowed the proposal of structure-property relations, particularly with respect to optical properties, which are of considerable importance for future developments.}, subject = {Ormocer}, language = {en} }