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241	Synthèse,Relaxivité et Luminescence de complexes de lanthanides dérivés de ligands ditopiques et assemblages supramoléculaires Paris, Jérôme 07 October 2010 (has links) Lanthanide elements display many remarkable and exciting properties which explain their widespread use in a number of very important biomedical tools like efficient MRI contrast agents or luminescent probes for highly sensitive assays of bioanalytes amongst other fields of application. In this context, the aim of the present work was to prepare and characterize lanthanide complexes of two ligands that feature a linear or a macrocyclic chelating unit compactly grafted onto a 1,10-phenanthroline derived moiety (phenDTPA and PhenHDO3A). The ditopic nature of the ligands allows the selective incorporation of a d6 metal ion and a lanthanide one in close proximity. The resulting rigid heterobimetallic supramolecular species show useful properties and constitute potential MRI contrast agents or new luminescent compounds depending on the type of the lanthanide and transition metal ions employed: for example, the selfassembly process of gadolinium(III) chelates around an iron(II) ion brings a remarkable increase of their relaxivity, a key parameter for use in MRI. On the other hand, association of a ruthenium and and a near infrared emitting 4f ion like ytterbium(III) gives mixed d-f structures able to harvest visible light and convert it into near infra-red signal. Visible light luminescent pH probes were also obtained with Eu3+ or Tb3+ phenHDO3A complexes. Relaxivity/relaxivite luminescence/luiminescence phenanthronline ditopic ligand/ligand ditopique DTPA DOTA DO3A gadolinium europium ytterbium Near infra-red/ proche infra-rouge
242	Electronic Energy Transfer within Asymmetric Pairs of Fluorophores: Partial Donor-Donor Energy Migration (PDDEM) Kalinin, Stanislav January 2004 (has links) A kinetic model of electronic energy migration within pairs of photophysically non-identical fluorophores has been developed. The model applies to fluorescent groups that exhibit different photophysical and spectral properties when attached to different positions in a macromolecule. The energy migration within such asymmetric pairs is partially reversible, which leads to the case of partial donor-donor energy migration (PDDEM). The model of PDDEM is an extension of the recently developed donor-donor energy migration model (DDEM, F. Bergström et al, PNAS 96 (1999) 12477), and applies to quantitative measurements of energy migration rates and distances within macromolecules. One important distinction from the DDEM model is that the distances can be obtained from fluorescence lifetime measurements. A model of fluorescence depolarisation in the presence of PDDEM is also presented. To experimentally test the PDDEM approach, different model systems were studied. The model was applied to measure distances between rhodamine and fluorescein groups within on-purpose synthesised molecules that were solubilised in lipid bilayers. Moreover, distances were measured between BODIPY groups in mutant forms of the plasminogen activator inhibitor of type 2 (PAI-2). Measurements of both the fluorescence intensity decays and the time-resolved depolarisation were performed. The obtained distances were in good agreement with independent determinations. Finally, the PDDEM within pairs of donors is considered, for which both donors exhibit a nonexponential fluorescence decay. In this case it turns out that the fluorescence relaxation of a coupled system contains distance information even if the photophysics of the donors is identical. It is also demonstrated that the choice of relaxation model has a negligible effect on the obtained distances. The latter conclusion holds also for the case of donor-acceptor energy transfer. Physical chemistry donor-donor energy migration (DDEM) homotransfer fluorescence relaxation lifetimes time-resolved fluorescence anisotropy time-correlated single photon counting distance measurements protein structure Fysikalisk kemi Physical chemistry Fysikalisk kemi
243	Nature Of Solute-Solvent Interaction : Effect Of Solvent Polarity On Excited State Structure Of 2,2,2-Trifluroacetophenone And Effect Of Hydrogen Bonding In Hydrated Electron Absorption Spectrum Chowdhury, Brojokishore 11 1900 (has links) In solution, the environment around the solute is determined solely by the solvent molecules, which are present closer to the solute. This interaction between solute and solvent shell is very crucial for equilibrium structure and reactivity of the solute. In the thesis, first we have investigated control of solvent polarity on the excited structure of 2,2,2 trifluroacetophenone and later effect of electronic excitation on the solvent shell organization has been described. It has been reported in literature that the lowest energy triplet configuration of 2,2,2 trifluroacetophenone corresponds to n,π* state. There are some other reports in favor of the probable existence of 2,2,2 trifluroacetophenone in n,π* lowest triplet state. Thus, transient absorption and time resolved resonance Raman spectroscopic methods have been used along with theoretical calculations to investigate the discrepancy in the assignment of the lowest triplet state configuration It has been observed that the lowest triplet state of 2,2,2 trifluroacetophenone is indeed nπ* and there is a solvent polarity induced change in triplet state energy ordering and structure changes. The absorption spectrum of hydrated electron is broad and structureless. So, it was though that the broadening feature could be attributed to homogeneous and inhomogeneous broadening. Transient resonance Raman spectrum of the water bending mode in presence of hydrated electron has been recorded at different excitation wavelengths. Interestingly, it has been observed that, peak position of water bending mode in presence of hydrated electron alters with change of excitation wavelength. A model has been proposed based on the experimental data. Solute Solvent Interactions Trifluroacetophenone Hydrogen Bonding Raman Spectroscopy Solvent Polarity Hydrated Electron Absorption Spectra Phenyl Alkyl Ketones Transient Absorption Resonance Raman Time-resolved Absorption (TRA) Time-resolve Resonance Raman (TR3) Physical Chemistry
244	Ultrafast Dynamics in Quasi-One-Dimensional Organic Molecular Crystals / Self-Assembled Monolayers of Photochromic Molecules / Ultraschnelle Dynamik in quasi-eindimensionalen organischen Molekülkristallen / Selbst-assemblierte Monoschichten photochromer Moleküle Canzler, Tobias W. 16 September 2002 (has links) (PDF) Der erste Teil der Arbeit beschäftigt sich mit ultraschnellen Relaxationsprozessen in quasi-eindimensionalen organischen Molekülkristallen. Als Modellsystem wird das Perylenderivat MePTCDI untersucht. Mit verschiedenen Methoden der optischen Ultrakurzzeit-Spektroskopie werden Prozesse der Exzitonen- und Phononenrelaxation in der Zeit-Domäne untersucht. Die dafür aufgebauten Experimente erreichen eine Zeitauflösung von 20 Femtosekunden. Durch optische Anregung der niedrigsten elektronischen Übergänge werden in einem organischen Molekülkristall freie Exzitonen mit Wellenvektor k=0 gebildet. Dabei werden gleichzeitig zahlreiche intramolekulare und intermolekulare Schwingungsfreiheitsgrade angeregt. Die Anregung mit fs-Laserpulsen führt zum Aufbau kohärenter Schwingungswellenpakete. Es werden sowohl hochenergetische Oszillationen intramolekularer Vibrationen beobachtet, als auch erstmalig niedrigenergetische Oszillationen, die von Gittervibrationen (Phononen) stammen. Die kohärenten Vibrationen im elektronischen Grundzustand klingen bei Raumtemperatur im Bereich einiger Pikosekunden ab. Durch die optische Anregung mit fs-Laserpulsen wird nicht nur phononische Kohärenz, sondern auch elektronische Kohärenz der optischen Übergänge induziert. Die elektronische Kohärenz klingt mit der Dephasierungszeit T2 ab. Trotz der hohen Zeitauflösung war es letztendlich nicht möglich, die Dephasierung des niedrigsten exzitonischen Übergangs zeitlich aufzulösen - sie liegt jedoch im Bereich 17fs &lt; T2 &lt; 52fs. Die energetische Relaxation der freien Exzitonen zu den relaxierten, emittierenden Exzitonenzuständen erfolgt mit einer Zeitkonstante von ca. 50fs. Von diesen relaxierten Zuständen erfolgt die energetische Abregung in den elektronischen Grundzustand im ns-Bereich. Im zweiten Teil der Arbeit werden Untersuchungen an selbst-assemblierten Monoschichten (SAM) photochromer Moleküle vorgestellt. Als Modellsystem dienen Azobenzen-funktionalisierte Thiole auf Gold (111). Es konnten hochgeordnete Monoschichten dieser photochromen Moleküle erzielt werden, allerdings sind die bisherigen Schichten aufgrund der dichten Packung nicht photoaktivierbar. Mit Hilfe von Raster-Mikroskopie und Infrarot-Spektroskopie werden diese ultradünnen Schichten strukturell untersucht. Es wird ein kommensurates Wachstum mit zwei Molekülen in der nahezu rechteckigen Einheitszelle beobachtet, wobei die laubbaumförmigen Moleküle nahezu senkrecht auf der Oberfläche stehen. Als weitere Methode wurde die Generation der zweiten Harmonischen (Second Harmonic Generation, SHG) angewendet. Diese Technik eröffnet prinzipiell die Möglichkeit, photostimuliertes Schalten der Schicht zeitaufgelöst zu untersuchen. / The first part of this thesis is devoted to ultrafast relaxation processes in quasi-one-dimensional organic molecular crystals. Crystalline samples of the perylene derivative MePTCDI are employed as a model system. Processes concerning the excitonic and phononic relaxation are investigated in time domain using various experimental techniques of optical ultrafast spectroscopy. The experimental setups attain a time-resolution of 20 femtoseconds. Free excitons at wavevector k=0 are formed in a molecular crystal by optical excitation of the lowest electronic transitions. Thereby, various intramolecular and intermolecular vibrational degrees of freedom are excited simultaneously. The excitation by fs-laser pulses results in the composition of coherent vibrational wave packets. Both, higher-energetic oscillations caused by intramolecular vibrations (internal phonons) and, for the first time in a quasi-one-dimensional organic system, lower-energetic modulations which are related to coherent lattice phonons (external phonons) are observed. The coherence of both types of phonons in the electronic ground state is damped at room temperature within a few ps. Besides phononic coherence, optical excitation by fs-laser pulses additionally induces electronic coherence of the optical transitions. The electronic coherence decays with the dephasing time T2. In spite of the high time-resolution, finally it was not possible to time resolve the dephasing of the lowest excitonic transition - however, we can estimated it to be in the range of 17fs &lt; T2 &lt; 52fs. The energetic relaxation of free excitons to the relaxed, emitting exciton states takes place with a time constant of approx. 50fs. The subsequent energetic relaxation to the electronic ground state occurs on a ns-time scale. In the second part, investigations of self-assembled monolayers (SAM) of photochromic molecules are presented. Azobenzene-functionalized thiols on gold (111) are employed as a model system. Highly ordered monolayers of these photochromic molecules could be realized. However, these layers are not photoactive because of dense packing. By use of scanning tunneling microscopy and infra-red spectroscopy the structural properties of these ultrathin layers are investigated. A commensurate growth, yielding a lattice with two molecules within the nearly rectangular unit cell is observed. The molecules, shaped like a broad-leafed tree, are found to stand nearly upright on the surface. Second harmonic generation (SHG) is applied as another experimental method. This technique allows to time resolve photo-stimulated conformational changes of the layers in principle. Exziton Molekülkristall Monoschicht Spektroskopie organisch photochrom quasi-eindimensional zeitaufgelöst exciton molecular crystal monolayer organic photochromic quasi-one-dimensional spectroscopy time-resolved ddc:29 rvk:UM 3150 Exziton Molekülkristall Monoschicht Organischer Kristall Photochromie Relaxation
245	Pump-Superkontinuum-Probe-Spektroskopie von Carotinoiden in organischen Lösungsmitteln / Pump-Supercontinuum-Probe Spectroscopy of Carotenoids in Organic Solvents Ehlers, Florian 12 October 2010 (has links) No description available. 540 Chemie Chemistry PSCP Carotinoide Spektroskopie zeitaufgelöst elektronische Dynamik PSCP carotenoids spectroscopy time resolved electronic dynamics 35.16 33.07 SD 000: Physikalische Chemie SIL 000: Laser-Chemie {Strahlungschemie} RRQ 000: Laser-Spektroskopie {Physik}
246	Ab-initio Studies of X-ray Scattering / Ab-initio Studien der Röntgenstreuung Debnarova, Andrea 28 August 2009 (has links) No description available. 530 Physik Mathematics and Computer Science Röntgenstreuung Zeitaufgelöste Röntgenstreuung Ab-initio-Berechnung Röntgen-Pulse Hoher Intensität Quantenchemie X-ray Scattering Time-resolved X-ray scattering Ab-initio Calculations High Intensity X-ray Pulses Quantum Chemistry 33.30 RTE 000: Physik der Moleküle
247	Design and Fabrication of Fractal Photoconductive Terahertz Emitters and Antenna Coupled Tunnel Diode Terahertz Detectors Maraghechi, Pouya Unknown Date No description available. Terahertz antenna Terahertz detectors photoconductive switch Electron Tunnel Diode metal-insulator-metal Atomic Layer Deposition Nanofabrication Antenna Coupled MIM detectors Terahertz Spectroscopy Terahertz Imaging THz Pump-probe Terahertz Radiation Time Resolved
248	Energetic Transitions of Magnetic Vortices Burgess, Jacob A.J. Unknown Date No description available. Magnetism Magnetic Vortex Magnetic Pinning Scanning Tunneling Microscopy Torsional Magnetometry Magneto-optical Kerr Effect Time Resolved STM Deformable Vortex Pinning Model Vortex Core Pinning Metallic Glass Spin Polarized STM Micromagnetics
249	A polarization sensitive interferometer for Faraday rotation detection LaForge, Joshua Michael 23 July 2007 (has links) Time-resolved Faraday rotation (TRFR) is a pulsed laser pump/probe optical measurement used to characterize electron spin dynamics in semiconductor materials. A Mach-Zehnder type interferometer with orthogonally polarized arms is presented as a device for TRFR measurement that is superior to optical bridge detection, the traditional measuring technique, since Faraday rotation can be passively optically amplified via interference. Operation of the interferometer is analyzed under ideal conditions. Corrections to the ideal case stemming from imperfectly aligned optics, finite polarization extinction ratios, and an imperfect recombination optic are analyzed using a matrix transformation approach. The design of the interferometer is presented and chronicled. A description of the single-beam active control system utilized to stabilize the interferometer by continuous corrections to the optical path length of one arm with a piezoelectric actuator is given. Optical amplification by increasing the power in either arm of the interferometer is demonstrated and TRFR measurements taken with the interferometer at ambient temperatures are compared with measurements taken with the optical bridge. We find the interferometer to offer a detection limit on the order of 50 mrad at room temperature, which is five times more sensitive than the optical bridge. Isolation and stabilization of the interferometer were also successful in reducing signal noise to a level comparable with the optical bridge. Our results demonstrate that the interferometer is a better detection device for Faraday rotation under ambient conditions. In the immediate future, improvements to the control system should be made and experiments should be performed with high-quality samples at cryogenic temperatures to confirm that the interferometer performs as favorably under those conditions. interferometer spintronics Mach-Zehnder time-resolved Faraday-rotation Faraday rotation Faraday effect semiconductor gallium arsenide pulsed laser ultrafast spectrometry
250	Détection de traces d’éléments lanthanides par fluorescence en temps résolu : application industrielle au marquage anti contrefaçon et à l'analyse chimique / Detection of lanthanide elements by time-resolved fluorescence analysis : industrial application to anti-counterfeiting marking and chemical analysis Marais, Arthur 06 February 2018 (has links) La fluorescence en temps résolu est une méthode d'analyse spectrophotométrique avancée permettant la sélection des photons émis par luminescence sur un critère temporel. Il est ainsi possible, et cela même dans des milieux complexes et pollués issu de l'industrie, de faire émerger sélectivement le signal d'espèces luminescentes présentant des durées de vie de luminescence relativement grandes.Ce type d'analyse spectrale est particulièrement adapté à la détection de trace d'éléments lanthanides. Chacun des éléments de la série présente en effet des propriétés luminescentes uniques bien que largement fonction de la nature des ligands qui les entourent. Les travaux de thèse présentés dans ce manuscrit utilisent avantageusement la constatation précédente. Deux technologies ont étés mise sur pied et/ou optimisées pour permettre un transfert vers des domaines industriels aux cahiers des charges bien définis.Ainsi dans le domaine de la lutte anti-contrefaçon l'ajout de marqueurs luminescents à temps résolu à base de lanthanide rend possible la surveillance de l'origine et du devenir de divers produits industriels.Dans le domaine pétrolier l'analyse des effluents à l'aide de sondes luminescentes à base de lanthanide permet de quantifier le taux résiduel de plusieurs classes d'additifs chimiques et permet d'optimiser la sécurité, la rentabilité et l'impact écologique du processus d'extraction.Dernièrement un prototype de spectrofluorimètre résolu en temps adapté à un usage industriel a été mis au point pour permettre un transfert technologique du laboratoire vers le milieu industriel / Time-resolved fluorescence is an advanced spectrophotometric analysis method which allows the selection of emitted luminescent photons on a time-based parameters. It is possible to extract the signal of long-lived luminescent species even in complex and polluted matrix from the industry. This type of analysis is especially fitted for the detection of lanthanide ions. During this thesis two technologies based on time-resolved analysis were designed to answer specific industrial problematics. The first one yields the residual concentration of chemical additives used during oil and gas extraction. The second one aims at protecting crude oils and refined fuels from counterfeiting. They both rely on the use of lanthanide complex and the measurement of their luminescent properties. A prototype of time-resolved spectrofluorimeter was also built to transfer the technologies from the laboratory to the industrial world Complexes de lanthanides Fluorescence en temps résolu Anticontrefaçon Marqueurs photoluminescents Extraction de pétrole et de gaz Quantification des additifs chimiques Anti dépôts minéraux Anti corrosion Lanthanide complexs Time resolved fluorescence Anticounterfeiting Photoluminescent markers Oil and gas extraction Chemical additives quantification Scale inhibitors Corrosion inhibitors 540

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