@phdthesis{Dem2003, author = {Dem, Claudiu Dorin}, title = {Design and construction of a device for light scattering studies on airborne particles}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-9605}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2003}, abstract = {This thesis is concerned with the development of an on-line in-situ device for a chemical characterisation of flowing aerosols. The thesis describes the principles and most important features of such a system, allowing also on-line measurements using Raman spectroscopy as a diagnostic technique An analysis of the effect of forced oscillations on the motion of the particle dispersed in a gas flow is given in Chapter 2. Also the most important particle parameters are introduced. A review of the particle/fluid interaction in laminar air flows and the response of the particle is presented. In Chapter 3 the behaviour of the particle under different external conditions (ion bombardment and electric fields) is extended. A brief review of the most important particle charging theories (diffusion, field, and alternating potential charging) shows, that the effect of the electrical properties (represented by the dielectric constant) of the particles affects the charging process. A non-contact method for particle charge measurement was also presented. In the second part of the chapter, the interaction between the electric field and the charged particle for the purpose of particle trapping is illustrated. The most common systems like the two or four ring electrodynamic balance and the quadrupole trap are pointed out. In Chapter 4 a short review of the possibility of using scattered light to study aerosol particles is presented. First, the conditions and the facilities of using the Mie theory for particle size and refractive index determination are mentioned, then some features concerning the classical treatment of the Raman effect are presented Supported by the theoretical considerations exposed in Chapter 2, 3, and 4 the construction and the tests of different devices are presented in Chapter 5. Following the goal of the thesis, first an overview of the used materials and methods for particle generation is presented. Then, the constructed charging devices are described (from the mechanical and electrical point of view) and compared by measuring the acquired charge on the particle. Charged particles can be trapped in different containers. Two types of axially symmetric electrodynamic balances (two ring or an extended four ring configuration) were presented. For a deeper understanding these systems were studied using analytic and numerical methods. Considering the presented purpose of the work another type of trapping system has been developed, namely the quadrupole trap. A similar theoretical characterisation (in term's of Mathieu equation) as for the electrodynamic balance was presented pointing out some specific features of this system. The incoming particle stream will be focused to the centre of the system simultaneously also the applied DC and AC potential onto the tube electrodes, yields a stable trapping of one or more particles. Chapter 6 consists of two parts: the system for single particle and for many particles investigation. The individual devices presented in Chapter 5 are now put together. The first part presents the method and the experimental realisation of a set-up for solid particle injection. In order to suppress the phase injection disadvantage found for the electrodynamic balance a developed program processes the information obtained from a particle cloud through an adequate electronic detection system, and reduces the number of particles until just one single particle is trapped. The method for one particle investigation can be extended for many particles. Using the presented set-up the particles are moved from one quadrupole to another and transformed from a particle cloud to a particle stream. A linearity between an external vertical mounted detector and the formed image of the particle stream on the CCD camera has been observed and used for simultaneous detection of many particles by Raman spectroscopy. For both methods Raman results are presented. One limitation of Raman Spectroscopy is the relatively long integration time needed for adequate signal-to-noise ratio. There are two factors which influence the integration time: first the incident radiation and the detector sensitivity, and second the intensity of the Raman bands. Using a CCD detector, the desired detector sensitivity should be achieved. So, the improvement of the signal-to-noise ratio should be the next goal in the system development. In order to reduce the integration time an optical system including optic fibres and the integration of an FT-Raman module operating in the visible region is planed. The goal of this work was to develop and construct an instrument for on-line in-situ single particle investigation by Raman spectroscopy. With the presented experimental set-up and the developed program the purpose of the work, the on-line in-situ near atmospheric pressure aerosol investigation was achieved. The Raman spectroscopy has been used successfully for a chemical characterisation of the aerosol particles.}, subject = {Aerosol}, language = {en} } @phdthesis{Tarcea2004, author = {Tarcea, Nicolae}, title = {Light as a universal tool : Microcapsule sizing by elastic light scattering and mineral investigation by in situ Raman spectroscopy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-9383}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {The present work consist of two major parts. The first part, extending over chapters 1, 2, 3 and 4, addresses the design and construction of a device capable of determining the shell thickness and the core size for monolayer spherical particles in a flow. The second part containing chapters 5, 6, 7, 8, 9 and 10, concentrate on the use of Raman spectroscopy as a space application, namely for use as a tool for in situ planetary investigations. This part directly addresses the MIRAS project, a study run under the auspices of Federal Ministry of Education and Research, BMBF and German Aerospace Center, DLR under national registration number 50OW0103. MIRAS stands for "Mineral Investigation by in situ Raman Spectroscopy". Microcapsule Sizing by Elastic Light Scattering The industrial development of processes based on microcapsules depends on the possibility to provide clear and complete information about the properties of these microcapsules. However, the tools for an easy and efficient determination of the microcapsule properties are lacking, several methods being often required to describe adequately the microcapsule behavior. Methods for evaluating the individual size and size distribution of both the core and the shell are required together with methods for measuring the mechanical strength, stability in appli-cation media, permeability of the shell, etc. Elastic light scattering measurements provide a possible way of determining properties such as core size, shell size and refractive index. The design and con-struction of a device capable of measuring the above mentioned parameters for a core-shell particle is the subject of the first part of this thesis. The basic principle of measurement for the device proposed here consists of an-alyzing one particle at a time by recording the elastic light scattering pattern at angles between approx. 60 and 120 grad. By comparing the experimentally recorded phase functions with the previously calculated phase functions stored in a database, the geometry of the scattering object can be identified. In our case the geometry is characterized by two parameters: the shell thickness and the core radius. In chapter 2 a short overview on the methods used for sizing microparticles is given. Different sizing methods are compared, and the advantages and disadvan-tages for the general problem of sizing are shortly discussed. It is observed that all sizing methods that are based on elastic light scattering theories are ensemble methods. Chapter 3 focusses on the theories used for calculating the theoretical scattering patterns with emphasize on the Mie theory. The generalization of Mie theory for layered particles is shortly presented and the far field intensity approximations are discussed. The last chapter (4) of this first part describes the experimental approach for building an automatic microcapsule sizer. The approach started by O. Sbanski [76] with the development of a software packet for calculating and storing theoret-ical phase functions for core-shell particles was continued with the designing and construction of a measuring device. The hardware construction and the software with all implemented corrections imposed by the individual setup components are described in detail. For the laser, the monochromaticity, the intensity profile of the beam as well as the planarity of the equi-phase fronts are taken into consid-eration. The flow cell with three different designs is described, and the influences of the employed design on the light scattering patterns are discussed together with the optical system used for recording the experimental phase functions. The detection system formed by two identical linear CCD arrays is presented together with the software approach used for data acquisition. Ways of improving the quality and the speed of the analyzing process are discussed. The final section presents measurements run on samples made of homogeneous spheres and also on samples containing industrial microcapsules. Mineral Investigation by in situ Raman Spectroscopy The envisaged future planetary missions require space-born instruments, which are highly miniaturized with respect to volume and mass and which have low needs of power. A micro Raman spectrometer as a stand alone device on a planetary surface (e.g. Mars) offers a wide spectrum of possibilities. It can assess the chemical analysis via determination of the mineral composition, detect organic molecules in the soil, identify the principal mineral phases, etc. The technical developments in the last years have introduced a new generation of small Raman systems suitable for robotic mineral characterization on planetary surfaces [20, 95]. Two different types of spectrometer were considered for the MIRAS study. As supporting laboratory experiments for the MIRAS study, the measure-ments on standard minerals and on SNC Mars meteorites are discussed in chapter 6. The following SNC meteorites have been investigated: Sayh al Uhaymir 060, Dar al Gani 735, Dar al Gani 476, Northwest Africa 856, Los Angeles, Northwest Africa 1068 and Zagami. Pyrite as a hitherto undescribed phase in the picritic (olivin-phyric) shergottite NWA 1068 as well as reduced carbon (e.g. graphite) and anatase in the shergottite Say al Uhaymir 060 are new findings for this class of meteorites. A detailed description of the proposed designs for MIRAS, with the compo-nents used for building the test version on a breadboard is covered in chapter 7. The scientific as well as the mission requirements imposed on the instrument are discussed. The basic design is presented and the main components that are brought together to build the device being the laser unit, the Raman head, the Rayleigh filtering box, and the spectral sensor (spectrometer with a matching de-tector) are described. The two proposed designs, one based on an acousto-optic tunable filter (AOTF) and the other based on a dispersive hadamard transform spectrometer are compared to each other. The actual breadboard setup with the detailed description of the components follows in Section 7.3. Further de-velopment of a Raman spectrometer for planetary investigations is proposed in combination with a microscope as part of the Extended-MIRAS project. The software developed for controlling the breadboard version of MIRAS is described in chapter 8 together with a short description of the structure of a relational database used for in house spectra management. The measuring pro-cedures and the data processing steps are presented. Spectra acquired with the MIRAS breadboard version based on the AOTF are shown in chapter 9. The final chapter addresses a rather different possibility of using Raman spectroscopy for planetary investigations. The chapter summarizes the content of four tech-nical notes that were established within the study contracted by the European Space Agency with firma Kayser-Threde in Munich concerning the possibility of applying Raman spectroscopy in the field of remote imaging.}, language = {en} } @phdthesis{Gessner2003, author = {Geßner, Ralph}, title = {Untersuchungen an biologischen Proben mit verschiedenen Raman- und SERS-spektroskopischen Techniken}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-8626}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2003}, abstract = {Diese Arbeit befasst sich mit der Entwicklung und Erprobung geeigneter Methoden zur Raman-spektroskopischen Untersuchung empfindlicher, insbesondere biologischer Proben. Das Ziel dabei ist, ein Werkzeug zur Verf{\"u}gung zu stellen, mit dem es m{\"o}glich ist, detaillierte Informationen {\"u}ber die Inhaltsstoffe einer Probe und deren r{\"a}umlichen Verteilung zu sammeln. Diese Daten sind beispielsweise f{\"u}r die Qualit{\"a}tssicherung pharmazeutischer Produktionen notwendig. Zu diesem Zweck wurden zwei verschiedene Ans{\"a}tze verfolgt: ein Raman-Spektrometer wurde zum einen mit einer Glasfasersonde, zum anderen mit einer optischen Gradientenfalle kombiniert. Beide Ans{\"a}tze wurden getestet und mit ihnen biologische Fragestellungen bearbeitet. Die Empfindlichkeit biologischer Proben und die geringe Konzentration ihrer Inhaltsstoffe macht es dabei notwendig, besonderen Wert auf probenschonende Messverfahren und eine hohe Nachweisempfindlichkeit zu legen. Die Raman- bzw. SERS-Spektroskopie ist hierzu in der Lage und erfordert gleichzeitig nur eine minimale Probenpr{\"a}paration. Anhand der pr{\"a}sentierten Experimente konnte gezeigt werden, dass sich die SERS-Glasfasersonde besonders zur Untersuchung empfindlicher Proben eignet. Insbesondere erlaubt sie minimal-invasives Arbeiten an biologischen Materialien. Es konnte außerdem gezeigt werden, dass die Sonde aufgrund ihrer geometrischen Beschaffenheit eine gute Ortsaufl{\"o}sung, bis in den Sub-Mikrometerbereich, bei den Messungen erlaubt. Daher eignet sich die Fasersonde besonders zur Untersuchung von hochempfindlichen biologischen Proben bei gleichzeitig sehr geringem Probenbedarf. Mit der optischen Gradientenfalle, als zweite Methode, hat man ein Werkzeug zur Hand, mit dem es m{\"o}glich ist, einzelne Mikroorganismen oder Mikropartikel in Suspension zu vermessen. Bei Arbeit mit der optischen Gradientenfalle ist eine freie, dreidimensionale Manipulation der gefangenen Zellen im Probengef{\"a}ß m{\"o}glich. Auf diese Weise k{\"o}nnen einzelne Zellen {\"u}ber l{\"a}ngere Zeit stabil im Laserfokus gehalten werden, wodurch l{\"a}ngere Integrationszeiten m{\"o}glich werden. Außerdem kann man auf diese Weise eine Immobilisierung der suspendierten Zellen auf einer funktionalisierten Oberfl{\"a}che vermeiden, wodurch unerw{\"u}nschte Effekte auf das zu messende Spektrum, wie z. B. Verschiebungen einzelner Banden oder {\"A}nderungen in den relativen Bandenintensit{\"a}ten, ausgeschlossen werden k{\"o}nnen. Zur Untersuchung partikul{\"a}rer Verunreinigungen ist es nicht notwendig, die L{\"o}sung aus dem Gef{\"a}ß heraus zu pr{\"a}parieren. Vielmehr k{\"o}nnen die Mikropartikel durch die optische Gradientenfalle in der L{\"o}sung festgehalten und spektroskopisch identifiziert werden. Dies erm{\"o}glicht beispielsweise die Charakterisierung von Verunreinigungen in pharmazeutischen L{\"o}sungen, ohne dass daf{\"u}r Ampullen ge{\"o}ffnet werden m{\"u}ssten. Auf diese Weise k{\"o}nnen Kontaminantien identifiziert werden, ohne Gefahr zu laufen, bei der Probenpr{\"a}paration weitere Verunreinigungen zu verursachen und damit die Messungen zu verf{\"a}lschen. Durch die Kombination eines Raman-mikroskopischen Aufbaus mit der SERS-Glasfasersonde bzw. der optischen Gradientenfalle ist es gelungen, Fragestellungen an biologischen Systemen in sehr Proben-schonender, aber gleichzeitig hoch-ortsaufl{\"o}sender Weise zu bearbeiten. Durch die Verwendung nicht-kontaminierender SERS-Sonden ist es m{\"o}glich, zus{\"a}tzliche Verst{\"a}rkungseffekte zu erzielen. Die verwendeten Anregungslaserleistungen k{\"o}nnen daher generell niedrig gehalten werden. Dennoch erh{\"a}lt man aussagekr{\"a}ftige Spektren in einer akzeptablen Zeit. Die Zwei-Laser-L{\"o}sung f{\"u}r die optische Gradientenfalle stellt ein zuverl{\"a}ssiges Werkzeug zur ber{\"u}hrungsfreien Manipulation kleiner Partikel bei gleichzeitiger Flexibilit{\"a}t in Bezug auf die Anregungswellenl{\"a}nge dar.}, subject = {Biologisches Material}, language = {de} } @phdthesis{Pavel2003, author = {Pavel, Ioana-Emilia}, title = {Vibrational spectroscopy and density functional theory calculations, a powerful approach for the characterization of pharmaceuticals and new organometallic complexes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-7186}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2003}, abstract = {In the current work, several well-known pharmaceuticals (1,4-dihydrazinophthalazine sulfate, caffeine, and papaverine hydrochloride) and new organometallic compounds (nickel(II) cupferronato complexes NiL2An, L = PhN2O2-, n = 1, A = o-phenanthroline (1), o,o'-bipyridine (2) and n = 2, A = H2O (3), o-NH2Py (4), o-C6H4(NH2)2 (5); silylene-bridged dinuclear iron complexes [Cp(OC)2Fe]2SiX2 (X = H (6), F (7), Cl (8), Br (9), I (10)); 3-silaoxetane 3,3-dimethyl-2,2,4,4-tetraphenyl-1-oxa-3-silacyclobutane (11) and 3-silathietane 3,3-dimethyl-2,2,4,4-tetraphenyl-1-sila-3-thiacyclobutane (12) compounds), which have successfully been characterized by using vibrational spectroscopy in conjunction with accurate density functional theory (DFT) calculations, are presented. The DFT computed molecular geometries of the species of interest reproduced the crystal structure data very well and in conjunction with IR and Raman measurements helped us to clarify the structures of the compounds, for which no experimental data were available; and this, especially for the new organometallic compounds, where the X-Ray analysis was limited by the non-availability of single crystals (3, 5, 10). Furthermore, a natural population analysis (NPA) and natural bond orbital (NBO) calculations together with a detailed analysis of the IR and Raman experimental as well as calculated spectra of the new organometallic compounds, allowed us to study some special bonding situations (1-12) or to monitor the structural changes observed with the change in temperature during the Raman experiments (11, 12). By combining these two methods (DFT and vibrational spectroscopy), the auspicious results obtained on the organometallic compounds 6-12 and overall in literature, made us confident of the power of theoretical calculations in aiding the interpretation of rich SERS spectra by solving some interesting issues. Consequently, the Raman and SERS spectra of well-known pharmaceuticals (1,4-dihydrazinophthalazine sulfate, caffeine, and papaverine hydrochloride) or new potentially biological active organometallic complexes (1-5), that were synthetized by our coworkers, were discussed with the assistance of the accurate results obtained from DFT calculations (structural parameters, harmonic vibrational wavenumbers, Raman scattering activities), and many previous incomplete assignments have been analyzed and improved. This allowed us to establish the vibrational behavior of these biological compounds near a biological artificial model at different pH values or concentrations (Ag substrate), taking into account that information about the species present under particular conditions could be of great importance for the interpretation of biochemical processes. The total electron density of molecules and the partial charges situated on selected atoms, which were determined theoretically by NPA, allowed us to establish the probability of different atoms acting as an adsorptive site for the metal surface. Moreover, a closer examination of the calculated orbitals of molecules brought further arguments on the presence or absence of the photoproducts at the Ag surface during the irradiation (1,4-dihydrazinophthalazine sulfate). Overall, the results provide a benchmark illustration of the virtues of DFT in aiding the interpretation of rich vibrational spectra attainable for larger polyatomic adsorbates by using SERS, as well as in furnishing detailed insight into the relation between the vibrational properties and the nature of the Ag substrate-adsorbate bonding. Therefore, we strongly believe that theoretical calculations will become a matter of rapidly growing scientific and practical interest in SERS.}, subject = {Arzneimittel}, language = {en} } @phdthesis{Strehle2003, author = {Strehle, Marion A.}, title = {Mikroskopische und spektroskopische Charakterisierung biologisch relevanter Oberfl{\"a}chen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-5775}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2003}, abstract = {In dieser Arbeit werden biologisch relevante Oberfl{\"a}chen untersucht, die in der Medizin bzw. in der Biologie eine wichtige Rolle spielen. Die Proteinadsorption auf Implantat-Oberfl{\"a}chen wurde charakterisiert, um wichtige Informationen {\"u}ber den Adsorptionsprozess zu erhalten. Das Fernziel hierbei ist, durch ein umfassendes Wissen {\"u}ber diesen f{\"u}r die Implantation wichtigen Schritt Biomaterialien mit m{\"o}glichst hoher Gewebevertr{\"a}glichkeit zu entwickeln. Die Verteilung von Propolis auf der Wachs-Oberfl{\"a}che von Bienenwaben wurde untersucht, um mehr {\"u}ber dessen Nutzen, der noch nicht vollst{\"a}ndig aufgekl{\"a}rt ist, zu erfahren und um auf m{\"o}gliche Auswirkungen einer ver{\"a}nderten Wabenstruktur auf die Kommunikation der Honigbienen R{\"u}ckschl{\"u}sse ziehen zu k{\"o}nnen. Das Ziel des ersten Teils dieser Arbeit war, das Adsorptionsverhalten der Proteine Fibrinogen, Albumin und Fibronektin auf Titandioxid, einem in der Medizin h{\"a}ufig als Implantat eingesetzten Material, zu studieren. Die Adsorption von Proteinen auf der Oberfl{\"a}che von Implantaten ist ein wichtiger Schritt f{\"u}r die Gewebevertr{\"a}glichkeit bzw. Biokompatibilit{\"a}t dieser Materialien. Es wurden sowohl die r{\"a}umliche Verteilung der Proteine auf den Implantat-Oberfl{\"a}chen als auch die durch die Adsorption hervorgerufenen strukturellen Ver{\"a}nderungen der Proteine untersucht. Als Methoden wurden hierf{\"u}r die Laser-Raster-Mikroskopie (LSM), die Kraftfeldmikroskopie (AFM) sowie die Raman-Spektroskopie eingesetzt. Durch ein umfassendes Wissen {\"u}ber den Adsorptionsprozess der Proteine auf Implantat-Materialien k{\"o}nnen die Oberfl{\"a}chen der Implantate dahingehend ver{\"a}ndert werden, dass es zu einer besseren Proteinadsorption und dadurch zu einer noch geringeren Rate an Abstoßungsreaktionen kommt. Die in dieser Arbeit vorgestellten Ergebnisse k{\"o}nnen einen Teil zum Verst{\"a}ndnis des Adsorptionsprozesses beitragen. Das Ziel des zweiten Teils dieser Arbeit war es, die chemische Zusammensetzung von Propolis (dem Kittharz der Bienen) und Wabenwachs von Apis mellifera carnica Pollm. sowie die r{\"a}umliche Verteilung von Propolis auf den Waben-Oberfl{\"a}chen zu untersuchen. Hierzu wurden die Raman-Spektroskopie und Raman-Mapping eingesetzt. Es wurden zun{\"a}chst Raman-Spektren von Propolis-Proben sowie Raman-Spektren von charakteristischen Standardsubstanzen des Propolis aufgenommen. Das Propolis-Spektrum sowie das Wachs-Spektrum wurden durch eine Auswahl an Standardsubstanzen simuliert. Um herauszufinden, welche Harze von den Bienen gesammelt und als Propolis im Stock verwendet werden, wurden von einigen Harzen, die als Propolis-Quellen in Betracht kommen, Raman-Spektren aufgenommen. Es wurde auch analysiert, ob die Kettenl{\"a}ngen der Alkane, aus denen die Wachse bestehen, einen Einfluss auf die Raman-Spektren hat. Mittels Raman-Mapping wurde schließlich die r{\"a}umliche Verteilung von Propolis auf der Waben-Oberfl{\"a}che untersucht. Die hier charakterisierten biologisch relevanten Oberfl{\"a}chen spielen eine wichtige Rolle in der Medizin und in der Biologie. Die Analyse mit mikroskopischen und spektroskopischen Methoden verschafft einen Einblick in die Prozesse, die sich an diesen Oberfl{\"a}chen abspielen. Die Proteinadsorption auf Implantat-Oberfl{\"a}chen sind f{\"u}r die Implantationsmedizin von Bedeutung. Es werden st{\"a}ndig neue Materialien entwickelt, die eine m{\"o}glichst gute Biokompatibilit{\"a}t aufweisen sollen. Erkenntnisse {\"u}ber die Prozesse, die hierf{\"u}r eine Rolle spielen, helfen bei der Entwicklung neuer Materialien. Die Verteilung von Propolis auf den Wachs-Oberfl{\"a}chen hat einen Einfluss auf die Materialbeschaffenheit der Waben. Dies k{\"o}nnte die Vibrationsweiterleitung beim Schw{\"a}nzeltanz der Honigbienen, der f{\"u}r deren Kommunikation von Bedeutung ist, beeinflussen. Die Verteilung des Propolis auf den Waben konnte f{\"u}r kleine Ausschnitte gezeigt werden. Inwiefern eine Propolisschicht auf den Stegen der Waben die Vibrationsweiterleitung tats{\"a}chlich beeinflusst, muss durch weiterf{\"u}hrende Experimente herausgefunden werden.}, subject = {Implantat}, language = {de} } @phdthesis{Meuer2002, author = {Meuer, Petra}, title = {Spektroskopische Untersuchungen an Kammerwasser}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-4974}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {Ziel dieser Arbeit war es, die M{\"o}glichkeiten zur Verwendung des Auges bzw. der Augenvorderkammer als spektroskopische Zelle f{\"u}r nicht-invasive In-vivo-Messungen zu untersuchen. Dabei stand vor allem die Ger{\"a}te-technische Umsetzung und die Entwicklung geeigneter Auswertestrategien im Vordergrund. In dieser Arbeit konnte gezeigt werden, dass die spektroskopische Untersuchung von Kammerwasser-Substanzen m{\"o}glich ist. Durch den Einsatz der UV/VIS-Spektroskopie konnte Fluorescein in vivo bestimmt werden. Die Anwendung der NIR-Spektroskopie eignet sich vor allem zur Bestimmung von Glucose im Kammerwasser. Die G{\"u}te der Glucose-Bestimmung ist von verschiedenen Faktoren abh{\"a}ngig, wie z. B. dem verwendeten Ger{\"a}t, den Parameter der Auswertung und der Temperatur. F{\"u}r weitergehende Studien sollten daher die in dieser Arbeit aufgedeckten Probleme und Strategien beachtet werden.}, subject = {Blutzucker}, language = {de} } @phdthesis{Flachenecker2002, author = {Flachenecker, G{\"u}nter}, title = {Die Dissoziations- und Rekombinations-Reaktion von Jodmolek{\"u}len in mikropor{\"o}sen Porosil-Kristalliten auf der Femtosekunden-Zeitskala}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-4472}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {In dieser Arbeit wurde die unimolekulare Dissoziations- und Rekombinations-Reaktion von Jodmolek{\"u}len untersucht, die in mikropor{\"o}sen Porosil-Kristalliten eingelagert waren. Hierf{\"u}r wurden sowohl experimentelle Pump-Probe-Experimente als auch theoretische Untersuchungen auf der Femtosekunden-Zeitskala durchgef{\"u}hrt. Die Idee, die diesen Experimenten zugrunde lag, bestand darin, zu erfahren, in welcher Weise und in welchem Maße die Struktur der Umgebung einen Einfluss auf die elementaren dynamischen Prozesse der Reaktion aus{\"u}bt. Die hier untersuchten Systeme I\$_2\$ in DDR-, TON-, FER- und MFI-Porosilen sind Modellsysteme f{\"u}r komplexere Molek{\"u}le, eingelagert in einer mikropor{\"o}sen kristallinen Umgebung.}, subject = {Tectosilicate}, language = {de} } @phdthesis{Baia2002, author = {Baia, Gheorghe Lucian}, title = {Theory and applications of confocal micro-Raman spectroscopy on hybrid polymer coatings and PDMS membranes and spectroscopic studies of doped B2O3-Bi2O3 glass systems}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-4606}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {The thesis consists of two major parts. The first part contains a theoretical-experimental study of confocal micro-Raman spectroscopy on hybrid polymer coatings and an application of this spectroscopic method on PDMS-membranes. The theoretical-experimental study includes the application of a model that describes the influence of the refraction effect on the focus length on confocal Raman experiments, and the development of a new model that additionally takes into account the effect of diffraction on the focus dimensions. A parallel comparison between these two theoretical approaches and experimental data has been also drawn and a better agreement between theory and experiment was observed, when both refraction and diffraction effects were considered. Further, confocal resonance micro-Raman spectroscopy has been applied to characterise the diffusion processes of pharmacologically relevant molecules (b-carotene dissolved in dimethylsulfoxide) through a polydimethylsiloxane (PDMS)-membrane. The diffusion rate as a function of the measurement depth and diffusion time as well as the concentration gradient under a steady flux have been determined. The measurements shown that the confocal micro-Raman technique is a powerful tool to investigate the kinetics of diffusion processes within a membrane before the steady state has been reached. The second part of the thesis contains infrared and Raman spectroscopic studies of copper and iron doped B2O3-Bi2O3 glass systems. These studies were performed to obtain specific data regarding their local structure and the role played by dopant ions on boron and bismuthate units. The changes of B2O3 and Bi2O3 structural units due to the relaxation of the amorphous structure, which was induced in these samples by the thermal treatment, were also evidenced.}, language = {en} } @phdthesis{Bolboaca2002, author = {Bolboaca, Monica-Maria}, title = {Vibrational characterisation of coordination and biologically active compounds by means of IR absorption, Raman and surface-enhanced Raman spectroscopy in combination with theoretical simulations}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-4616}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {The thesis contains two major parts. The first part deals with structural investigations on different coordination compounds performed by using infrared absorption and FT-Raman spectroscopy in combination with density functional theory calculations. In the first section of this part the starting materials Ph2P-N(H)SiMe3 and Ph3P=NSiMe3 and their corresponding [(MeSi)2NZnPh2P-NSiMe3]2 and Li(o-C6H4PPh2NSiMe3)]2·Et2O complexes have been investigated in order to determine the influence of the metal coordination on the P-N bond length. In the next section the vibrational spectra of four hexacoordinated silicon(IV) and germanium(IV) complexes with three symmetrical bidentate oxalato(2-) ligands have been elucidated. Kinetic investigations of the hydrolysis of two of them, one with silicon and another one with germanium, have been carried out at room temperature and at different pH values and it was observed that the hydrolysis reaction occurs only for the silicon compound, the fastest reaction taking place at acidic pH. In the last section of this part, the geometric configurations of some hexacoordinated silicon(IV) complexes with three unsymmetrical bidentate hydroximato(2-) ligands have been determined. The second part of the thesis contains vibrational investigations of some biologically active molecules performed by means of Raman spectroscopy together with theoretical simulations. The SER spectra of these molecules at different pH values have also been analysed and the adsorption behaviour on the metal surface as well as the influence of the pH on the molecule-substrate interaction have been established.}, subject = {Komplexe}, language = {en} } @phdthesis{Roesch2002, author = {R{\"o}sch, Petra}, title = {Raman-spektroskopische Untersuchungen an Pflanzen und Mikroorganismen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-3539}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2002}, abstract = {In dieser Arbeit werden Pflanzen, Pflanzengewebe, Pflanzenzellen und Mikro-organismen spektroskopisch untersucht und ihre Inhaltsstoffe unter minimaler Probenpr{\"a}paration im biologischen Gewebe direkt lokalisiert und identifiziert. Unter den verf{\"u}gbaren Schwingungs-spektroskopischen Methoden ist die Mikro-Raman-Spektroskopie f{\"u}r diese Fragestellungen besonders gut geeignet, da Wasser Raman-Spektren nur wenig beeinflusst. Daher kann mit Raman-spektroskopischen Methoden auch in stark wasserhaltigem Gewebe gemessen werden. Weiterhin erh{\"a}lt man mit der Mikro-Raman-Spektroskopie eine gute r{\"a}umliche Aufl{\"o}sung im sub-µm-Bereich, wodurch es m{\"o}glich ist, heterogene Proben zu untersuchen. Dar{\"u}ber hinaus kann die Mikro-Raman-Spektroskopie mit anderen Methoden, wie z. B. der oberfl{\"a}chenverst{\"a}rkten Raman-Spektroskopie (SERS), kombiniert werden. In pflanzlichen Zellen liegt eine Vielzahl von Substanzen in geringen Konzentrationen vor. Aufgrund der niedrigen Quantenausbeute des Raman-Effekts treten vor allem Substanzen, die eine Resonanz-Verst{\"a}rkung erfahren, in den Spektren hervor. Diese Substanzen, wie z. B. b-Carotin, k{\"o}nnen deshalb in geringen Konzentrationen detektiert werden. Der Schwerpunkt dieser Arbeit liegt in der Untersuchung von Sekund{\"a}r-Metaboliten wie Alkaloiden, Lipiden oder Terpenen, die in der Pflanze agglomerieren. Neben der Identifikation von Inhaltsstoffen, k{\"o}nnen die Raman-Spektren von Pflanzen f{\"u}r die chemotaxonomische Klassifizierung mit Hilfe der hierarchischen Clusteranalyse verwendet werden. Die Identifizierung von Mikroorganismen auch in sehr geringen Mengen (Monolage, einzelne Zellen) ist mit der Mikro-Raman-Spektroskopie nur unter bestimmten Voraussetzungen durchf{\"u}hrbar. F{\"u}r weitergehende Untersuchungen wird hier die SERS-Sonde oder ein TERS-Aufbau verwendet werden.}, subject = {Pflanzen}, language = {de} }