Zur Wechselwirkung von Uran mit den Bioliganden Citronensäure und Glucose

Steudtner, Robin

30 September 2010

Um das Verhalten von Actiniden im Menschen (Stoffwechsel), in geologischen und in biologischen Systemen vorherzusagen, ist es erforderlich deren Speziation genau zu kennen. Zur Bestimmung dieser wird das chemische Verhalten des Urans hinsichtlich Komplexbildungsreaktionen und Redoxreaktionen in Modellsystemen untersucht. Anhand der gewonnenen thermodynamischen Konstanten und dem Redoxverhalten können Risikoabschätzungen für das jeweilige untersuchte System getroffen werden. Das umweltrelevante Uran(IV)-Uran(VI)-Redoxsystem besitzt mit der metastabilen fünfwertigen Oxidationsstufe einen zumeist kurzlebigen Zwischenzustand. Innerhalb dieser Arbeit gelang es erstmalig die Uran(V)-Fluoreszenz mittels laserspektroskopischer Methoden nach zu weisen. Beispielsweise konnte das Bandenmaximum von aquatischem Uranyl(V) im perchlorhaltigem Medium (λex = 255 nm) mit 440 nm, bei einer Fluoreszenzlebensdauer von 1,10 ± 0,02 µs bestimmt werden. Die fluoreszenzspektroskopische Untersuchung eines aquatischen [U(V)O2(CO3)3]5--Komplexes (λex= 255 nm und 408 nm) zeigte bei Raumtemperatur keine Fluoreszenz. Durch Anwendung der Tieftemperaturtechnik wurden bekannte Quencheffekte des Carbonats unterdrückt, so dass bei beiden Anregungswellenlängen ein für Uran(V) typisches Fluoreszenzspektrum im Bereich von 375 nm bis 450 nm, mit Bandenmaxima bei 401,5 nm (λex = 255 nm) und 413,0 nm (λex = 408 nm) detektiert werden konnte. Darüber hinaus konnte bei 153 K (λex = 255 nm) eine Fluoreszenzlebensdauer von 120 ± 0,1 µs bestimmt werden. Untersetzt wurden diese fluoreszenzspektroskopischen Nachweise durch mikroskopische Studien verschiedener Uran(IV)-Festphasen (Uraninit…UO2, Uran(IV) Tetrachlorid…UCl4) und einer sulfathaltigen Uran(IV)-Lösung (UIVSO4). Diese wurden durch kontinuierliche Sauerstoffzufuhr zu Uran(VI) oxidiert. Die ablaufende Oxidation wurde mit dem konfokalen Laser Scanning Mikroskop (CLSM) verfolgt, wobei die Proben mit einer Wellenlänge von 408 nm zur Fluoreszenz angeregt wurden. Die auftretenden Bandenmaxima bei 445,5 nm (UO2), bei 445,5 nm (UCl4) und bei 440,0 nm (UIVSO4) konnten eindeutig der Uran(V)-Fluoreszenz zugeordnet werden. Zur Bestimmung thermodynamischer Konstanten mit Hilfe der Tieftemperaturfluoreszenz wurde zunächst der Einfluss der Temperatur auf das Fluoreszenzverhalten des freien Uranyl(VI)-Ions näher betrachtet. Es zeigte sich, dass mit Erwärmung der Probe (T>298 K) die Fluoreszenzlebensdauer von 1,88 µs (298 K) deutlich absinkt. Die Fluoreszenzintensität verringerte sich dabei um 2,3 % pro 1 K zwischen 273 K und 313 K. Im Gegensatz dazu, steigt die Fluoreszenzlebensdauer um das 150-fache auf 257,9 µs bei einer Verminderung der Temperatur (T <298 K) auf 153 K. Das weitere Absenken der Temperatur (T <153 K) zeigte keinen Einfluss auf die Fluoreszenzlebensdauer. Die Lage der Hauptemissionsbanden des freien Uranyl(VI)-Ions (488,0 nm, 509,4 nm, 532,4 nm, 558,0 nm, 586,0 nm) zeigte bei diesen Untersuchungen keine temperaturabhängige Verschiebung. Die Validierung der Tieftemperaturtechnik zur Bestimmung thermodynamischer Konstanten mittels zeitaufgelöster laserinduzierten Fluoreszenzspektroskopie erfolgte anhand des Uran(VI)-Citrat-Systems. Im Gegensatz zu bisherigen fluoreszenzspektroskopischen Betrachtungen bei Raumtemperatur wurde das Fluoreszenzsignal bei tiefen Temperaturen mit einsetzender Komplexierung nicht gequencht, woraus die Ausprägung einer gut interpretierbaren Fluoreszenz resultierte. Die Analyse der spektralen Daten mit SPECFIT ergaben mit log β101 = 7,24 ± 0,16 für den [UO2(Cit)]--Komplex und log β202 = 18,90 ± 0,26 für den [(UO2)2(Cit)2]2 -Komplex exakt die in der Literatur angegebenen Stabilitätskonstanten. Zudem konnten Einzelkomponentenspektren mit Bandenmaxima bei 475,3 nm, 591,8 nm, 513,5 nm, 537,0 nm und 561,9 nm für den 1:0:1-Komplex und 483,6 nm, 502,7 nm, 524,5 nm, 548,1 nm und 574,0 nm für den 2:0:2-Komplex und Fluoreszenzlebensdauern von 79 ± 15 µs (1:0:1) und 10 ± 3 µs (2:0:2) bestimmt werden. Zur Modellkomplexierung des Uran-Citrat-Systems wurde in dieser Arbeit auch das Komplexbildungsverhalten von U(IV) in Gegenwart von Citronensäure untersucht. Hierbei wurden über den gesamten pH-Wertbereich gelöste Uran-Citrat-Spezies spektroskopisch nachgewiesen und die Stabilitätskonstanten sowie die Einzelkomponentenspektren für die neu gebildeten Uran(IV) und (VI)-Spezies bestimmt. Für die neu gebildeten Citrat-Komplexe des sechswertigen Urans wurden Komplexbildungskonstanten von log β203 = 22,67 ± 0,34 ([(UO2)2(Cit)3]5-) und log β103 = 12,35 ± 0,22 ([UO2(Cit)3]7-) und für die Komplexe des vierwertigen Urans von log β1-21 = -9,74 ± 0,23 ([U(OH)2Cit]-) und log β1 31 = -20,36 ± 0,22 ([U(OH)3Cit]2-) bestimmt. Untersuchungen zum Redoxverhalten von Uran in Gegenwart von Citronensäure zeigten unter aeroben und anaeroben Versuchsbedingungen eine photochemische Reduktion vom U(VI) zu U(IV), welche spektroskopisch nachgewiesen werden konnte. Dabei zeigt speziell die Reaktion unter oxidierenden Bedingungen, welchen großen Einfluss vor allem organischen Liganden auf das chemische Verhalten des Urans haben können. Sowohl die Reduktion unter O2- als auch die unter N2-Atmosphäre, weisen ein Maximum bei einem pH Wert von 3,5 bis 4 auf. Unter anaeroben Bedingungen reduziert die Citronensäure mit ca. 66 %, 14 % mehr Uran(VI) zu Uran(IV) als unter anaeroben Bedingungen mit ca. 52 %. Ab einem pH-Wert von 7 konnte eine Reduktion nur unter sauerstofffreien Bedingungen festgestellt werden. Die Wechselwirkung von U(VI) in Gegenwart von Glucose wurde hinsichtlich Reduktion und Komplexierung des Uran(VI) betrachtet. Mit Hilfe der zeitaufgelösten laserinduzierten Fluoreszenzspektroskopie bei tiefen Temperaturen wurde dabei ein Uranyl(VI)-Glucose-Komplex nachgewiesen. Die Komplexierung wurde lediglich bei pH 5 beobachtet und weist eine Komplexbildungskonstante von log βI=0,1 M = 15,25 ± 0,96 für den [UO2(C6H12O6)]2+-Komplex auf. Mit einer Fluoreszenzlebensdauer von 20,9 ± 2,9 µs und den Hauptemissionsbanden bei 499,0nm, 512,1 nm, 525,2 nm, 541,7 nm und 559,3 nm konnte der Uranyl(VI)-Glucose-Komplex fluoreszenzspektroskopisch charakterisiert werden. Unter reduzierenden Bedingungen wurde, ab pH-Wert 4 eine auftretende Umwandlung vom sechswertigen zum vierwertigen Uran durch Glucose in Gegenwart von Licht beobachtet. Der Anteil an gebildetem Uran(IV) steigt asymptotischen bis zu einem pH-Wert von 9, wo das Maximum mit 16 % bestimmt wurde. Als Reaktionsprodukt der Redoxreaktion wurde eine Uran(VI)-Uran(IV)-Mischphase mit der Summenformel [UIV(UVIO2)5(OH)2]12+ identifiziert. Mit Hilfe der cryo-TRLFS wurde, durch Verminderung von Quencheffekten die Uranspeziation in natürlichen Medien (Urin, Mineralwasser) direkt bestimmt. Proben mit Uran Konzentrationen von < 0,1 µg/L konnten dadurch analysiert werden. In handelsüblichen Mineralwässern wurde die zu erwartende Komplexierung durch Carbonat nachgewiesen. Im Urin zeigte sich in Abhängigkeit vom pH-Wert eine unterschiedliche Uranspeziation. Die fluoreszenzspektroskopische Untersuchung wies bei niedrigerem pH Wert (pH<6) eine Mischung aus Citrat- und Phosphat-Komplexierung des U(VI) und bei höheren pH-Wert (pH>6) eine deutliche Beteilung von Carbonat an der Komplexierung auf. Diese Ergebnisse stehen in sehr guter Übereinstimmung mit theoretischen Modellrechnungen zur Uranspeziation im Urin. Die in dieser Arbeit gewonnenen Ergebnisse zeigen, dass für eine zuverlässigere Prognose des Urantransportes in Geo- und Biosphäre in Zukunft nicht nur Betrachtungen zur Komplexchemie, sondern auch zum Redoxverhalten des Urans nötig sind, um die Mobilität in der Natur richtig abschätzen zu können.:I. Zusammenfassung XI II. Summary XV III. Danksagung XIX 1. Motivation und Zielstellung 1 2. Grundlagen 2 2.1. Zur Chemie des Urans 2 2.1.1. Uran im aquatischen System 2 2.1.2. Redoxchemie des Urans 7 2.2. Citronensäure 10 2.3. Glucose 16 2.4. Komplexbildungskonstanten 22 3. Spektroskopie 28 3.1. Spektroskopie des Urans 30 3.1.1. UV/VIS-Spektroskopie 30 3.1.2. Zeitaufgelöste laserinduzierte Fluoreszenzspektroskopie 32 3.1.3. Infrarot-Spektroskopie 36 3.1.4. Spektroskopie bei tiefen Temperaturen 38 3.2. Spektroskopie organischer Verbindungen 40 4. Ergebnisse und Diskussion 43 4.1. Zur Fluoreszenz des Urans 43 4.1.1. Uran(V)-Fluoreszenz 43 4.1.1.1. Nachweis der Uran(V)-Fluoreszenz 43 4.1.1.2. Mikroskopische Visualisierung der Uran(V)-Fluoreszenz 47 4.1.1.3. Verifizierung der Anregungswellenlänge 408 nm 50 4.1.2. Temperaturabhängigkeit der Fluoreszenz des freien Uranyl(VI)-Ions 52 4.2. Wechselwirkung von Uran mit Citronensäure 54 4.2.1. Uran(VI)-Komplexierung durch Citronensäure 54 4.2.1.1. Photochemische Stabilität 54 4.2.1.2. Spektroskopische Untersuchung zur Uran(VI) Komplexierung durch Citronensäure 55 4.2.1.3. Bestimmung der Komplexbildungskonstanten 63 4.2.2. Uran(IV)-Komplexierung mit Citronensäure 68 4.2.2.1. Spektroskopische Untersuchung zur Uran(IV) Komplexierung durch Citronensäure 68 4.2.2.2. Bestimmung der Komplexbildungskonstanten zwischen Uran(IV) und Citronensäure 69 4.2.3. Uran(VI)-Reduktion durch Citronensäure 72 4.3. Wechselwirkung von Uran mit Glucose 79 4.3.1. Komplexierung von Uran(VI) mit Glucose 79 4.3.1.1. Photochemische Stabilität 79 4.3.1.2. pH-Abhängigkeit der Komplexierung 82 4.3.1.3. Bestimmung der Komplexbildungskonstante 89 4.3.2. Reduktion von Uran(VI) durch Glucose 92 4.3.2.1. pH-Abhängigkeit 92 4.3.2.2. Identifizierung der Reaktionsprodukte der Redoxreaktion 94 4.3.2.3. Reduktion durch verschiedene Zuckerderivate 97 4.3.2.4. Reduktion im gepufferten System 99 4.4. Zur Bestimmung der Uranspeziation in natürlichen Proben 101 5. Anwendung der Erkenntnisse auf die zukünftige Betrachtung uranhaltiger Umweltsysteme 108 5.1. Komplexbildungsreaktionen 108 5.2. Redoxreaktionen 112 6. Experimenteller Teil 115 6.1. Chemikalien 115 6.2. Bestimmung der molaren Extinktionskoeffizienten von Uran(IV) 116 6.3. Uran(V)-Fluoreszenz 119 6.4. Temperaturabhängigkeit der Uranyl(VI)-Fluoreszenz 120 6.5. Stabilität citronensäurehaltigen Uranyl(VI)-Lösungen 120 6.6. Komplexierung zwischen Uran(VI) und Citronensäure 121 6.7. Komplexierung zwischen Uran(IV) und Citronensäure 122 6.8. Reduktion von Uran(VI) durch Citronensäure 122 6.9. Stabilität glucosehaltigen Uranyl(VI)-Lösungen 122 6.10. Komplexierung zwischen Uran(VI) und Glucose 123 6.11. Reduktion von Uran(VI) durch Glucose 124 6.12. Uran in natürlichen Proben 125 7. Geräte 127 7.1. Lasersysteme 127 7.2. UV/VIS-System 129 7.3. IR-Systeme 129 7.4. Neonlicht 131 7.5. Elementaranalysen 131 7.6. pH-Wert-Messung 132 7.7. Experimente unter Inertgas 132 7.8. Proben schütteln 132 7.9. Probenzentrifugation 132 8. Literaturverzeichnis 133 9. Abkürzungen und Symbole 147 10. In Verbindung mit dieser Arbeit entstandene Publikationen 151

info:eu-repo/classification/ddc/546

ddc:546

[pt] EFEITOS CAUSADOS PELO IMPACTO DE ÍONS DE MEV EM METEORITOS DO TIPO CONDRITO ORDINÁRIO: INTEMPERISMO ESPACIAL / [en] EFFECTS PRODUCED BY MEV ION IMPACT ON ORDINARY CHONDRITE METEORITES: SPATIAL WEATHERING

JEAN MICHEL DA SILVA PEREIRA

18 March 2020

[pt] Corpos relativamente pequenos do sistema solar não possuem atmosfera (ou muito rarefeita, chamada exosfera) e nem campo magnético: encontram-se praticamente desprotegidos da influência do ambiente espacial no qual estão inseridos. Tais corpos (como a maioria dos asteroides, luas e cometas distantes do Sol), estão sujeitos aos efeitos do chamado intemperismo espacial. Com o objetivo de simular e estudar este fenômeno em laboratório, três amostras de meteoritos do tipo condrito ordinário foram irradiadas por feixes de H(positivo) com energia de 1,0 MeV. Uma das amostras foi, também, irradiada por feixe de N(positivo) de 2,0 MeV. Os efeitos da irradiação foram monitorados por espectroscopias Raman e UV-VIS-NIR. Os resultados Raman mostram variações sistemáticas do número de onda, da intensidade e da largura das bandas vibracionais estudadas, evidências de modificações estruturais. As seções de choque de destruição das ligações Si-O presentes nas estruturas cristalinas foram determinadas. A espectroscopia UV-VIS-NIR por refletância de esfera integrada foi usada para monitorar as modificações nas características espectrais. Os espectros obtidos mostram escurecimento e avermelhamento progressivos das amostras irradiadas; a amplitude destas modificações depende do conteúdo inicial de ferro na estrutura. É proposto que o avermelhamento observado com o aumento da fluência (ou dose) da irradiação deve-se ao aumento do coeficiente de absorção na faixa azul que, por sua vez, decorre da diminuição do gap óptico do material. Estes resultados são relevantes para a modelagem da evolução físico-química de asteroides expostos ao vento solar. / [en] Relatively small bodies in the solar system have no atmosphere (or very thin, called the exosphere) and no magnetic field: they are virtually unprotected from the influence of the space environment in which they are inserted. Such bodies (like most asteroids, moons, and comets far from the sun), are subject to the effects of so-called space weathering. To simulate and study this phenomenon in the laboratory, three samples of ordinary chondrite meteorites were irradiated by H(positive) beams with 1.0 MeV energy. One of the samples was also irradiated by a 2.0 MeV N(positive) beam. The effects of irradiation were monitored by Raman and UV-VIS-NIR spectroscopies. The Raman results show systematic variations in the wavenumber, intensity, and width of the studied vibrational bands, evidence of structural modifications. The shock sections of the destruction of Si-O bonds present in the crystalline structures were determined. Integrated sphere reflectance UV-VIS-NIR spectroscopy was used to monitor changes in spectral characteristics. The obtained spectra show progressive darkening and reddening of the irradiated samples; The extent of these modifications depends on the initial iron content in the structure. It is proposed that the redness observed with the increase of irradiation creep (or dose) is due to the increase in the absorption coefficient in the blue band, which, in turn, results from the decrease of the optical gap of the material. These results are relevant for modeling the physicochemical evolution of asteroids exposed to the solar Wind.

[pt] ESPECTROSCOPIA

[pt] ESPECTROSCOPIA UV VIS NIR

[pt] IRRADIACAO POR IONS DE MEV

[pt] CONDRITO ORDINARIO

[pt] METEORITO

[en] SPECTROSCOPY

[en] UV VIS NIR SPECTROSCOPY

[en] MEV ION IRRADIATION

[en] ORDINARY CHONDRITE

[en] METEORITE

Synthèse et caractérisation de nouveaux complexes polymétalliques à base de ligands tridentates comprenant des groupements carboxylates

Theobald, Isabelle

January 2007

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

Ruthénium

Terpyridine

Triazine

Dimère de rhodium

Électrochimie

UV-Vis

Fluorescence

Structure Rayons-X

Phostosynthèse artificielle

Identification of Major Organic Constituents of Saffron Isolated by Solid Phase Extraction and Column Chromatography

Alsudairy, Ziad

31 July 2019

Water extracts of saffron, a spice derived from the plant Crocus Sativus L. obtained from India and Iran, were analyzed by liquid chromatography-mass spectrometry (LC-MS) and gas chromatography-mass spectrometry (GC-MS). The components in the extracts were separated on four different solid phase extraction cartridges with four different solvents and by silica gel column. Analysis was done by GC-MS, LC-MS and UV-Vis spectroscopy. The extracts separated into three distinct bands (two bright yellow and one orange) on the silica gel column. Based on GC-MS, the extracted compounds show many structural similarities. Using both extraction techniques, several compounds were identified that were not previously reported to be in saffron. Picrocrocin, safranal, and crocins presence in the extracts were evidenced by absorbance bands at wavelengths of 250 nm, 310 nm and 440 nm, respectively, in their UV-Vis spectra. The LC-MS analysis revealed several high molecular weight compounds that were not observed by GC-MS.

Saffron

Liquid Chromatography

GC-MS

UV-Vis spectra

LCMS

Food Chemistry

Life Sciences

ESTUDO DAS PROPRIEDADES DAS PORFIRINAS TMPyP E ZnTPPS4 PARA POTENCIAL APLICAÇÃO EM TERAPIA FOTODINÂMICA

Mendes, Marilei Casturina

17 November 2008

Made available in DSpace on 2017-07-24T19:38:00Z (GMT). No. of bitstreams: 1 Marilei Casturina.pdf: 1682032 bytes, checksum: 153b370b1eb7a1287824bf96aa0d0d65 (MD5) Previous issue date: 2008-11-17 / In this work is to porphyrin free base, cationic, meso-tetrapyridylporphyrin, TMPyP,and porphyrin metal, anion, zinc (II)-meso-Tetrakis (4-sulfonatophenyl), ZnTPPS4, in order to assess its possible applications in photodynamic therapy (PDT). For both, were investigated by molecular spectroscopy and UV-Vis, some properties of these porphyrins, such as interaction with biomimetic models, the ability to aggregate in different proportions water/ethanol, the photo-bleaching before lighting the red LEDs and generation of singlet oxygen through the test of uric acid. Microbiological tests were also conducted with Artemia salina and the bacterium Escherichia coli, to assess the in vitro photodynamic action on these microorganisms. The spectral behavior of porphyrin ZnTPPS4 was estimated to be varying the pH of the solution of porphyrin in aqueous medium and acetate/phosphate in the presence and absence of surfactant SDS (anion), CTAB (cationic) and HPS (zwiterionic). Through this analysis, we found that the porphyrin spectral change due to changes in pH, occurred at pHs lower when the porphyrin found himself in the presence of surfactants CTAB and HPS, indicating that there was interaction between porphyrin/ micelle surfactant, mediated by hydrophobic and electrostatic interactions. The ability of aggregation was evaluated by adding the solution of the porphyrin mixtures water/ethanol in different proportions in order to analyze the spectral behavior of both porphyrins with the increase of water content. Through this analysis it was found the displacement of the Soret band for a wavelength smaller, and the decrease in absorbance intensity of the condition of 100% water, a fact that may be related to different coefficients of molar absorptivity of porphyrins in solvents used. The photobleaching was putting itself and ethanol aqueous solutions of porphyrin under lighting of LEDs red during a total period of 1 hour, and showed that both porphyrins do not fall apart before the light source used. As the generation of singlet oxygen conducted through the test of uric acid, found that the generation of this species is better in water than ethanol, probably because there is more molecular oxygen dissolved in the first solvent. The porphyrin TMPyP showed increased photodynamic activity (PA) that ZnTPPS4, due to higher absorption in the range of issuing LEDs employees. Regarding microbiological tests found that the highest viewing on A. salina mortality occurs in the presence of porphyrin and under illumination, indicating photodynamic action of porphyrins on the microorganism. The testing done with E. coli, it is further inhibit the growth of this microorganism colonies where they were treated with porphyrins and light, compared with the controls: I) under light and without porphyrin; II) in the presence of porphyrin and no light; III) in the absence of light and porphyrin. / Neste trabalho estudou-se a porfirina base livre, catiônica, meso-tetrakis(4-metilpiridil)porfirina, TMPyP e a porfirina metalada, aniônica, Zinco(II)-mesotetrakis(4-sulfonatofenil), ZnTPPS4, para avaliar suas possíveis aplicações em terapia fotodinâmica (TFD). Para tanto, foram investigadas através de espectroscopia molecular UV-Vis, a interação das referidas porfirinas com modelos biomiméticos, a capacidade de agregação em diferentes proporções água/etanol, o foto-branqueamento perante iluminação de LEDs vermelhos e a geração de oxigênio singlete através do teste do ácido úrico. Também foram realizados testes com a Artemia salina e com a bactéria Escherichia coli, a fim de avaliar a ação fotodinâmica in vitro sobre esses microrganismos. O comportamento espectral da porfirina ZnTPPS4, foi avaliado variando-se o pH da solução de porfirina em meio aquoso e em acetato/fosfato na presença e na ausência dos surfactantes SDS (aniônico), CTAB (catiônico) e HPS (zwiteriônico). Através dessa análise, verificou-se que a mudança espectral da porfirina em decorrência da variação de pH, ocorreu em pHs menores quando a porfirina encontrou-se na presença dos surfactantes CTAB e HPS, indicando que houve interação entre porfirina/micela de surfactante, mediada por interações hidrofóbicas e eletrostáticas. A capacidade de agregação foi avaliada, acrescentando solução das porfirinas a misturas água/etanol de diferentes proporções, a fim de analisar o comportamento espectral de ambas as porfirinas com o aumento do teor de água. Através dessa análise verificou-se o deslocamento da banda Soret para comprimentos de onda menores, bem como, a diminuição da intensidade da absorbância em condição de 100% de água, fato que pode estar relacionado aos diferentes valores de coeficiente de absortividade molar das porfirinas nos solventes utilizados. A análise de foto-branqueamento foi realizado colocando-se soluções aquosas e etanólicas de porfirina sob iluminação de LEDs vermelhos durante um período total de 1 hora, e mostrou que ambas as porfirinas não se decompõem perante a fonte de luz empregada. Quanto a geração de oxigênio singlete realizado através do teste do ácido úrico, verificou-se que a geração dessa espécie é melhor em água que etanol. A porfirina TMPyP mostrou maior atividade fotodinâmica (AF) que a ZnTPPS4, por possuir maior absorção na faixa de emissão dos LEDs empregados. Em relação aos testes microbiológicos verificou-se que o maior índice de mortalidade sobre A. salina ocorre na presença das porfirina e sob iluminação, indicando ação fotodinâmica das porfirinas sobre esse microrganismo. No teste feito com a E. coli, evidenciou-se maior inibição no crescimento das colônias desse microrganismo quando as mesmas foram tratadas com porfirinas e luz, em comparação com os controles: I) sob luz e sem porfirina; II) na presença de porfirina e sem luz; III) na ausência de luz e porfirina.

TMPyP

ZnTPPS4

terapia fotodinamica

Escherichia coli

Artemia Salina

UV-Vis

Síntese, caracterização e estudo fotofísico de novas estruturas fotoativas e seu potencial uso como sensores ópticos

Silva, Cláudia de Brito da

January 2014

Este trabalho apresenta a síntese de novos compostos fotoativos contendo os grupos uréia e tiouréia e suas potenciais aplicações como sensores de ânions. Os compostos sintetizados foram caracterizados pelas técnicas de FTIR, RMN de 1H e 13C, onde foi possível confirmar obtenção dos compostos. Os compostos obtidos apresentam absorção na região do ultravioleta com valores de extinção molar de acordo com as transições -*. Com objetivo de testar os novos compostos sintetizados como sensor de ânions foi realizado um estudo fotofísico na presença de diferentes ânions, sendo todos como sais de tetrabutilamônio. Esses testes também foram realizados utilizando o método de detecção visual e a espectroscopia de RMN 1H indicando que os compostos 32 e 33 apresentaram resposta colorimétrica após a adição de fluoreto. / This work presents the synthesis of novel photoactive compounds containing the urea and thiourea groups and its potential application as sensors for anions in solution. The synthesized compounds were characterized by FTIR, 1H and 13C NMR techniques. The compounds show absorption in the ultraviolet region with values of molar extinction accordingly to -* electronic transitions. In order to test the new compounds as optical sensors for anions, photophysical studies, as well as the method of visual detection and 1H NMR titration were performed in the presence of different anions as tetrabutylammonium salts. Fluoride could be successfully detected by UVVis and 1H NMR titration using compounds 32 and 33.

Sintese organica

Benzazolas

Fluorescência

Tiouréia

Ureia

Benzazole

Urea

Thiourea

Optical sensors

UV-Vis

Fluorescence

Improving the stability of the black carrot (Daucus carota L.) colourant

Iliopoulou, Ioanna

January 2016

The replacement of artificial with natural dyes is one of the most challenging research fields in the food production area. Recent studies have shown that some frequently used synthetic colours, called the “Southampton 6 Colours” may be linked with hyperactivity in children. The purpose of this work is to analyse the degradation behaviour of black carrot, a natural, red dye commonly used for colouring food products, and subsequently improve its stability during heat and storage conditions. The stability of the black carrot mixture to heat exposure was investigated at a range of pH values by heat-treating aqueous solutions in a domestic oven at around 180oC to maintain the temperature at 100oC and the powdered material in a furnace at 180oC (typical baking conditions). 1H NMR (800 MHz) spectroscopy was used for the assignment of the aromatic chemical shifts of the black carrot mixture by overlaying them with the characterised 1H NMR chemical shifts of the individual components separated by RP-HPLC. Integration of high-resolution 1H NMR (800 MHz) spectra was used to follow the relative degradation of each of the components. Different procedures for the complexation of black carrot with metal oxides were developed, for which colourants of different colour shades were prepared. Spectroscopic techniques were used to follow the degradation of the complexes which were heat-treated at 180oC. Nano-scale investigation of the metal oxide powders was also carried out. The optimised colourants were tested on a bench scale and subsequently on an industrial scale in food pilot procedures. The successful complexes produced were found to be more heat stable compared to the commercial black carrot dye. The developed technologies are cheap and easy-to-produce methods to create intense heat and storage stable coloured pigments which can be used for the replacement of existing artificial dyes during food processing.

664

Modeling the peak absorption of MEH-PPV in various solvents using Density Functional Theory

Moore, Corell H

01 January 2019

Density Functional Theory (DFT) and time-dependent Density Functional Theory (TD-DFT) are powerful tools for modeling orbital energy in conjugated molecules and have been useful tools for research in organic photovoltaics. In this work, DFT is first used to explain the red shift in the absorption spectrum and increased absorption observed in MEH-PPV. Initially, the modeling of the red-shift in the absorption peak of MEH-PPV is studied using Gaussian 03 software with the global hybrid functional B3LYP for exchange-correlation and the 6-31G basis set. DFT and TD-DFT are used to separately study the effects of polymer chain length, carbon-carbon double-bond stretching, and the polymer in solution vs. in gas space on red shift in absorption spectrum. Next, Gaussian 09 software and the same B3LYP functional and 6-31G basis set are used to study interchain and intrachain interactions of MEH-PPV in solution. The red shift in the absorption peaks for three MEH-PPV configurations (single-chain pentamer, two stacked pentamers, and decamer) are compared with experimental results for five different solvents (chloroform, toluene, xylene, dichloromethane, and chlorobenzene). This investigation indicates that inter-chain interactions dominate in “good” aromatic solvents as compared to “poor” non-aromatic solvents. The results suggest that inter-chain charge transfer interactions play a critical role in real solutions and inter-chain aggregation takes precedence over intra-chain aggregation in aromatic solvents. In the final section of the study, accurate values for the range-separation parameter (w) for three lengths of MEH-PPV polymer (trimer, tetramer, and pentamer) in five different solvents (chloroform, chlorobenzene, xylene, Tetrahydrofuran, and dichloromethane) are reported using the range-separated functionals wB97XD and CAM-B3LYP. Using these data, range separation parameters are predicted and used for longer polymer chains in chloroform solution. The differences in the range separation parameters for the different solvents is statistically significant and gives further insight into the polymer/solvent interaction.

DFT

Uv-Vis

Absorption

polymer solar cells

red-shift

range separation parameter

Polymer and Organic Materials

Electrical, Optical and Thermal Investigations of Cobalt Oxide-Antimony Doped Tin Oxide (CoO-ATO) Thin Films and Nanofiber Membranes

Roy, Nirmita

02 November 2017

The main aim of this thesis work is to investigate the electrical, optical and thermal impact characteristics of cobalt oxide doped antimony tin oxide (CoO-ATO) in the form of thin films and nanofiber membranes. CoO-ATO is a novel composite material that has the potential to be used as reinforced aircraft coatings, military garment coatings, or more specifically as an anti-reflective (AR) top coating for photovoltaic (PV) cells. This work will be critical in determining the effectiveness of using a CoO-ATO layer in these applications. Electrospun nanofibers and spin coated thin films consisting of a polymeric solution of CoO-ATO will be used. Thin films are created using spin coating techniques, and nanofiber membranes are created using an electrospinning technique. Polystyrene (PS) will be used as a solute, and chloroform as a solvent, to create the solution. It is hypothesized that coatings of this material will have improved optical characteristics as compared to traditional ATO coatings and minimum impact from thermal cycling making it a favorable candidate for PV cells. This work will do an electrical, optical and thermal cycling impact characterization of CoO-ATO thin films and nanofiber membranes for a doping range of x% CoO where x ranged from 0.2

Solar cell

Electro spinning

Spin coating

UV-VIS

FTIR

Thermal impact

Electrical and Computer Engineering

Probing Iron Accumulation in Sacchromyces cerevisiae Using Integrative Biophysical and Biochemical Techniques

Miao, Ren

2010 December 1900

Iron is an essential element for life. It is involved in a number of biological processes, including iron sulfur (Fe/S) cluster assembly and heme biosynthesis. However it is also potentially toxic due to its ability to induce formation of reactive oxygen species (ROS) via Fenton chemistry. Therefore its uptake, trafficking and utilization must be regulated to avoid its toxicological effect. It has been recently discovered that Fe/S cluster biosynthesis machinery plays a key role in the cellular iron regulation and its disruption leads to impaired iron regulation and iron accumulation within mitochondria. The iron accumulation resulted from impaired Fe/S cluster assembly in the eukaryotic model organism Saccharomyces cerevisiae (baker’s yeast) was studied. Various biophysical (e.g. Mössbauer, EPR, UV-vis spectroscopy) and biochemical (e.g. Western blots, PCR, enzyme activity assay, etc.) techniques were used to characterize the iron content in yeast mitochondria isolated from several mutants strains. In these mutants one of the proteins involved in Fe/S cluster biosynthesis (Yah1p and Atm1p) is mutated and iron regulation and metabolism are disrupted. By integrating the results obtained from these different methods, it was determined that excess iron accumulates in the mutant mitochondria as inorganic phosphate Fe(III) nano-particles exhibiting superparamagnetic behaviors. Oxygen is required for iron accumulation and nanoparticle formation. The Fe(III) nano-particles can be chemically reduced to Fe(II) then largely exported from the mitochondria. These biophysical and biochemical methods were also used to examine the iron distribution in whole yeast cells of the Aft1-1up strain in which iron regulon genes are constitutively activated and compared to that of Yah1p-depleted and wild type yeast. Constitutive activation of iron regulon genes does not alter the cellular iron distribution significantly. However disruption of Fe/S cluster assembly by Yah1p depletion causes dramatic cellular iron redistribution: the vacuolar iron is largely evacuated and most of the cellular iron probably precipitates in mitochondria as Fe(III) nanoparticles. The results provide novel insights into iron trafficking and possible signal communications between organelles within cells.

Biological iron

Mossbauer spectroscopy

EPR spectroscopy

Electron microscopy

XAS spectroscopy

UV-vis spectroscopy

Nanoparticles