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Způsoby zapalování jiskřišť / Methods of ignition spark gapsPekárek, Dominik January 2015 (has links)
This thesis deals with methods of spark gap ignition. The thesis describes spark gap ignition by external electrode, by Rogowski electrode and by lasers. Advantages and disadvantages of these methods are also discussed. In the final part of the thesis there is described experiment with high voltage spark gap.
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Laser-Ionization Time-of-Flight Mass Spectrometry of High Molecular Mass Inorganic ComplexesWatson, R. Craig Jr. 04 November 1997 (has links)
Laser-Ionization Time-of-Flight Mass Spectrometry (LI-TOF-MS) is a sophisticated tool for the molecular-weight determination and structural characterization of a variety of molecules. Advances in instrumentation and ionization methods have recently expanded its role in the analysis of high-mass analytes. Large multimetallic complexes, which are efficient solar-energy converters, rely heavily on their chemical structure for optimum operation. Molecular mass determinations of these multimetallic complexes have been problematic due to their lability and high molecular weights.
This thesis describes the characterization of a LI-TOF-MS instrument and confirmation of theoretical time-of-flight mass-separation principles. Several test cases demonstrate the instrument's proper operation and calibration for a wide mass range of analytes. Mass spectral results of three organometallic compounds: i. [Ir(dpp)₂Cl₂](PF₆), ii. {[(bpy)₂Ru(dpp)]₂IrCl₂}(PF₆)₅, and iii. {[(bpy)₂Ru(dpp)]₂RuCl₂}(PF₆)₅ under a variety of laser ionization and sample preparation conditions are compared. A complete structural characterization of the monometallic complex, [Ir(dpp)₂Cl₂](PF₆), is presented. The two trimetallic analytes fragmented easily, but significant components of the molecules are successfully identified. After optimizing the ionization and analytical procedure, LI-TOF-MS proved useful in the analysis of high molecular mass metal complexes. / Master of Science
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Trapped Ion Mobility Spectrometry coupled to Fourier Transform Ion Cyclotron Resonance Mass Spectrometry for the analysis of Complex Mixtures.Benigni, Paolo 18 September 2017 (has links)
Analytical Characterization of complex mixtures, such as crude oil, environmental samples, and biological mixtures, is challenging because of the large diversity of molecular components. Mass spectrometry based techniques are among the most powerful tools for the separation of molecules based on their molecular composition, and the coupling of ion mobility spectrometry has enabled the separation and structural elucidation using the tridimensional structure of the molecule. The present work expands the ability of analytical chemists by furthering the development of IMS-MS instrumentation by coupling Trapped Ion Mobility Spectrometry to Fourier Transform Ion Cyclotron Resonance Mass Spectrometry (TIMS-FT-ICR MS). The TIMS-FT-ICR MS platform combines the high-resolution separation of TIMS, which has mobility resolving powers up to 400, and ultra-high mass resolution of FT-ICR MS, with mass resolving power over 1,000,000. This instrumentation allows the assignment of exact chemical composition for compounds in a complex mixture, as well as measurement of the collision cross-section of the molecule. Herein, the principles of the TIMS separation and its coupling to FT-ICR MS are described, as well as how the platform can be applied to targeted analysis of molecules, and untargeted characterization of complex mixtures.
Molecular standards were analyzed by TIMS-MS in order to develop a computational workflow that can be utilized to elucidate molecular structure, using the measured collision cross-section of the ion. This workflow enabled identification of structural, cis/trans isomers, and chelated molecules and provides the basis for unsupervised structural elucidation of a complex mixture, and in particular for the elucidation of hydrocarbons from fossil fuels. In summary, this work presents the coupling of TIMS-FT-ICR MS and provides examples of applications as a proof of concept of the potential of this platform for solving complex analytical challenges.
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Quantification relative et absolue du cholestérol à partir de sections tissulaires minces via l’imagerie par spectrométrie de masse par désorption ionisation laser assistée par l’argentSaadati Nezhad, Zari 03 1900 (has links)
Le cholestérol est l'une des molécules biologiques indispensable au bon fonctionnement de la plupart des organismes vivants, y compris chez l’homme. Cette molécule se trouve en abondance dans des tissus cérébraux et joue trois rôles principaux dans l'organisme. C’est un constituant (composant) essentiel de la membrane cellulaire qui sert à maintenir l’intégrité et la fluidité des cellules. Le cholestérol est aussi un élément déclencheur pour la production d’hormones stéroïdiennes comme les hormones sexuelles et la vitamine D. Finalement, il contribue à la production des acides biliaires par le foie.
Dans cette étude, une méthode analytique de quantification absolu du cholestérol dans sections tissulaires de cerveau de souris par IMS a été développée. Pour ce faire, dans un premier temps des courbes d’étalonnage faites à partir de concentrations croissantes de cholesterol-d7 ont été réalisé en dopant directement des sections minces d’homogénat de cerveau. Par la suite, un étalon interne de stigmastérol (un stérol naturel d’origine exclusivement végétale) a été utilisé pour normaliser les signaux en provenance du cholestérol et du cholestérol-d7.
Finalement, les analyses ont été effectué en utilisant une méthode IMS préalablement développée au laboratoire pour la détection spécifique et l’imagerie du cholestérol par désorption ionisation laser assistée par l’argent. L’étalon interne a été utilisé ici pour réduire les erreurs instrumentales, et les résultats avant et après normalisation montrent le rôle fonctionnel de cette méthode dans l’amélioration de la linéarité de la courbe d’étalonnage et, en conséquence, la mesure précise du cholestérol dans des échantillons analysés. / Cholesterol is one of the biological molecules essential for the proper functioning of most living organisms, including humans, and accurate quantification of cholesterol has many potential implications. This molecule is found abundantly in the brain and plays three main roles in the body. It is an essential component of the cell membrane which serves to maintain the integrity and fluidity of cells. Cholesterol is also a chemical trigger for the production of various steroid hormones such as sex hormones and vitamin D. Ultimately, it helps the liver to produce bile acids. A greater understanding of cholesterol and of its role in the body may directly impact our understanding of these processes.
In this study, an analytical method for the absolute quantification of cholesterol in the mouse brain slices by IMS was developed. To achieve this calibration curves made from increasing concentrations of cholesterol-d7 were first performed by doping them on thin sections of brain homogenate. Subsequently, stigmasterol (a natural sterol of exclusively plant origin) was used as an internal standard to normalize the signals from cholesterol and cholesterol-d7 was evenly deposited over all analyzed sections.
Finally, the analyzes were performed using an IMS method previously developed in the laboratory for the specific detection and imaging of cholesterol by silver-assisted laser ionization desorption. The internal standard was used here to reduce instrument errors, and the before and after normalization results show the functional role of this method in improving the linearity of the calibration curve and, therefore, the accurate measurement of cholesterol in the analyzed samples.
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Insights into Carbonaceous Chondrites: A Mass Spectrometry Study on Bulk, Soluble, and Insoluble Organic MatterMehmed, Sebastian January 2024 (has links)
This study presents an analysis of the organic matter in meteorites, particularly carbonaceous chondrites (CCs), using advanced experimental techniques such as Two-step laser desorption laser ionization mass spectrometry (L2MS-oTOF) and Atmospheric Pressure Photoionization-Orbitrap (APPI-Orbitrap). The analysis focuses on the molecular complexity of both soluble (SOM) and insoluble (IOM) organic matter as well as the bulk rock and identifying and classifying different molecular families to understand the chemical composition of the meteorites. A new software tool, SpectraC, was developed to aid in analysing and comparing mass spectra from multiple meteorite samples simultaneously. The findings of the study reveal the complex chemical composition of meteorites, with condensed aromatics dominating most samples, and highlight the importance of using multiple techniques for a more complete understanding of the sample’s contents. This research lays the foundation for future work in astrochemistry, including the development of a state-of-the-art analytical tool and further exploration of the organic matter in meteorites. / Cette étude présente une analyse de la matière organique dans les météorites, en particulier les chondrites carbonées (CC), en utilisant des techniques expérimentales avancées telles que la spectrométrie de masse à ionisation laser par désorption en deux étapes (L2MS-oTOF) et l’ionisation photochimique à pression atmosphérique-Orbitrap (APPI-Orbitrap). L’analyse se concentre sur la complexité moléculaire de la matière organique soluble (SOM) et insoluble (IOM) ainsi que sur la roche globale, et identifie et classe différentes familles moléculaires pour comprendre la composition chimique des météorites. Un nouvel outil logiciel, SpectraC, a été développé pour aider à analyser et comparer les spectres de masse de plusieurs échantillons de météorites simultanément. Les résultats de l’étude révèlent la composition chimique complexe des météorites, avec une domination des aromatiques condensés dans la plupart des échantillons, et mettent en évidence l’importance d’utiliser plusieurs techniques pour une compréhension plus complète du contenu des échantillons. Cette recherche pose les bases des travaux futurs en astrochimie, y compris le développement d’outils analytiques de pointe et l’exploration plus poussée de la matière organique dans les météorites.
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