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Ion solvation in aqueous and non-aqueous solventsArslanargin, Ayse 12 October 2015 (has links)
No description available.
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Synthèse de carbonates organiques à partir de CO2 en présence de métallophthalocyanines : étude expérimentale / Organic carbonates synthesis from CO2 with metallophthalocyanines : experimental studyIonescu, Raluca Oana 08 April 2011 (has links)
Depuis les années 70, la synthèse de carbonates organiques a rencontré un grand intérêt dans diverses applications de l’industrie chimique. Parmi ces composés, le carbonate de diméthyle, qui est à la base de la fabrication de certains polycarbonates, est particulièrement intéressant. C’est un excellent solvant, et plus récemment, il s’est révélé être un additif potentiel pour les essences grâce à son contenu élevé en oxygène. Encore aujourd’hui, au niveau industriel, la synthèse de carbonate de diméthyle est basée sur l’utilisation de réactifs dangereux tels que le phosgène ou le monoxyde de carbone. Pour s’aligner sur les demandes de la chimie verte, une recherche assidue a été développée afin de trouver une voie de synthèse plus propre mais efficace qui pourrait être appliquée au niveau industriel. Parmi celles-ci, la voie la plus appropriée est la réaction directe du CO2 et du méthanol en présence d’un catalyseur capable d’activer le dioxyde de carbone. Dans ce travail, l’activité des complexes de type métallophthalocyanines a été testée en conditions atmosphériques et sous haute pression et haute température. Les méthodes de spectroscopie infrarouge, UV-visible etRMN ont été mise en oeuvre pour caractériser les intermédiaires réactionnels formés. Les travaux ont démontré que ces complexes métalliques possèdent une capacité d’activation du CO2 et du méthanol pour former le carbonate de diméthyle, tout en ayant une activité catalytique encore trop faible pour envisager de développer un procédé industriel. Ce type de complexes a cependant montré une activité satisfaisante pour la synthèse de carbonate de propylène à partir de CO2 et d’oxyde de propylène. / Since the 1970’s, the synthesis of organic carbonates has been of a strong interest in applications in the chemical industry as an intermediate in the synthesis of polycarbonates, as a solvent and more recently as a possible additive in gasoline due to its high oxygen content. Until now, industrial dimethyl carbonate synthesis has been based on the use of harmful reagents such as phosgene and carbon monoxide. To bring it into line with the requirements of green chemistry, research has been carried out to find a cleaner way of synthesis that could be also applied at an industrial scale. It was found that one of the most suitable chemical routes is the use of carbon dioxide and methanol in the presence of a catalyst that is able to activate the CO2 molecule. In this work, the activity of metallophthalocyanine complexes was tested under atmospheric, as well as high pressure and high temperature conditions. Infrared, UV-visible and RMN spectroscopy has been used to attempt to identify the reaction intermediates. In this work metallophthalocyanine complexes have been shown to activate methanol and CO2 molecules by forming dimethyl carbonate. However, the yields are too low to develop a chemical process at the industrial scale. Nevertheless, this type of complex has shown to be active in the synthesis of propylene carbonate from carbon dioxide and propylene oxide.
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Advanced Methods, Materials, and Devices for MicrofluidicsWhite, Celesta E. 26 November 2003 (has links)
Advanced Methods, Materials, and Devices for Microfluidics
Celesta E. White
217 Pages
Directed by Dr. Clifford L. Henderson
Microfluidics is a rapidly growing research area that has the potential to influence a variety of industries from clinical diagnostics to drug discovery. Unlike the microelectronics industry, where the current emphasis is on reducing the size of transistors, the field of microfluidics is focusing on making more complex systems of channels with more sophisticated fluid-handling capabilities, rather than reducing the size of the channels. While lab-on-a-chip devices have shown commercial success in a variety of biological applications such as electrophoretic separations and DNA sequencing, there has not been a significant amount of progress made in other potential impact areas for microfluidics such as clinical diagnostics, portable sensors, and microchemical reactors. These applications can benefit greatly from miniaturization, but advancement in these and many other areas has been limited by the inability or extreme difficulty in fabricating devices with complex fluidic networks interfaced with a variety of active and passive electrical and mechanical components.
Several techniques exist for the fabrication of microfluidic devices, but these methods have significant limitations, and alternative fabrication approaches are currently desperately needed. One such method that shows promise for its ability to integrate the desired high levels of functionality utilizes thermally sacrificial materials as place holders. An encapsulating overcoat material provides structural stability and becomes the microchannel walls when the sacrificial material is removed from the channel through thermal decomposition. Disadvantages of this method, however, include numerous processing steps required for sacrificial layer patterning and elevated temperatures needed for the decomposition of initial sacrificial materials. These limitations keep this method from becoming an economical alternative for microfluidic device fabrication.
The materials needed for this method to reach its full potential as a valid fabrication technology for m-TAS are not currently available, and it was a major focus of this work to develop and characterize new sacrificial materials, particularly photosensitive polycarbonate systems. In addition to the development of new sacrificial polymers, the framework for a working microfluidic device was developed to show that this concept will indeed provide significant advancements in the development of future generations of microfluidic systems. Finally, novel fabrication methods for microfluidics through combined imprinting and photopatterning of photosensitive sacrificial materials was demonstrated.
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Cyanide-catalyzed C-C bond formation: synthesis of novel compounds, materials and ligands for homogeneous catalysisReich, Blair Jesse Ellyn 25 April 2007 (has links)
Cyanide-catalyzed aldimine coupling was employed to synthesize compounds
with 1,2-ene-diamine and ñ-imine-amine structural motifs: 1,2,N,N'-
tetraphenyletheylene-1,2-diamine (13) and (+/-)-2,3-di-(2-hydroxyphenyl)-1,2-
dihydroquinoxaline (17), respectively. Single crystal X-ray diffraction provided solidstate
structures and density functional theory calculations were used to probe isomeric
preferences within this and the related hydroxy-ketone/ene-diol system. The enediamine
and imine-amine core structures were calculated to be essentially identical in
energy. However, additional effects-such as ÃÂ conjugation-in 13 render an enediamine
structure that is slightly more stable than the imine-amine tautomer (14). In
contrast, the intramolecular hydrogen bonding present in 17 significantly favors the
imine-amine isomer over the ene-diamine tautomer (18).
Aldimine coupling (AIC) is the nitrogen analogue of the benzoin condensation
and has been applied to dialdimines, providing the first examples of cyclizations effected
by cyanide-catalyzed AIC. Sodium cyanide promoted the facile, intramolecular
cyclization of several dialdimines in N,N-dimethylformamide, methanol, or
dichloromethane/water (phase-transfer conditions) yielding a variety of six-membered
heterocycles. Under aerobic conditions, an oxidative cyclization occurs to provide the
diimine heterocycle.
Cyanide-catalyzed aldimine coupling was employed as a new synthetic method
for oligomerization. Nine rigidly spaced dialdimines were oxidatively coupled under
aerobic conditions to yield conjugated oligoketimines and polyketimines with
unprecedented structure and molecular weight (DP = 2 - 23, ~700 -8200 g/mol). The ñ- diimine linkage was established based on IR spectroscopy, NMR spectroscopy, size
exclusion chromatography, and X-ray crystallographic characterization of the model
oxidized dimer of N-benzylidene-(p-phenoxy)-aniline. Cyclic voltammetry indicates ptype
electrical conductivity, suggesting they are promising candidates for plastic
electronic devices.
The cyanide-catalyzed benzoin condensation reaction of 4-substituted
benzaldehydes followed by oxidation to the diketone, and the Schiff Base condensation
of two equivalents of o-aminophenol provides 2,3-(4-X-phenyl)2-1,4-(2-
hydroxyphenyl)2-1,4-diazabutadiene. The ligand is given the moniker X-dabphol.
These ligands are readily metallated to form M-X-dabphol complexes. The copper
complexes catalytically fix CO2 with propylene oxide to yield propylene carbonate. DFT
studies along with a comparison with Hammet parameters help validate and elaborate on
the catalytic cycle and the catalytic results obtained. The nickel complex is competent
for olefin epoxidation. Synthesis, characterization, X-ray structure, DFT analysis, and
catalytic activity of the parent nickel dabphol complex are reported.
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Structural Determination of Copolymers from the Cross-catalyzed Reactions of Phenol-formaldehyde and Polymeric Methylenediphenyl DiisocyanateHaupt, Robert A. 07 May 2013 (has links)
This work reports the elucidation of the structure of a copolymer generated by the cross- catalyzed reactions of PF and pMDI prepolymers. The electronic behavior of phenolic monomers as perturbed by alkali metal hydroxides in an aqueous environment was studied with 1H and 13C NMR. Changes in electronic structure and thus reactivity were related to solvated ionic radius, solvent dielectric constant, and their effect on ion generated electric field strength. NMR chemical shifts were used to predict order of reactivity for phenolic model compounds with phenyl isocyanate with good success. As predicted, 2-HMP hydroxymethyl groups were more reactive than 4-HMP in forming urethane bonds under neutral conditions and 2-HMP hydroxymethyl groups were more reactive than 4-HMP in forming urethane bonds under alkaline conditions.
The structure of the reaction products of phenol, benzyl alcohol, 2-HMP, and 4-HMP with phenyl isocyanate were studied using 1H and 13C NMR under neutral organic and aqueous alkaline conditions. Reactions in THF-d8 under neutral conditions, without catalyst, were relatively slow, resulting in residual monomer and the precipitation of 1,3-diphenyl urea from the carbamic acid reaction. The reactions of phenol, 2-HMP, and 4-HMP in the presence of TEA catalyst favored the formation of phenyl urethanes (PU). Reactions with benzyl alcohol, 2-HMP, and 4-HMP in the presence of DBTL catalyst favored the formation of benzyl urethanes (BU). Reactions of 2-HMP and 4-HMP led to formation of benzylphenyldiurethane (BPDU). DBTL catalysts favored formation of BDPU strictly by a benzyl urethane pathway, while TEA favored its formation mostly via phenyl urethane, although some BU was also present. Under aqueous alkaline conditions, 2-HMP was more reactive than 4-HMP, exhibiting an enhanced reactivity that was attributed to intramolecular hydrogen bonding and a resulting resonance stabilization of the phenolic aromatic ring.
ATR-FTIR spectroscopic studies generated real time structural information for model compound reactions of the cross-catalyzed system, differentiating among reaction peaks generated by the carbamic acid reaction, PU and BU formation. ATR-FTIR also permitted monitoring of propylene carbonate hydrolysis and accelerated alkaline PF resole condensation. ATR-FTIR data also showed that the overall reaction stoichiometry between the PF and pMDI components drove copolymer formation. Benzyl urethane formation predominated under balanced stoichiometric conditions in the presence of ammonium hydroxide, while phenyl urethane formation was favored in its absence. Accelerated phenolic methylene bridge formation became more important when the PF component was in excess in the presence of sufficient accelerator. A high percentage of free isocyanate was present in solid copolymer formed at ambient temperature. The combination of ammonium hydroxide and tin (II) chloride synergistically enhanced the reactivity of the materials, reducing the residual isocyanate.
From 13C CP/MAS NMR of the copolymer, the presence of ammonium hydroxide and tin (II) chloride and the higher PF concentration resulted in substantial urethane formation. Ammonium hydroxide favored formation of benzyl urethane from the 2-hydroxymethyl groups, while phenyl urethane formed in its absence. The low alkalinity PF resole with ammonium hydroxide favored benzyl urethane formation. Comparison of these results with the 13C NMR model compound reactions with phenyl isocyanate under alkaline conditions confirmed high and low alkalinity should favor phenyl and benzyl urethane formation respectively. These cross catalyzed systems are tunable by formulation for type of co-polymer linkages, reactivity, and cost. / Ph. D.
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In Situ Probe Microscopic Studies on Graphite Electrodes for Lithium-ion Batteries / その場プローブ顕微鏡を用いたリチウムイオン電池用黒鉛負極に関する研究Hee-Youb, Song 23 September 2016 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第20000号 / 工博第4244号 / 新制||工||1657(附属図書館) / 33096 / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授 安部 武志, 教授 作花 哲夫, 教授 阿部 竜 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM
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Kapalné elektrolyty pro lithno-iontové akumulátory / Liquid electrolytes for lithium-ion accumulatorsŠtichová, Zuzana January 2011 (has links)
The aim of this master´s thesis was the measurement of electrical conductivity and dynamic viscosity of the electrolytes. Based on these measurements to verify Walden theorem between measured variables. Electrolytes were used on sulfolane base in combination with propylene carbonate and salt. The thesis also deals with the measuring method of dielectric properties of electrical and optical method with a refractometer. The freezing point of combination of sulfolan and propylene carbonate were determined by cryoscopy.
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<i>In-situ</i> scanning tunneling microscopy studies of the SEI formation on graphite anodes in propylene carbonateDehiwala Liyanage, Chamathka H. January 2019 (has links)
No description available.
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Spectroscopy-Informed Design Rules for K-ion BatteriesElls, Andrew Williams January 2024 (has links)
While Li-ion batteries (LIBs) are the prevailing electrochemical energy storage technology, development of batteries using earth abundant alkali metals (e.g., Na and K) is necessary to alleviate LIB supply chain concerns. K-ion batteries (KIBs) offer a compelling advantage over Na via their compatibility with commercialized graphite anodes, and therefore may be more readily adopted within existing battery production lines. K-ions present some inherent advantages as well, such as rapid diffusion and low energy barriers to desolvation in the battery electrolyte that may enable fast charging. Presently, research on KIBs is in early stages and it is unclear if the same battery design principles produced by decades of study on LIBs apply to KIBs. Here, I examine structure-performance relationships in KIB anodes and electrolytes to propose broad design rules.
In the first chapter, I summarize the motivations and prominent advancements in materials used for KIBs, providing commentary on the direction of the field. I begin by summarizing present concerns over materials criticality facing LIBs and how KIBs address these concerns but do not necessarily achieve lower costs. I continue with a summary of popular materials choices for KIB anodes, cathodes, and electrolytes. I place particular emphasis on the discovery and development of graphite anodes and the advantages of using a weak Lewis acid such as K-ions in batteries. Finally, I discuss the challenges presented by using highly reactive K metal anodes in research.
In the second chapter, I examine the mechanisms of potassiation/depotassiation of two high-capacity tin phosphide anodes, Sn₄P₃ and SnP₃, and discuss possible failure modes. Ex situ 31P and 119Sn solid-state nuclear magnetic resonance (NMR) analyses reveal that both Sn₄P₃ and SnP₃ exhibit phase separation of elemental P and the formation of KSnP-type environments (which are predicted to be stable based on DFT calculations) during potassiation, while only Sn₄P₃ produces metallic Sn as a byproduct. In both anode materials, K reacts with elemental P to form K-rich compounds containing isolated P sites that resemble K₃P, but K does not alloy with Sn during potassiation of Sn₄P₃. During charge, K is only fully removed from the K3P-type structures, suggesting that the formation of ternary regions in the anode and phase separation contribute to capacity loss upon reaction of K with tin phosphides.
The third chapter addresses the use of fluorinated electrolyte additives in KIBs. Fluoroethylene carbonate (FEC) is a well-known additive used in Li-ion electrolytes, because the products of its sacrificial decomposition aid in forming a stable solid electrolyte interphase (SEI) on the anode surface. Here, we show that FEC addition to KIBs containing hard carbon anodes results in a dramatic decrease in capacity and cell failure. Using a combination of 19F solid-state NMR spectroscopy, X-ray photoelectron spectroscopy (XPS), and electrochemical impedance spectroscopy (EIS), we show that FEC decomposes during galvanostatic cycling to form insoluble KF and K₂CO₃ on the anode surface, which correlates with increased interfacial resistance in the cell. Our results strongly suggest KIB performance is sensitive to accumulation of an inorganic SEI, likely due to poor K transport in these compounds.
The fourth chapter presents a nonflammable electrolyte mixture for use in KIBs. In this report, we show that a low-concentration (1 M) KPF6 electrolyte combining ethylene carbonate
(EC), propylene carbonate (PC), and triethyl phosphate (TEP) is nonflammable, retains high ionic conductivity, and is compatible with graphite. Notably, we then show that this electrolyte is only usable in KIBs; the analogous Li electrolyte fails immediately due to the incompatibility of Li, PC, and graphite. We continue the study by characterizing the impact of TEP on the graphite interphase using a combination of EIS, XPS, and 1D and 2D NMR spectroscopy. We show that, compared to using EC/PC alone, the addition of TEP reduces resistance of the SEI layer, lessens reductive decomposition of carbonates to soluble organic species, and produces inorganic phosphate salts (that we posit contribute to passivation in lieu of fluorination in the SEI).
The fifth chapter concludes by summarizing the design strategies learned in each of the preceding three chapters and makes recommendations for future studies. The proposed research emphasizes the need for fundamental studies on materials properties in KIBs, contradicting the current push towards optimizing capacity and longevity of KIBs to prove their relevance. Doing so will not only inform how to design high-performance batteries, but potentially uncover distinct advantages of KIBs that complement existing LIB technologies.
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Compréhension du phénomène d’adhésion d’un gel polymère réalisé par extrusion sur substrat aluminium : application au contact électrode-collecteur d’une supercapacité / Study of the adhesion of a polymer gel produced by extrusion on an aluminium substrate : application for the collector-electrode contact of a supercapacitorAkkoyun, Meral 13 November 2012 (has links)
L’objectif de ce travail est d'envisager les modifications de formulation ou de procédé dans la technologie de geltrusion développée par Batscap pour augmenter la fiabilité des supercondensateurs en limitant l'autodécharge. La technologie repose sur l’extrusion simultanée de polymères (PVDF, PVDF-HFP), d’un solvant (PC) et de charges (CA, NC). Le mélange réalisé en extrusion bivis est ensuite filmé et laminé sur le collecteur en aluminium. Dès lors, il a été fondamental de chercher à comprendre les interactions entre les différents composants de l’électrode, avec l’étude de la miscibilité du système ternaire polymère/polymère/solvant puis l’étude de l’adsorption du solvant sur les charges. Cette démarche a permis une meilleure compréhension des phénomènes impliqués en passant par une caractérisation approfondie du complexe, dans sa formulation actuelle aux différentes étapes du procédé. Ensuite, des modifications de formulations ont été envisagées. En particulier, l'effet de la structure et de la masse molaire des polymères sur l’adhésion a été étudié. Dans tous les cas, il a été envisagé de tester les possibilités offertes par l'utilisation d'un solvant différent (DMSO). Ce dernier étant un meilleur solvant du PVDF est plus facile à éliminer que le PC. Enfin, à partir des données rhéologiques du mélange, une modélisation mécanique, en utilisant le modèle de Maxwell à plusieurs temps de relaxation, a été menée dans l'opération de laminage du mélange en prenant en compte un comportement viscoélastique du gel. Toutes ces études ont permis de conclure sur les modifications pertinentes de la formulation ainsi que des conditions du procédé / The objective of this work is to consider changes in formulation or process of the geltrusion technology developed by Batscap to increase the reliability of supercapacitors by limiting self-discharge. The technology is based on the simultaneous extrusion of polymers (PVDF, PVDF-HFP), solvent (propylene carbonate) and fillers (activated carbon, carbon black). The mixture carried out in a twin-screw extrusion is then filmed and laminated on the aluminium collector. Therefore, it was important to understand the interactions between the different components of the electrode, and especially to study the miscibility of the ternary system polymer/polymer/solvent and also the adsorption of solvent on fillers. This approach has allowed a better understanding of the phenomena involved through a characterization of the complex, in its current form at different stages of the process. Then, changes in formulations were considered. In particular, the effect of the structure and molecular weight of the polymers on adhesion was studied. In all cases, it was envisaged to test the possibilities offered by the use of a different solvent (dimethyl sulfoxide). The latter being a better solvent for the PVDF, is also easier to remove than propylene carbonate. Finally, from the rheological data of the mixture, a mechanical modeling, using the multimodal Maxwell model, was conducted in the lamination step taking into account of the viscoelastic behavior of the gel. All these studies allow us to conclude on the relevant changes in the formulation and process conditions
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