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1	Development of the Pressure-Sensitive-Paint Technique for Advanced Turbomachinery Applications Navarra, Kelly R. 16 July 1997 (has links) A new pressure-measurement technique which employs the tools of molecular spectroscopy has recently received considerable attention in the fluid mechanics community. Measurements are made via oxygen-sensitive molecules attached to the surface of interest as a coating, or paint. The pressure-sensitive-paint (PSP) technique is now commonly used in stationary wind-tunnel tests; this thesis presents the extension of the technique to advanced turbomachinery applications. New pressure- and temperature-sensitive paints (TSPs) have been developed for application to a state-of-the-art transonic compressor where pressures up to 2 atm and surface temperatures up to 140° C are expected for the first-stage rotor. PSP and TSP data has been acquired from the suction surface of the first-stage rotor of a transonic compressor operating at its peak-efficiency condition. The shock structure is clearly visible in the pressure image, and visual comparison to the corresponding computational fluid dynamics (CFD) prediction shows qualitative agreement to the PSP data. / Master of Science Pressure-sensitive paint turbomachinery optical pressure measurement techniques luminescence quenching.
2	Complexos de isotiocianatos de lantanídeos com quelantes aromáticos: supressão da luminescência mediada pela transferência de energia tripleto-estado de transferência de carga Silva, Iran Ferreira da Silva 07 August 2015 (has links) Submitted by Maike Costa (maiksebas@gmail.com) on 2016-05-11T11:38:41Z No. of bitstreams: 1 arquivo total.pdf: 5689290 bytes, checksum: 55be9a3cf14a111bd7b7407cbca5df8e (MD5) / Made available in DSpace on 2016-05-11T11:38:41Z (GMT). No. of bitstreams: 1 arquivo total.pdf: 5689290 bytes, checksum: 55be9a3cf14a111bd7b7407cbca5df8e (MD5) Previous issue date: 2015-08-07 / The photoluminescence efficiency in compounds of lanthanide ions is a result of the complex balance between absorption of photons, energy transfer and quenching mechanisms, among which the multiphonon decay and suppression mediated by low energy ligand-to-metal charge transfer states (LMCT) which might be generated by ligands that have a low oxidation potential, for instance the NCS–. Less than a decade ago, this process was described mainly in terms of the energy transfer between 4f states and LMCT states, not being considered the participation of intraligands states. In the present study, we investigated the photoluminescent properties of new lanthanide isothiocyanates coordination complexes with N-acetyl-2-aminopyridine, N-benzoyl-2-aminopyridine and N-benzoyl-2- aminopyrimidine as ligands. We also synthesized the well-known complexes of formulas [Ln(NCS)3(phen)3] (H2O), and [Ln(NO3)3(Phen)2] with phen = 1,10-phenanthroline. The complexes were characterized via CHN elemental analysis, vibrational spectroscopy, complexometric titration and thermogravimetric analysis. Their spectroscopic properties were investigated via molecular diffuse reflectance, excitation and emission spectroscopy along with time decay of the emitting states. The results from the analysis of emission spectroscopy and photoluminescence excitation, as well as the lifetimes measurements of the emitting states of the investigated complexes provided what we believe to be the most expressive experimental demonstration of the luminescence quenching via triplet-LMCT energy transfer process in Eu(III) complex so far. / A eficiência na fotoluminescência em compostos de íons lantanídeos é o resultado de um balanço complexo entre absorção de fótons, transferência de energia e mecanismos supressores, dentre os quais se destacam o decaimento multifônon e a supressão mediada por estados de transferência de carga ligante-metal (TCLM) de baixa energia, que pode ser gerado por ligantes que apresentam baixo potencial de oxidação, a exemplo do NCS–. Há menos de uma década, este processo era descrito essencialmente em termos da transferência de energia entre estados 4f e os estados TCLM, não sendo considerada a participação dos estados intraligantes. Neste trabalho, investigamos as propriedades fotoluminescentes de novos compostos de coordenação de isotiocianatos de lantanídeos com os ligantes N-acetil- 2-aminopiridina, N-benzoil-2-aminopiridina e N-benzoil-2-aminopirimidina. Sintetizamos, também, os complexos já conhecidos, de fórmulas gerais [Ln(NCS)3(phen)3] (H2O) e [Ln(NO3)3(phen)2] com phen= 1,10-fenantrolina. Os complexos foram caracterizados por análise elementar de CHN, espectroscopia vibracional na região do infravermelho, análise termogravimétrica e titulação complexométrica e suas propriedades espectroscópicas foram investigadas por espectroscopias molecular de reflectância difusa e de excitação e emissão bem como os tempos de decaimento dos estados emissores. Os resultados obtidos a partir das análises de espectroscopia de emissão e excitação da fotoluminescência, assim como as medidas de tempos de vida dos estados emissores dos complexos investigados proporcionaram o que acreditamos ser a demonstração experimental mais expressiva, até então, do processo de supressão da luminescência mediada pelo processo de transferência de energia tripleto-TCLM em complexos do íon Eu(III). Supressão da luminescência Transferência de energia Estados de transferência de carga Energy transfer Charge transfer states Luminescence quenching CIENCIAS EXATAS E DA TERRA::QUIMICA
3	NaYF4:Yb,Er Upconversion Nanocrystals: Investigating Energy Loss Processes for the Systematic Enhancement of the Luminescence Efficiency Grauel, Bettina 23 May 2022 (has links) Aufkonvertierende (upconverting; UC) Nanomaterialien bilden eine neue Klasse nichtlinearer lumineszenter Reporter, die nah-infrarotes (NIR) Anregungslicht in Photonen von höherer Energie umwandeln. Das effizienteste bekannte UC-System bildet hierbei β-NaYF4: 20%Yb(III), 2%Er(III) mikrokristallines Bulkmaterial, für welches UC-Quantenausbeuten (ΦUC) von 10 % berichtet werden, während ΦUC von Nanokristallen (nanocrystals; NC) um mehrere Größenordnungen niedriger sein können. Um die Effizienz von UC-Nanomaterialien zu erhöhen, werden NC üblicherweise mit inerten Schalen versehen. In dieser Arbeit werden mehrere verschiedene Bulkmaterialien spektroskopisch untersucht, um ein Vergleichsmaterial auszuwählen, das als Maßstab für alle folgenden, vergleichbaren Messungen an NC dient. Die Oberfläche von ultrakleinen (3.7±0.5) nm NC wird mit Schalen von bis zu 10 nm Dicke versehen, um die optimale Schalendicke für vollständige Oberflächenpassivierung zu identifizieren, allerdings weisen die Ergebnisse auf eine mögliche Kern-Schale-Durchmischung hin. In einer zweiten Studie werden die unterschiedlichen Dotanden, Er(III) und Yb(III), auf ihre optischen Eigenschaften sowie die Einflüsse von Energietransfer (ET) und von ihrer Umgebung spektroskopisch untersucht. Dabei kann klar zwischen Oberflächeneffekten und oberflächenunabhängigen Volumeneffekten unterschieden werden. Die Ergebnisse werden durch ein einfaches Monte-Carlo-Modell gestützt, durch das die größen- und leistungsdichte-(P-)abhängigen Populierungsdynamiken der strahlenden Banden von Er(III) vorhergesagt werden können. Zuletzt werden durch eine verbesserte Synthesemethode UCNC mit stark verbesserten Lumineszenzeigenschaften hergestellt, mit denen bei vergleichsweise niedrigen P die gleichen ΦUC wie beim Bulkmaterial erreicht werden. Dies liefert einen Einblick in vielfältige Anwendungsmöglichkeiten für UCNC. / Upconversion (UC) nanomaterials are an emerging new class of non-linear luminescent reporters which convert near-infrared (NIR) excitation light into higher-energy photons. The most efficient known UC material is the β-NaYF4: 20%Yb(III), 2%Er(III) bulk (microcrystalline) phosphor with reported UC quantum yields (ΦUC) of 10 %, while ΦUC of nanocrystals (NC) can be several orders of magnitude lower. Strategies to improve the efficiency of UC nanomaterials include surface passivation with inert shells. In this work, several different bulk materials are compared to select one benchmark material for comparisons with NC analyzed with the same measurement techniques. The surface of ultrasmall (3.7 ± 0.5) nm NC is coated with inert shells of up to 10 nm thickness to identify an optimal shell thickness for complete surface passivation, but the results suggest core-shell intermixing. To distinguish between the different dopant ions, Er(III) and Yb(III), and the effect of energy transfer (ET) in a second study, single- and co-doped UCNC are investigated spectroscopically and the influence of their environment is determined thoroughly. Herein, a clear distinction between surface-related and surface-independent, volume-related effects is achieved and the results are emphasized by the use of a simple random walk model which accurately predicts size- and power density (P)-dependent population dynamics of the emissive bands of Er(III). Finally, utilizing an improved synthesis technique, UCNC with enhanced luminescence properties are produced, reaching the same ΦUC as the benchmarked bulk material at reasonably low P, providing an insight into numerous possible applications of UCNC. Photon-Aufkonversion absolute Quantenausbeutebestimmung Zerfallsmessung Oberflächenpassivierung Oberflächen-Lumineszenzlöschung Volumeneffekt Energietransfer und -migration Lanthanoid-dotierte Nanokristalle photon upconversion absolute quantum yield determination decay measurement surface passivation surface luminescence quenching volume effect energy transfer and migration lanthanide-doped nanocrystals 530 Physik ddc:530
4	Characterisation of Photo-Physical Properties of Upconversion Nanocrystals at Ensemble and Single Particle Level Frenzel, Florian 19 July 2022 (has links) Aufkonvertierungs-Nanokristalle (UCNPs), wie NaYF4 Kristalle, welche mit Yb3+ and Er3+ Ionen dotiert sind, emittieren höher energetisches Licht im ultravioletten/sichtbaren und nahinfraroten Bereich, nachdem sie mit weniger energiereichem nahinfraroten Licht angeregt wurden. Damit besitzen sie einzigartige optische Eigenschaften, wie verschiedenfarbige Emissionsbanden, verringerte Hintergrundfluoreszenz, größere Eindringtiefen in organisches Probenmaterial und eine hohe Lichtstabilität. Diese Eigenschaften sind besonders in der optischen Bioanalyse, in medizinischen und technischen Anwendungen von Vorteil. In dieser Arbeit werden die photophysikalischen und spektralen Eigenschaften von UCNPs im Ensemble und an Einzelpartikeln untersucht. Ein dafür entwickeltes konfokales Mikroskop ermöglicht Einzelpartikelmessungen bis in den Sättigungsbereich der UCNPs bei hohen Laser Anregungsleistungsdichten (P). Die erste Studie dieser Arbeit umfasst Ensemble- und Einzelpartikelmessungen an Kern und Kern-Schale 𝛽-NaYF4 Kristallen, welche mit 20% Yb3+ und 1% bis 3% Er3+ Ionen dotiert sind, wobei die optischen Eigenschaften P-abhängig über sechs Größenordnungen untersucht wurden. Die zweite Studie diskutiert die Einflüsse bei starker Änderung der Yb3+/Er3+ Ionen Dotierung anhand von drei verschiedenen Probensystemen. Diese unterscheiden sich sowohl in der Partikelgröße als auch in der Synthesevorschrift. Bei der dritten Studie wurde die direkte Anregung von Yb3+ mit der von Nd3+ Ionen an Nd/Yb/Er dotierten NaYF4 Partikeln bezüglich des aufkonvertierten Lumineszenz Verhaltens in Wasser verglichen. In weiteren Messungen wurde sowohl der Lumineszenz Resonanz Energie Transfer (LRET) ausgehend von einem UCNP zu dem Farbstoff Sulforhodamine B, als auch plasmonische Wechselwirkungen von Au-Schale UCNPs bei Einzelpartikelmessungen untersucht. / Upconversion nanoparticles (UCNPs), such as, NaYF4 crystals co-doped with Yb3+ and Er3+ ions, emit higher energetic light in the UV/vis and NIR range under lower energetic NIR excitation. This generates unique optical properties, for example, multi-colour band emissions, reduced background fluorescence, deeper tissue penetration depths and high photostability rendering UCNPs attractive options for bioimaging, medicinal and engineering applications. In this thesis the influence of multi-factor parameters on the photo-physical and spectroscopic properties of UCNPs are investigated under ensemble and single particle (SP) condition. For this purpose, a confocal laser scanning microscope was constructed to enable the characterisation of individual UCNPs up to their saturation conditions at high laser power densities (P). At first, ensemble and SP studies of core- and core-shell 𝛽-NaYF4 crystals co-doped with 20% Yb3+ and 1% to 3% Er3+ are performed over a P-range of six orders of magnitude. The second part of this thesis discusses influences in a wide variation in Yb3+/Er3+ ion doping concentration. Thereby, three different sample sets of varying size have been studied, using different synthesis approaches. A comparison of the Nd- and Yb-excitation of Nd/Yb/Er triple-doped NaYF4 UCNPs regarding their upconversion luminescence performance in water is provided in the third section of the thesis. In further studies, the process of luminescence resonance energy transfer (LRET) from an UCNP to the sulforhodamine B dye and the plasmonic interaction of an Au-shelled UCNP have been examined at the SP level. Photon-Aufkonvertierung Lathanoid-dotierte Nanokristalle Ensemble und Einzelpartikel Messungen konfokale Mikroskopie hohe Anregungsleistungsdichten Zerfallsmessung absolute Quantenausbeute lumineszente Auslöschung Yb- und Nd-Anregungsmessungen FRET/LRET Prozess Plasmonische Wechselwirkungen Photon upconversion lanthanide-doped nanocrystals ensemble and single particle studies confocal microscopy high excitation power density decay kinetics absolute quantum yield luminescence quenching Yb- and Nd-excitation FRET/LRET process plasmonic interactions 621 Angewandte Physik 530 Physik ddc:621 ddc:530

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