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Synthesis of Insulin-Regulated Aminopeptidase (IRAP) inhibitorsAgalo, Faith January 2015 (has links)
The need for alternative cognitive enhancers has risen due to the fact that clinical trial results of the drugs currently approved for treating these disorders have not been satisfactory. IRAP has become a possible drug target for treating cognitive impairment brought about by Alzheimer’s disease, head trauma or cerebral ischemia, among others. This came after the revelation that Angiotensin IV enhances memory and learning. Angiotensin IV, the endogenous ligand of IRAP has been structurally modified with the aim of producing potent IRAP inhibitors. However, the peptidic nature of these inhibitors restricts their use; they are not likely to cross the blood brain barrier. Other strategies for generating IRAP inhibitors have been through structure-based design and receptor based virtual screening. These drug-like molecules have exhibited positive results in animal studies. IRAP inhibitors have been identified via a HTS of 10500 low-molecular weight compounds to give the hit based on a spirooxindole dihydroquinazolinone scaffold, with an IC50 value of 1.5 µM. In this project, some analogues to this hit compound have successfully been synthesized using a known method, whereas others have been synthesized after additional method development. The application of the developed method was found to be limited, because poor yield was obtained when a compound with an electron withdrawing substituent on the aniline was synthesized. As a result of this, modification of this method may be required or new methods may have to be developed to synthesize these types of analogues. Inhibition capability of 5 new spirooxindole dihydroquinazolinones was tested through a biochemical assay. Compound 6e emerged as the most potent inhibitor in the series, with an IC50 value of 0.2 µM. This compound will now serve as a lead compound and should be used as a starting point for future optimization in order to generate more potent IRAP inhibitors.
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Low-Cost Microwave-Assisted Partial Pseudomorphic Transformation of Biogenic SilicaSchneider, Denise, Kircheis, Ralf, Wassersleben, Susan, Einicke, Wolf-Dietrich, Gläser, Roger, Enke, Dirk 03 April 2023 (has links)
This work introduces a cost and time efficient procedure to specifically increase
mesopore volume and specific surface area of biogenic silica (specific surface area:
147 m2 g−1 and mesopore volume: 0.23 cm3 g−1) to make it suitable for applications
in adsorption or as catalyst support. The target values were a specific surface
area of ∼500 m2 g−1 and a mesopore volume of ∼0.40–0.50 cm3 g−1 as these
values are industrially relevant and are reached by potential concurring products such
as precipitated silica, silica gel, and fumed silica. The applied process of partial
pseudomorphic transformation was carried out as a single reaction step in a microwave
reactor instead of commonly used convective heating. In addition, the conventionally
used surfactant cetyltrimethylammonium bromide (CTABr) was substituted by the
low-cost surfactant (Arquad® 16-29, cetyltrimethylammonium chloride (CTACl) aqueous
solution). The influence of microwave heating, type of surfactant as well as the
concentration of NaOH and CTACl on the textural and structural properties of the
modified biogenic silica was investigated using nitrogen adsorption as well as scanning
and transmission electron microscopy. The results show that the textural parameters of
the modified biogenic silica can be exactly controlled by the amount of NaOH in the
reaction solution. By variation of the NaOH concentration, specific surface areas in the
range of 215–1,001m2 g−1 andmesopore volumes of 0.25–0.56 cm3 g−1 were achieved
after reaction at 393 K for 10min. The presented microwave route using the low-cost
surfactant solution decreases the reaction time by 99% and as shown in an example for
German prices, lowers the costs for the surfactant by 76–99%.
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Luminescência persistente no visível e infravermelho em oxissulfetos de terras raras preparados por síntese no estado sólido assistida por micro-ondas / Red and infrared persistent luminescence in rare earth oxysulfides prepared by a microwave-assisted solid-state synthesisMachado, Ian Pompermayer 14 April 2016 (has links)
A maioria dos materiais que apresentam o fenômeno da luminescência persistente possuem o íon Eu2+ como ativador, exibindo emissões sintonizáveis entre o azul e o verde. Entretanto, materiais com luminescência persistente na região do vermelho e infravermelho próximo (Near Infrared - NIR) são ainda pouco reportados na literatura. Portanto, foram preparados neste trabalho os materiais TR2O2S.Ln3+ e TR2O2S.Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd e Y; Ln3+: Eu e Yb) pelo método de síntese no estado sólido assistido por micro-ondas. Os materiais foram caracterizados pelas técnicas de Difração de raios X (DRX), Microscopia eletrônica de varredura (MEV), Espectroscopia de absorção no infravermelho (IV), Espectroscopia de absorção de raios X próximo a borda com radiação síncrotron (XANES), Termoluminescência (TL) e Espectroscopia de excitação na região do UV-UV vácuo com radiação síncrotron. Quando excitados na banda de absorção da matriz (band gap) ou por exemplo, nas bandas de transferência de carga LMCT O2-(2p) → Eu3+(4f6) e S2-(3p) → Eu3+(4f6), os materiais TR2O2S:Eu3+ e TR2O2S:Eu3+,Mg2+,Ti3+/IV apresentam um grande número de bandas de emissão finas atribuídas às transições 5D2,1,0 → 7FJ do íon Eu3+. Os dados espectroscópicos sugerem um alto grau de covalência e uma baixa energia de fônons para as matrizes TR2O2S. Além do mais, os materiais TR2O2S:Yb3+ e TR2O2S:Yb3+,Mg2+,Ti3+/IV apresentam bandas de emissão finas na faixa 900-1050 nm (NIR) atribuídas à transição 2F5/2 → 2F7/2 do íon Yb3+. Os mecanismos de luminescência persistente foram propostos para os materiais TR2O2S:Ln3+ e TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd e Y; Ln3+: Eu, Yb) e podem ser via armadilhamento de buracos ou via armadilhamento de elétrons. O mecanismo via armadilhamento de buracos é relativo à excitação dos íons Eu3+ e Yb3+ e explica a existência do fenômeno da luminescência persistente nos materiais sem co-dopantes (TR2O2S:Eu3+ e TR2O2S:Yb3+). De outra forma, o mecanismo via armadilhamento de elétrons ocorre nos materiais TR2O2S:Eu3+,Mg2+,Ti3+/IV e TR2O2S:Yb3+,Mg2+,Ti3+/IV para a emissão oriunda do íon Ti3+. Nos materiais TR2O2S:Eu3+,Mg2+,Ti3+/IV observa-se o processo de transferência de energia Ti3+ → Eu3+, o que leva a uma luminescência persistente mais eficiente do íon Eu3+. Por outro lado, devido à grande diferença de energia entre os íons Ti3+ e Yb3+, o processo de transferência de energia Ti3+ → Yb3+ não acontece para os materiais TR2O2S:Yb3+,Mg2+,Ti3+/IV. Portanto, a luminescência persistente ocorre via mecanismo de armadilhamento de buracos simultaneamente ao de armadilhamento de elétrons, obtendo uma luminescência persistente com contribuição no visível oriunda do íon Ti3+ e no NIR do íon Yb3+. Os materiais apresentam um grande potencial em aplicações e inovação tecnológica na área de fotônica como sondas biológicas luminescentes e sensibilizadores de células solares. / Most of persistent luminescent materials have the Eu2+ ion as an activator, displaying tunable emission color from blue to green region. However, there is a few examples of red and near infrared (NIR) persistent luminescent materials reported in literature. In this work, the TR2O2S:Ln3+ and TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd and Y; Ln3+: Eu and Yb) luminescent materials were prepared by microwave-assisted solid state synthesis. The materials were characterized with X-ray diffraction, Scanning electron microscopy, Infrared absorption spectroscopy, synchrotron radiation X-ray absorption spectroscopy near edge (XANES), Thermoluminescence (TL) and synchrotron radiation UV-VUV spectroscopy. When excited at the host absorption band (band gap) or at the ligand-to-metal-charge-transfer bands (LMCT), O2-(2p) → Eu3+(4f6) and S2-(3p)→ Eu3+(4f6), the materials TR2O2S:Eu3+ and TR2O2S:Eu3+,Mg2+,Ti3+/IV display a large number of narrow emission bands assigned to Eu3+ 5D2,1,0→7FJ transitions. Spectroscopic data indicate a high degree of covalency and low phonon energy of TR2O2S hosts. The TR2O2S:Yb3+ and TR2O2S:Yb3+,Mg2+,Ti3+/IV materials show emission bands in the range from 900 to 1050 nm (NIR) assigned to the 2F5/2→2F7/2 transitions of Yb3+ ion. The persistent luminescence mechanisms were proposed for TR2O2S:Ln3+ and TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd and Y; Ln3+: Eu and Yb) materials, there are two possible ways, hole-trapping or electron-trapping mechanisms. The hole-trapping mechanism is related to the excitation of Eu3+ and Yb3+ ions and explains the persistent luminescence phenomenon in non-co-doped materials (TR2O2S:Eu3+ and TR2O2S:Yb3+). The electron-trapping mechanism governs the persistent luminescence of Ti3+ ion in TR2O2S:Eu3+,Mg2+,Ti3+/IV and TR2O2S:Yb3+,Mg2+,Ti3+/IV materials. The Ti3+ → Eu3+ energy transfer was observed in TR2O2S:Eu3+,Mg3+,Ti3+/IV materials and leads to an improvement of Eu3+ persistent luminescence. On the other hand, due to the large energy levels gap between Ti3+ and Yb3+ ions, there is no Ti3+→Yb3+ energy transfer in TR2O2S:Yb3+,Mg2+,Ti3+/IV materials. Therefore, the persistent luminescence in these materials occurs with hole-trapping and electron-trapping mechanisms simultaneously, obtaining a visible-NIR persistent luminescence composed by Ti3+ and Yb3+ emissions, respectively. The materials exhibit great potential in biological and technological innovation in photonic areas such as luminescent probes and solar cell sensitizers
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Síntese de micro-ondas para padrões atômicos de frequência de césio¹³³ / Microwave Synthesizer for Cesium¹³³ Atomic Frequencies StandardsOtoboni, Felipe Arduini 10 April 2013 (has links)
Esta dissertação propõe o projeto e a implementação de um sintetizador de sinal pertencente à banda X, com frequência de 9.192 GHz, para promover a transição atômica do átomo de césio durante o ciclo de operação do padrão atômico de frequência do CePOF/IFSC. Diferente do sintetizador em uso, este provê duas fontes de sinais, a fim de realizar a alimentação simétrica da cavidade de micro-ondas. A alimentação simétrica apresenta uma melhoria em relação à montagem experimental atual e visa atenuar os efeitos de gradiente de potência ao quais os átomos estão expostos enquanto cruzam a cavidade de interrogação. O sintetizador também apresenta um controle de fase em um dos sinais, para que seja possível um ajuste de fase entre eles, permitindo que ambos cheguem à cavidade de interrogação em fase. O método utilizado para a síntese dos sinais é o indireto, onde o sinal de interesse é obtido por meio de osciladores e componentes que possibilitam a manipulação algébrica das frequências, aliados aos circuitos de travamento para controle dos osciladores / This text considers the design and implementation of an X-band signal synthesizer, with a 9.192 GHz frequency, to promote the atomic transition of cesium during the operation process of the CePOF/IFSCs atomic frequency standard. Unlike the current synthesizer, the present one provides two sources of signal, in order to perform the symmetrical feed of the microwave cavity. The symmetrical feed is an improvement compared to the current experimental set up and aims at reducing the power gradient effects to which the atoms are exposed when travelling throughout the interrogation cavity. The synthesizer also has a phase control in one of the signals, in order to ensure that both signals will get into the interrogation cavity in phase. The synthesis method used is the indirect one; the desired signal is formed by means of oscillators and devices that allow the algebraic manipulation of frequencies, combined with lock circuits to control the oscillators
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Luminescência persistente no visível e infravermelho em oxissulfetos de terras raras preparados por síntese no estado sólido assistida por micro-ondas / Red and infrared persistent luminescence in rare earth oxysulfides prepared by a microwave-assisted solid-state synthesisIan Pompermayer Machado 14 April 2016 (has links)
A maioria dos materiais que apresentam o fenômeno da luminescência persistente possuem o íon Eu2+ como ativador, exibindo emissões sintonizáveis entre o azul e o verde. Entretanto, materiais com luminescência persistente na região do vermelho e infravermelho próximo (Near Infrared - NIR) são ainda pouco reportados na literatura. Portanto, foram preparados neste trabalho os materiais TR2O2S.Ln3+ e TR2O2S.Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd e Y; Ln3+: Eu e Yb) pelo método de síntese no estado sólido assistido por micro-ondas. Os materiais foram caracterizados pelas técnicas de Difração de raios X (DRX), Microscopia eletrônica de varredura (MEV), Espectroscopia de absorção no infravermelho (IV), Espectroscopia de absorção de raios X próximo a borda com radiação síncrotron (XANES), Termoluminescência (TL) e Espectroscopia de excitação na região do UV-UV vácuo com radiação síncrotron. Quando excitados na banda de absorção da matriz (band gap) ou por exemplo, nas bandas de transferência de carga LMCT O2-(2p) → Eu3+(4f6) e S2-(3p) → Eu3+(4f6), os materiais TR2O2S:Eu3+ e TR2O2S:Eu3+,Mg2+,Ti3+/IV apresentam um grande número de bandas de emissão finas atribuídas às transições 5D2,1,0 → 7FJ do íon Eu3+. Os dados espectroscópicos sugerem um alto grau de covalência e uma baixa energia de fônons para as matrizes TR2O2S. Além do mais, os materiais TR2O2S:Yb3+ e TR2O2S:Yb3+,Mg2+,Ti3+/IV apresentam bandas de emissão finas na faixa 900-1050 nm (NIR) atribuídas à transição 2F5/2 → 2F7/2 do íon Yb3+. Os mecanismos de luminescência persistente foram propostos para os materiais TR2O2S:Ln3+ e TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd e Y; Ln3+: Eu, Yb) e podem ser via armadilhamento de buracos ou via armadilhamento de elétrons. O mecanismo via armadilhamento de buracos é relativo à excitação dos íons Eu3+ e Yb3+ e explica a existência do fenômeno da luminescência persistente nos materiais sem co-dopantes (TR2O2S:Eu3+ e TR2O2S:Yb3+). De outra forma, o mecanismo via armadilhamento de elétrons ocorre nos materiais TR2O2S:Eu3+,Mg2+,Ti3+/IV e TR2O2S:Yb3+,Mg2+,Ti3+/IV para a emissão oriunda do íon Ti3+. Nos materiais TR2O2S:Eu3+,Mg2+,Ti3+/IV observa-se o processo de transferência de energia Ti3+ → Eu3+, o que leva a uma luminescência persistente mais eficiente do íon Eu3+. Por outro lado, devido à grande diferença de energia entre os íons Ti3+ e Yb3+, o processo de transferência de energia Ti3+ → Yb3+ não acontece para os materiais TR2O2S:Yb3+,Mg2+,Ti3+/IV. Portanto, a luminescência persistente ocorre via mecanismo de armadilhamento de buracos simultaneamente ao de armadilhamento de elétrons, obtendo uma luminescência persistente com contribuição no visível oriunda do íon Ti3+ e no NIR do íon Yb3+. Os materiais apresentam um grande potencial em aplicações e inovação tecnológica na área de fotônica como sondas biológicas luminescentes e sensibilizadores de células solares. / Most of persistent luminescent materials have the Eu2+ ion as an activator, displaying tunable emission color from blue to green region. However, there is a few examples of red and near infrared (NIR) persistent luminescent materials reported in literature. In this work, the TR2O2S:Ln3+ and TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd and Y; Ln3+: Eu and Yb) luminescent materials were prepared by microwave-assisted solid state synthesis. The materials were characterized with X-ray diffraction, Scanning electron microscopy, Infrared absorption spectroscopy, synchrotron radiation X-ray absorption spectroscopy near edge (XANES), Thermoluminescence (TL) and synchrotron radiation UV-VUV spectroscopy. When excited at the host absorption band (band gap) or at the ligand-to-metal-charge-transfer bands (LMCT), O2-(2p) → Eu3+(4f6) and S2-(3p)→ Eu3+(4f6), the materials TR2O2S:Eu3+ and TR2O2S:Eu3+,Mg2+,Ti3+/IV display a large number of narrow emission bands assigned to Eu3+ 5D2,1,0→7FJ transitions. Spectroscopic data indicate a high degree of covalency and low phonon energy of TR2O2S hosts. The TR2O2S:Yb3+ and TR2O2S:Yb3+,Mg2+,Ti3+/IV materials show emission bands in the range from 900 to 1050 nm (NIR) assigned to the 2F5/2→2F7/2 transitions of Yb3+ ion. The persistent luminescence mechanisms were proposed for TR2O2S:Ln3+ and TR2O2S:Ln3+,Mg2+,Ti3+/IV (TR3+: La, Gd and Y; Ln3+: Eu and Yb) materials, there are two possible ways, hole-trapping or electron-trapping mechanisms. The hole-trapping mechanism is related to the excitation of Eu3+ and Yb3+ ions and explains the persistent luminescence phenomenon in non-co-doped materials (TR2O2S:Eu3+ and TR2O2S:Yb3+). The electron-trapping mechanism governs the persistent luminescence of Ti3+ ion in TR2O2S:Eu3+,Mg2+,Ti3+/IV and TR2O2S:Yb3+,Mg2+,Ti3+/IV materials. The Ti3+ → Eu3+ energy transfer was observed in TR2O2S:Eu3+,Mg3+,Ti3+/IV materials and leads to an improvement of Eu3+ persistent luminescence. On the other hand, due to the large energy levels gap between Ti3+ and Yb3+ ions, there is no Ti3+→Yb3+ energy transfer in TR2O2S:Yb3+,Mg2+,Ti3+/IV materials. Therefore, the persistent luminescence in these materials occurs with hole-trapping and electron-trapping mechanisms simultaneously, obtaining a visible-NIR persistent luminescence composed by Ti3+ and Yb3+ emissions, respectively. The materials exhibit great potential in biological and technological innovation in photonic areas such as luminescent probes and solar cell sensitizers
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Platinum@Hexaniobate Nanopeapods: Sensitized Composite Architectures for Photocatalytic Hydrogen Evolution Under Visible Light IrradiationDavis-Wheeler Chin, Clare 06 August 2018 (has links)
Hydrogen fuel is one of the most important areas of research in the field of renewable energy development and production. Hydrogen gas can be generated by fuel cells, water electrolyzers, and heterogeneous nanoscale catalysts. It can be burned to directly release chemical energy or condensed for storage and transport, providing fuel for combustion devices or storing excess energy generated by renewable sources such as wind turbines and concentrated solar power assemblies. While platinum is the most active catalyst for hydrogen reduction, its high cost significantly deters its utilization in advanced photocatalytic materials. One approach to mitigating this expense is optimizing the morphology and placement of nanostructured platinum catalysts. Highly crystalline, morphologically-controlled platinum nanoparticles (Pt NPs) have been effectively utilized to increase hydrogen generation efficiency in a variety of nanocomposite materials. However, synthesis routes to high-quality Pt NPs can be dangerous and difficult to replicate. Furthermore, utilization of the Pt NPs in nanocomposite materials is hindered by lack of control over catalyst placement.
Nanopeapods are versatile nanocomposites that offer a high degree of control over catalyst placement as well as the potential for interesting new properties arising from the interaction between the catalyst and a semiconductor. Platinum@hexaniobate nanopeapods (Pt@HNB NPPs) consist of linear arrays of Pt NPs encapsulated within the scrolled semiconductor hexaniobate. Pt@HNB NPPs offer significant advantages over similar composites by utilizing the isolated reduction environment of the encapsulated Pt NP arrays to decrease kinetic competition and surface crowding.
This work describes the design, fabrication, and implementation of the new nanocomposite platinum@hexaniobate nanopeapods for sensitized hydrogen production under visible light irradiation. The following chapters present facile microwave heating syntheses of highly crystalline Pt nanocubes and Pt@HNB NPPs with consistent morphology and high catalyst loading. A detailed study is also presented of the optical properties of the Pt nanocubes, which produced a UV-range absorbance band that indicates the formation of a localized surface plasmon resonance. Most significantly, preliminary results from visible light photolysis indicate that sensitized Pt@HNB NPPs produce hydrogen in quantities comparable to published systems, and that alteration of experimental parameters may result in even greater yields.
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Materials for depollution based on the model of manganese dioxygenasesChaignon, Jérémy, Chaignon, Jérémy 20 December 2013 (has links) (PDF)
The objective of this work is the synthesis of model material for manganese dioxygenase which is an enzyme that oxidizes catechol-like substrates with dioxygen. Our strategy comprises three main steps that form the different chapters of this thesis: - Synthesis and characterization of manganese(II) complexes with tridentate ligands. - Optimization of a microwave-assisted synthesis of a mesoporous silica. - Functionalization of these materials and complex grafting, as well as preliminary catalytic tests. The ligands used are tertiary amines containing an alkyne arm and two coordinating arms with functions such as pyridine, imidazole or carboxylate. The complexes were crystallized and/or characterized by IR, EPR, SQUID and cyclic voltamperometry. Microwave synthesis, based on the conditions of classical hydrothermal synthesis, allowed us to reduce the synthesis time from one day to two hours. The quality of these new materials was verified by IR, TGA, BET and powder XRD. These materials are then bi-functionalized using a molecular stencil patterning mehod with a an azide function for complex grafting via click chemistry and a function pyridine or trimethylsilyl to control the coordinating ability of the metal environment. These complexes and materials are active in catechol oxidation with O2.
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Síntese de micro-ondas para padrões atômicos de frequência de césio¹³³ / Microwave Synthesizer for Cesium¹³³ Atomic Frequencies StandardsFelipe Arduini Otoboni 10 April 2013 (has links)
Esta dissertação propõe o projeto e a implementação de um sintetizador de sinal pertencente à banda X, com frequência de 9.192 GHz, para promover a transição atômica do átomo de césio durante o ciclo de operação do padrão atômico de frequência do CePOF/IFSC. Diferente do sintetizador em uso, este provê duas fontes de sinais, a fim de realizar a alimentação simétrica da cavidade de micro-ondas. A alimentação simétrica apresenta uma melhoria em relação à montagem experimental atual e visa atenuar os efeitos de gradiente de potência ao quais os átomos estão expostos enquanto cruzam a cavidade de interrogação. O sintetizador também apresenta um controle de fase em um dos sinais, para que seja possível um ajuste de fase entre eles, permitindo que ambos cheguem à cavidade de interrogação em fase. O método utilizado para a síntese dos sinais é o indireto, onde o sinal de interesse é obtido por meio de osciladores e componentes que possibilitam a manipulação algébrica das frequências, aliados aos circuitos de travamento para controle dos osciladores / This text considers the design and implementation of an X-band signal synthesizer, with a 9.192 GHz frequency, to promote the atomic transition of cesium during the operation process of the CePOF/IFSCs atomic frequency standard. Unlike the current synthesizer, the present one provides two sources of signal, in order to perform the symmetrical feed of the microwave cavity. The symmetrical feed is an improvement compared to the current experimental set up and aims at reducing the power gradient effects to which the atoms are exposed when travelling throughout the interrogation cavity. The synthesizer also has a phase control in one of the signals, in order to ensure that both signals will get into the interrogation cavity in phase. The synthesis method used is the indirect one; the desired signal is formed by means of oscillators and devices that allow the algebraic manipulation of frequencies, combined with lock circuits to control the oscillators
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Hybridization of lamellar oxides : from insertion to in situ synthesis / Hybridation d'oxydes lamellaires : de l'insertion à la synthèse in situWang, Yanhui 19 October 2016 (has links)
Dans cette thèse, nous avons développé l'utilisation de l'activation microondes pour fonctionnaliser des pérovskites lamellaires et notamment la phase d'Aurivillius Bi2SrTa2O9 (BST), connue pour ses propriétés ferroélectriques. Nous sommes parvenus à protoner cette phase (HST) et à la fonctionnaliser par diverses amines et polyamines, avec des temps de réaction considérablement réduits par rapport aux fonctionnalisations en conditions classiques. Cette approche nous a permis de fonctionnaliser HST par des amines plus encombrées et plus complexes. Cette stratégie a ensuite été étendue au greffage d'alcools et de polyols. Nous avons également établi une stratégie de modification post-synthèse, pour synthétiser in situ la molécule désirée, en utilisant la chimie "click" et l'activation microondes. Enfin, nous sommes parvenus à insérer des ions métalliques et des complexes de métaux de transition, ce qui constitue une première étape vers la synthèse de nouveaux hybrides multiferroïques. / During this PhD thesis, we have developed the use of microwave activation to functionalize layered perovskites, among which the Aurivillius phase Bi2SrTa2O9 (BST), known for its ferroelectric properties. We managed to protonate this phase (leading to HST) and to functionalize it by various amines and polyamines, with reaction times much shorter than using classical conditions. This approach allowed us to functionalize HST by bulkier and more complex amines. This strategy has further been extended to the grafting of alcohols and polyols. We have also established a postsynthesis modification strategy, in order to synthesize the desired molecule in situ, within the interlamellar space, using "click" chemistry and microwave activation. Finally, we managed to insert transition metal ions and complexes, which constitutes a promising step towards the synthesis of new multiferroic hybrid materials.
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Utilisation du triflate de fer(III) en glycosylation sous activation micro-ondes ou en flux continu / Glycosylation promoted by iron triflate(III) under microwave irradiation or in continuous flowXolin, Amandine 06 November 2015 (has links)
Les oligosaccharides et les glycoconjugués jouent des rôles essentiels dans de nombreux processus biologiques. Cependant, leur synthèse est plus complexe que la majorité des autres biomolécules. Le principal défi réside souvent dans la formation de la liaison glycosidique. Il est donc toujours nécessaire de développer des réactions de glycosylation efficaces et totalement stéréosélectives, utilisant de nouveaux donneurs et permettant d'accéder à des structures glycosidiques à différentes échelles. Ces réactions sont d'autant plus intéressantes si elles utilisent des promoteurs peu chers, peu toxiques et peu dangereux pour l'environnement, comme des sels de fer. Dans ce cadre, la formation directe de b-glycosides de la N-acétyl-D-glucosamine par catalyse au triflate de fer(III) a été étudiée. Cette glycosylation peut être réalisée sous irradiation micro-ondes ou en flux continu. Les conditions d'activation sous micro-ondes ont ensuite été étendues à la synthèse de motifs de N-glycanes complexes. Cette synthèse consiste en une étape de polyglycosylation au triflate de fer(III), combinée à une étape d'introduction d'un lien moléculaire, via une nouvelle glycosylation ou une réaction de la chimie click. Enfin, une a-mannosylation utilisant le triflate de fer(III) a été découverte et mise au point. Cette glycosylation, réalisée sous activation micro-ondes, est totalement stéréosélective, même en l'absence de groupement participant. / Oligosaccharides and glycoconjugates are involved in numerous biological events. However, their synthesis is generally more complex than for other biomolecules. The main challenge is often the generation of the glycosidic bond. For this reason, it is still important to develop efficient and stereoselective glycosylations, which afford glycosides in significant amounts using new donors. These reactions are even more attractive if the promoter used is cheap, non-toxic and environmentally friendly, like iron salts. In this context, the direct synthesis of b-glycosides of N-acetyl-D-glucosamine using catalytic iron triflate(III) has been developed. This glycosylation can be performed under microwave irradiation or in continuous flow. The microwave-assisted conditions were then extended to the synthesis of complex N-glycan mimics. This synthesis is based on a polyglycosylation reaction using an iron(III) triflate catalysis coupled to another glycosylation or a click reaction to introduce a functionalized linker. Finally, an a-mannosylation promoted by iron(III) triflate has been developed. This glycosylation, performed under microwave irradiation, is completely stereoselective, even without neighbouring group participation.
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