Global ETD Search

1	Phosphorescence anisotropy studies of the protein moiety in human serum lipoproteins Kim, Heiryun January 1977 (has links) No description available. Anisotropy. Phosphorescence spectroscopy.
2	Phosphorescence anisotropy studies of the protein moiety in human serum lipoproteins Kim, Heiryun January 1977 (has links) No description available. Phosphorescence spectroscopy. Anisotropy.
3	Delayed emission and the heavy-atom effect as probes of biomolecular structure and dynamics Lee, William Edward. January 1985 (has links) No description available. Phosphorescence spectroscopy Proflavine -- Spectra. Fluorescence spectroscopy Emission spectroscopy
4	Delayed emission and the heavy-atom effect as probes of biomolecular structure and dynamics Lee, William Edward. January 1985 (has links) No description available. Emission spectroscopy Phosphorescence spectroscopy Fluorescence spectroscopy Proflavine -- Spectra.
5	Hydroxypropylmethylcellulose: A New Matrix for Solid-Surface Room-Temperature Phosphorimetry Hamner, Vincent N. 05 November 1999 (has links) This thesis reports an investigation of hydroxypropylmethylcellulose (HPMC) as a new solid-surface room-temperature phosphorescence (SSRTP) sample matrix. The high background phosphorescence originating from filter paper substrates can interfere with the detection and quantitation of trace-level analytes. High-purity grades of HPMC were investigated as SSRTP substrates in an attempt to overcome this limitation. When compared directly to filter paper, HPMC allows the spectroscopist to achieve greater sensitivity, lower limits of detection (LOD), and lower limits of quantitation (LOQ) for certain phosphor/heavy-atom combinations since SSRTP signal intensities are stronger. For example, the determination of the analytical figures of merit for a naphthalene/sodium iodide/HPMC system resulted in a calibration sensitivity of 2.79, LOD of 4 ppm (3 ng), and LOQ of 14 ppm (11 ng). Corresponding investigations of a naphthalene/sodium iodide/filter paper system produced a calibration sensitivity of 0.326, LOD of 33 ppm (26 ng), and LOQ of 109 ppm (86 ng). Extended purging with dry-nitrogen gas yields improved sensitivities, lower LOD's, and lower LOQ's in HPMC matrices when LOD and LOQ are calculated according to the IUPAC guidelines.To test the universality of HPMC, qualitative SSRTP spectra were obtained for a wide variety of probe phosphors offering different molecular sizes, shapes, and chemical functionalities. Suitable spectra were obtained for the following model polycyclic aromatic hydrocarbons (PAHs): naphthalene, p-aminobenzoic acid, acenaphthene, phenanthrene, 2-naphthoic acid, 2-naphthol, salicylic acid, and triphenylene.Filter paper and HPMC substrates are inherently anisotropic, non-heterogeneous media. Since this deficiency cannot be addressed experimentally, a robust statistical method is examined for the detection of questionable SSRTP data points and the deletion of outlying observations. If discordant observations are discarded, relative standard deviations are typically reduced to less than 10% for most SSRTP data sets. Robust techniques for outlier identification are superior to traditional methods since they operate at a high level of efficiency and are immune to masking effects.The process of selecting a suitable sample support material often involves considerable trial-and-error on the part of the analyst. A mathematical model based on Hansen's cohesion parameter theory is developed to predict favorable phosphor-substrate attraction and interactions. The results of investigations using naphthalene as a probe phosphor and sodium iodide as an external heavy-atom enhancer support the cohesion parameter model.This document includes a thorough description of the fundamental principles of phosphorimetry and provides a detailed analysis of the theoretical and practical concerns associated with performing SSRTP. In order to better understand the properties of both filter paper and HPMC, a chapter is devoted to the discussion of the cellulose biopolymer. Experimental results and interpretations are presented and suggestions for future investigations are provided. Together, these results provide a framework that will support additional advancements in the field of solid-surface room-temperature phosphorescence spectroscopy. / Ph. D. Outliers Cellulose Cohesion (or Solubility) Parameters Robust Statistics Phosphorescence Spectroscopy Hydroxypropylmethylcellulose (HPMC)
6	Ultrafast photophysics of iridium complexes Hedley, Gordon J. January 2010 (has links) This thesis presents ultrafast photophysical measurements on a number of phosphorescent iridium complexes and establishes relationships between the relaxation rates and the vibrational properties of the material. When ultrafast luminescence is measured on the peak of the phosphorescence spectrum and on its red-side, 230 fs and 3 ps decay time constants were observed in all materials studied, and this was attributed to population redistribution amongst the three electronic substates of the lowest triplet metal-ligand charge transfer (MLCT) state. The observation of luminescence at higher values of energy embodied ultrafast dissipation of excess energy by intramolecular vibrational redistribution (IVR) and it was found that the dissipation channels and rate of IVR could be modified by chemical modification of the emitting molecule. This was tested in two ways. Firstly by adding electronically inactive dendrons to the core, an increase in the preference for dissipation of excess energy by IVR rather than by picosecond cooling to the solvent molecules was found, but this did not change the rate of IVR. The second method of testing was by fusing a phenyl moiety directly onto the ligand, this both increased the rate of IVR and also the preference for dissipation by it rather than by picosecond cooling. Fluorescence was recorded in an iridium complex for the first time and a decay time constant of 65 fs was found, thus allowing a direct observation of intersystem crossing (ISC) to be made. In a deep red emitting iridium complex internal conversion (IC) and ISC were observed and the factors controlling their time constants deduced. IC was found to occur by dissipation of excess energy by IVR. The rate of IC was found to be dependent on the amount of vibrational energy stored in the molecule, with IC fast (< 45 fs) when < 0.6 eV of energy is stored and slower (~ 70 fs) when the value is > 0.6 eV. The rate of ISC agreed with these findings, indicating that the very process of ISC may be thought of as closely analogous to that of IC given the strongly spin-mixed nature of the singlet and triplet MLCT states. 530.412
7	Oxydation des protéines par les espèces réactives de l'oxygène : l'importance de l'environnement protéique / Proteins oxydation by reactive oxygen species : the importance of the proteic environment Sjöberg, Béatrice 20 December 2013 (has links) Les espèces réactives de l'oxygène sont générées dans l'environnement biologique dans le cadre du métabolisme, mais elles peuvent aussi être produites en excès dans le cas de stress oxydatif provoqué par exemple par une exposition aux rayons UV. Dans le travail présenté ici, nous sommes intéressés par l'oxydation des protéines par deux de ces espèces réactives de l'oxygène : le peroxyde d'hydrogène, oxydant plutôt faible avec un temps de vie long, et l'oxygène singulet, oxydant fort avec un temps de vie court. L'action de ce dernier sur les protéines est étudiée en utilisant la spectroscopie de phosphorescence résolue en temps et l'oxydation des protéines par le peroxyde d'hydrogène est suivie par spectroscopie Raman. Dans ce cas, un travail préliminaire a été nécessaire afin d'attribuer de manière précise les bandes Raman des chaînes latérales des résidus d'acides aminés. Pour les deux types d'oxydations, les constantes de vitesse des réactions ont été déterminées pour trois protéines modèles. La stratégie suivie est d'utiliser de petits fragments de protéines tels que des acides aminés libres et des tripeptides pour comprendre ce qui se passe à l'échelle de la protéine. Cela nous aide à souligner l'importance de l'environnement protéique. Dans le cas de l'étude par spectroscopie Raman, l'influence du nombre de liaisons peptidiques sur les spectres obtenus depuis l'acide aminé libre, au tripeptide, jusqu'à la protéine est aussi mis en évidence. / Reactive species of oxygen are generated in biological environment as part of metabolism but they can also be produced in excess in case of oxidative stress provoked by UV exposure for example. In the present work we are interested in the oxidation of proteins by two of those reactive species of oxygen : hydrogen peroxide, rather weak oxidant with a long life time, and singlet oxygen, a strong oxidant with a short life time. The action of the latter one on the proteins is studied by using time-resolved phosphorescence spectroscopy and oxidation of the proteins by hydrogen peroxide is monitored by using Raman spectroscopy. In this case a preliminary work was necessary to attribute accurately the Raman bands of amino-acid residues side chains. For both oxidations, reaction rate constants of the reactions were determined for three model proteins. The strategy followed is to use small fragments of proteins such as free amino-acids and tripeptides to understand what is happening at the protein scale. This helps us underlining the importance of the proteic environment. In the case of Raman spectroscopy study, it also shows the influence of the number of peptidic bonds on the spectra obtained from free amino-acid to tripeptide and then to protein.Keywords : Raman Spectroscopy, protein, oxidation, hydrogen peroxide, singlet oxygen, time-resolved phosphorescence spectroscopy, reaction rate constant. Spectroscopie Raman Oxydation Peroxyde d'hydrogène Oxygène singulet Constante de vitesse de réaction Proteine Raman spectroscopy Protein Oxydation Hydrogen peroxyde Singlet oxygen Reaction rate constant 540

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