Global ETD Search

1	Synthesis and Characterization of Deep Eutectic Solvents (DES) with Multifunctional Building Blocks Lo, Yi-Ting 06 September 2019 (has links) No description available. Polymer Chemistry Polymers deep eutectic solvent
2	Deep Eutectic Solvents and Visible-Light Photocatalysis: Pathways to Greener Chemistry Burlingham, Sarah-Jayne 10 June 2024 (has links) This doctoral thesis is focused on applying visible light photocatalysis and deep eutectic solvents in organic transformations and combining the two to develop sustainable procedures. Chapter 1 deals with using visible-light photocatalysis to synthesize olefins via decarboxylative alkenylation from readily available carboxylic acids and vinyl sulfones. The developed protocol employs a metal-free, eco-friendly photocatalyst using a vitamin B2-derived species, achieving alkenes in a highly diastereoselective manner. Further transformations of the obtained compound were carried out while also analysing the reaction mechanism through an array of theoretical calculations and experimental procedures. Chapter 2 consists of the elaboration of a sustainable methodology for the aerobic photooxidation of xanthenes, thioxanthene and 9,10-dihydroacridines, employing a recyclable eutectic mixture as solvent and riboflavin tetraacetate as photocatalyst. This methodology's sustainability was further demonstrated by calculating a series of green metrics. Chapter 3 deals with synthesizing and characterizing novel chiral deep eutectic solvents and their application in asymmetric organocatalysis as combined solvent/organocatalyst. Thus, chiral ammonium salts were prepared and combined with other compounds, forming eutectic mixtures characterized by different procedures and later employed in the enantioselective addition of cyclohexanone to trans-β-nitrostyrene. Photocatalysis Deep eutectic solvents Green chemistry Organocatalysis
3	Deep Eutectic Solvents: À la Carte Solvents for Cross-Coupling Reactions Marset, Xavier 18 June 2019 (has links) En la presente memoria se describe el uso de líquidos eutécticos sostenibles (DESs en inglés) como medios de reacción, empleando diferentes catalizadores metálicos para llevar a cabo la síntesis de compuestos orgánicos de interés en química orgánica. En el Primer Capítulo se detalla el uso de un catalizador heterogéneo de cobre soportado sobre magnetita en el acoplamiento cruzado deshidrogenante de tetrahidroisoquinolinas en mezclas eutécticas. En el Segundo Capítulo se pormenoriza sobre la síntesis de un complejo tipo pinza de paladio y su empleo en la reacción de acoplamiento cruzado de Hiyama, tanto en mezclas eutécticas como en glicerol, como medios sostenibles de reacción. Asimismo, y con el fin de mejorar la compatibilidad de los catalizadores de paladio en estos líquidos eutécticos, se detalla el diseño y la síntesis de fosfinas catiónicas, las cuales han probado su efectividad como ligandos de paladio en reacciones típicas de acoplamiento cruzado (Suzuki, Heck y Sonogashira) en diferentes mezclas eutécticas. Finalmente, en el Tercer Capítulo se describen reacciones multicomponente de acoplamiento cruzado para la formación de enlaces C-S. Por un lado, se ha desarrollado una metodología para la inserción de SO2 catalizada por paladio a partir de ácidos borónicos y metabisulfito de sodio. Por otro lado, una variante de la metodología anterior permitió la síntesis de sulfonamidas sustituyendo los ácidos borónicos por compuestos de triarilbismuto y nitrocompuestos bajo catálsis de cobre. En este último caso, una nueva mezcla eutéctica ha sido descrita y caracterizada, tanto físco-química como biológicamente. Deep Eutectic Solvents Química sostenible Reacciones de acoplamiento cruzado Química Orgánica
4	Deep Eutectic Solvents as Sustainable Media for Pharmaceutical Purposes Procopio, Debora 16 September 2024 (has links) This doctoral thesis explores the use of Deep Eutectic Solvents (DESs) as an environmentally friendly alternative to conventional solvents in common organic transformations and formulation processes within the pharmaceutical industry. For this purpose, the thesis has been divided into five distinct chapters: Chapter I details the development of a sustainable approach for the synthesis of amides, using Reactive Deep Eutectic Solvents (RDESs) that serve both as a reaction medium and as reagents. This innovative method aims to eliminate hazardous solvents, allowing efficient product recovery and avoiding the need for additional chromatographic purifications. The sustainability of the developed method was estimated through the assessment and comparison of sustainability metrics on a large scale compared to conventional industrial strategies. Chapter II delineates a pioneering use of a simple and commercially available ruthenium catalyst to carry out the photocatalytic amide synthesis in DES. Even in this case, the environmental impact of the new methodology has been assessed using green metrics. Chapter III presents an eco-sustainable method for the removal of the tert-butyl carbamate (Boc) group, widely used in organic chemistry for the protection of amine functionalities. The N-Boc deprotection procedure was carried out in the absence of organic solvent, using a DES based on choline chloride and p-toluenesulfonic acid, which acts both as a reaction medium and catalyst. This approach was tested for the deprotection of various N-Boc derivatives. Furthermore, the impact of the developed methodology was valuated using green metrics. Chapter IV aims to propose a green, "one-pot" synthesis in two stages of the Active Pharmaceutical Ingredient (API) Atenolol. Currently, Atenolol ranks among the top five best-selling drugs worldwide, belonging to a class of beta-blockers commonly used for treating angina, hypertension, and reducing the risk of mortality after a heart attack. The novel synthetic methodology for Atenolol involves a DES which acts both as reaction medium and catalyst, providing a sustainable and environmentally friendly alternative to conventional industrial synthetic routes. The environmental impact of this synthetic strategy has been assessed using sustainability metrics and compared with traditional procedures. Finally, Chapter V aims to delve into how DESs can be sustainably utilized as alternative solvents in the pharmaceutical sector due to their extraordinary ability to significantly enhance the solubilization and delivery of poorly water-soluble Active Pharmaceutical Ingredients (APIs) belonging to Biopharmaceutics Classification System (BCS) Classes II and IV. This exploration holds potential positive implications for the pharmaceutical, chemical, and other related industries. / This project has received funding from the University of Alicante (VIGROB-316FI), the Spanish Ministerio de Ciencia e Innovación (PID2021-127332NB-I00), and the Valencian Department of Innovation, Universities, Science, and Digital Society (APOSTD/2020/235 and AICO/2021/013). Deep eutectic solvents Green solvents Green synthesis Sustainability
5	Electrolytes pour supercondensateurs asymétriques à base de MnO2 / Electrolytes for asymmetrical MnO2 supercapacitors Boisset, Aurelien 15 July 2014 (has links) Cette thèse a pour but de caractériser le fonctionnement de supercondensateurs asymétriques composés de dioxyde de manganèse de structure birnessite et de carbone activé dans différents électrolytes. Les électrolytes aqueux neutres à base de sels inorganiques montrent les meilleures performances électrochimiques. La nature et la structure des cations et des anions du sel semblent impacter les performances électrochimiques et la stabilité de la structure du matériau d’oxyde de manganèse. Lors de cyclage en milieu aqueux avec de large de fenêtre de tension de fonctionnement appliquée, un mécanisme de dégradation du dispositif a été avancé tenant compte de la nature des anions ou des cations des sels utilisés. Quelques voies de modification du matériau MnO2, afin d’améliorer ces performances électrochimiques, ont été étudiés. Des électrolytes non aqueux originaux ont été également caractérisés et plus particulièrement, les solvants « Deep Eutectic » à base de N-méthylacétamide et de sels de Lithium. Ces derniers semblent prometteurs comme électrolytes pour des applications en température sur carbone activé ou matériaux d’insertion tels que le ferrophosphate de lithium. Cependant ils semblent non adaptés aux oxydes de manganèse, mais donnent de bons résultats en cyclage avec le carbone activé. / The aim of this thesis was to investigate the performances of asymmetric supercapacitors based on manganese dioxide (birnessite) and activated carbon electrode materials using various electrolytes. From this work, it appears that neutral aqueous electrolytes containing inorganic salts have the best electrochemical performances. Furthermore, the nature and the structure of both ions (cations and anions) in solution seem to impact strongly the electrochemical performances of the supercapacitors, as well as, the MnO2’s structure stability and affinity. In the case of aqueous-based electrolyte, a device degradation mechanism has been proposed as a function of salt ions structure and nature to further understand the supercapacitor’s life-cycling when a large potential window is applied. Some novel synthesis ways and/or modifications were investigated to further improve the electrochemical properties of MnO2 material. Additionaly, original non-aqueous electrolytes has been also formulated and then characterized, particularly the ‘Deep Eutectic’ Solvents, based on the N-methylacetamide mixed with a lithium salt. However, these electrolytes don’t have a good affinity with manganese oxide-based materials. Interestingly, these Deep Eutectic Solvents show good cycling results with activated carbon. In fact, these electrolytes seem to be promising for high temperature energy storage applications, especially using activated carbon or insertion electrode material like the lithium ferrophosphate. Supercondensateur Asymétrique Oxyde de manganèse Birnessite Cryptomélane Carbone activé Électrolyte Solvant « Deep Eutectic » Supercapacitor Asymmetric Manganese oxide Birnessite Cryptomelane Activated carbon Electrolyte Deep eutectic solvent
6	Electrodeposition and characterisation of nickel-niobium-based diffusion barrier metallisations for high temperature electronics interconnections Wang, Jing January 2016 (has links) The control of interfacial microstructural stability is of utmost importance to the reliability of liquid solder interconnects in high temperature electronic assemblies. This is primarily due to excessive intermetallic compounds (IMCs) that can form and continuously grow during high temperature operation, which practically renders conventional barrier metallisations inadequate. In this study, electrically conducting, NbOx containing Ni coatings were developed using electrodeposition. Their suitability as a solder diffusion barrier layer was assessed in terms of the electrical conductivity and barrier property. The present work explores a novel electrochemical route to produce Ni-NbOx composite coatings of good uniformity, compactness and purity, from non-aqueous glycol-based electrolytes consisting of NiCl2 and NbCl5 as metal precursors. The effects of cathodic current density and NaBH4 concentrations on the surface morphology, composition and thickness of the coatings were examined. A combined study of Scanning Transmission Electron Microscopy (STEM) and Electrochemical Quartz Crystal Microbalance (EQCM) was conducted to understand the fundamental aspects of this novel electrodeposition process. The composite coatings generally exhibited good electrical conductivity. The reaction behaviour between a liquid 52In-48Sn solder and Ni-NbOx, with Nb contents up to 6 at.%, were studied at 200°C. The results indicate that, Ni-NbOx with sufficient layer thickness and higher Nb content, offered longer service lifetime. Nb enrichment was generally observed at or close to the reaction front after high temperature storage, which suggests evident effectiveness of the enhanced diffusion barrier characteristics. 671.7
7	The electrodeposition of tin coatings from deep eutectic solvents and their subsequent whisker growth Stuttle, Christopher January 2014 (has links) Tin electrodeposits produced from aqueous electrolytes are frequently used within the electronics industry due to their high solderability and corrosion protection. One limitation to using these deposits is their spontaneous formation of long conductive filament whiskers. These whiskers grow post-electrodeposition and increase the risk of unwanted electrical shorts within electronic devices. In this thesis, tin electrodeposits produced from a proprietary bright acid Tinmac electrolyte, currently used in industry, were studied. Electrodeposits were produced using a range of current densities with and without agitation and were characterised with respect to crystallographic orientation, topography and surface finish. Moreover, the intermetallic compound (IMC) growth produced at the copper substrate-tin coating interface was assessed over a period of time as its growth is considered to be a significant driving force behind whisker formation. In addition, a technique for the electrochemical anodic oxidation of tin electrodeposits on copper substrates was developed. This technique was used throughout this project for the study of IMC growth from tin electrodeposits as it was able to effectively remove the tin whilst leaving the IMCs and substrate unaffected. Ionic liquids exhibit promising electrochemical characteristics for electrodeposition but are still not widely utilised in industry. Their ability to deposit tin coatings has been studied in the present investigation. Trials concentrated on process optimisation to produce uniform electrodeposits by varying current density, SnCl2.2H2O concentration, and electrolyte composition. These deposits were then characterised and compared to tin coatings of similar thickness produced from Tinmac with respect to topography, surface finish, crystallographic orientation, IMC growth, and whisker propensity. Electrodeposits produced from the ionic liquid electrolyte exhibited a different crystallographic texture, topography, and IMC growth compared to those produced from Tinmac. Moreover, the deposit produced from the ionic liquid featured increased whisker growth compared to those produced from Tinmac, but in a wider context, far less growth than conventional tin electrodeposits in the literature. In addition, by exploiting other electrochemical characteristics of ionic liquids, such as their large potential window, future work may be able to produce novel tin or tin alloy electrodeposits which may further reduce the whisker propensity of deposits produced in this investigation. 621.3
8	Functionalisation of cucurbit[n]uril and exploring deep eutectic solvents as a medium for supramolecular chemistry McCune, Jade Alexis January 2018 (has links) No description available.
9	Exploring Selectivity and Hysteresis : Kinetic Studies on a Potato Epoxide Hydrolase Lindberg, Diana January 2010 (has links) The kinetic mechanism of an α/β hydrolase fold epoxide hydrolase from potato, StEH1, has been studied with the aims of explaining the underlying causes for enantio- and regioselectivity, both being important for product purity. Further effort has been laid upon understanding the causes of a hysteretic behavior discovered in the measurements leading to Paper I. The enantioselectivity was investigated with substrates differing only in substituent size at one carbon of the oxirane ring structure. In catalysis with trans-stilbene oxide and styrene oxide, enantioselectivity is the result of differences in alkylation rates. In pre-steady state measurement with trans-2-methylstyrene oxide (2-MeSO), a rate-limiting step involving slow transitions, referred to as hysteresis, was discovered. With this substrate enantioselectivity is proposed to be a consequence of the catalytic rate of (1R,2R)-enantiomer being more influenced by the hysteretic behavior than was the rate of the other enantiomer. In steady-state measurements with (1R,2R)-2-MeSO, at different temperatures and pH, hysteretic cooperativity was displayed. It can be concluded that this behavior is dependent on the relationship between kcat and the rate of transition between two Michaelis complexes. From the differences in pH dependence of kcat/KM in formation of the two diols resulting from low regioselectivity in catalysis of (1R,2R)-2-MeSO, it is suggested that hysteresis is a result of the substrates placed in different conformational modes within the active site cavity. Regioselectivity is proposed to be the result of specific interactions between the catalytically important Tyr and the substrate, with a link between KM-values and degree of regioselectivity. Furthermore, the hysteretic kinetic model proposed can explain hysteresis, cooperativity and regioselectivity resulting from StEH1 catalyzed hydrolysis of (1R,2R)-2-MeSO. Biochemistry Biokemi
10	Electrodeposition of reactive metals and alloys from non-aqueous electrolytes and their applications / 非水系電解浴を用いる活性金属および合金の電析とその応用 Higashino, Shota 23 September 2020 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第22798号 / エネ博第412号 / 新制\|\|エネ\|\|79(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー応用科学専攻 / (主査)教授平藤哲司, 教授土井俊哉, 教授馬渕守 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM electrodeposition reactive metal non-aqueous electrolyte ionic liquid deep eutectic solvent 501

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