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81	An absorption refrigeration system using ionic liquid and hydrofluorocarbon working fluids Kim, Sarah Sungeun 22 May 2014 (has links) Efficient heat management in energy intensive applications such as server and data centers has become a national concern due to the magnitude of the energy consumed. In that matter, the absorption refrigeration system is an attractive solution because the abundant waste heat available in the data centers can be recycled to run the heat pump, which will bring about significant cooling cost savings. The use of absorption refrigeration has been limited due to the drawbacks related to the working fluids in commercially available equipment. Recently, ionic liquids (ILs) have been suggested as the absorbent in absorption heat pumps due to their tunable properties, negligible volatility and high thermal stability. The non-random-two-liquid-model was initially used to analyze the feasibility of the new IL based working fluid. Hydrofluorocarbons (HFCs) were paired with IL absorbents due to their good properties as refrigerants. The cooling-to-total-energy (CE) efficiency had a local maximum with respect to desorber temperature due to the solubility limit at lower temperatures and large heating requirements at higher temperatures. The waste heat recycling coefficient of performance (COP) continually increased with respect to desorber temperature and among the HFCs studied in this work, R134 gave the highest COP value, which is up to 40 times higher than that of typical vapor compression systems and 60 times higher than NH3/H2O and H2O/LiBr absorption refrigeration systems. A Redlich-Kwong equation of state (RK-EOS) was employed for accurate computation of mixture properties over a wide range of operating conditions. Analysis using the RK-EOS model showed that the CE trend in refrigerants followed the trend of solubility in the [bmim][PF6] IL. However, the trend in COP was different from that of CE as the operating pressure ranges became an important factor. Required pumping work of the working fluids has also been analyzed using a two phase pressure drop equation and the results show that the impact of viscous IL flow is insignificant compared to the total pumping work. The HFCs studied in this work have very similar structures. However, the extent of solubility and system efficiency in the same IL, [bmim][PF6], made a large difference. Most surprisingly, even when the refrigerant had the same chemical formula, the change in fluorine position in tetrafluoroethane showed significantly different system performance. The symmetrical tetrafluoroethane had superior CE and COP over the asymmetrical tetrafluoroethane most likely due to the higher probability to form hydrogen bonding with the absorbent. The computational results for various HFC/IL pairs show that in selecting the working fluid pairs, the refrigerant should have high overall solubility in the IL and a large gradient of solubility with respect to temperature. Also, refrigerants with small pressure ranges are preferred. In addition to the simulation study, a bench-top absorption refrigeration system was built and operated using IL based working fluids for the first time. The effect of cooling was observed by operating the test system. The experimental results were congruent with the predictions from the modeling work. In conclusion, an absorption refrigeration system based on the IL chemical compressor has been shown to be a promising solution in applications which need efficient cooling and generate abundant waste heat. Absorption refrigeration Ionic liquid Heat pump Heat pumps Absorption Waste heat Ionic solutions
82	Three applications of green chemistry in engineering: (1) silylamines as reversible ionic liquids for carbon dioxide capture; (2) carbon dioxide as protecting group in chemical syntheses; (3) mitigating the thermal degradation of polyvinyl chloride Switzer, Jackson Reeves 27 August 2014 (has links) Green chemistry principles served as a guide for three industrially-relevant projects. In the first project, silylamines were applied as reversible ionic liquids for carbon dioxide capture from post-combustion flue gas streams. The effect of silylamine structure was thoroughly researched to develop a comprehensive library of silylamines and an accompanying set of structure-property relationships. The proposed solvent systems have the potential to present significant energy savings, as design has focused on their use in a non-aqueous, solvent-free environment. The second project also dealt extensively with carbon dioxide capture, as a reversible, in-situ protecting group for amines. Three strategies for the reversible protection of amines using carbon dioxide were developed and evaluated. Further, a chemoselective reaction was performed using carbon dioxide to protect a reactive amine and consequentially direct reactivity elsewhere within the same molecule. The carbon dioxide-protection technology developed has significant impact in multi-step industrial syntheses, as reversible, in-situ protection with carbon dioxide could eliminate the need for separate protection and deprotection unit operations. Lastly, a study was performed on the thermal degradation and stabilization of PVC in the presence of both plasticizers and thermal stabilizers. The study combined both model compound experiments as well as work with bulk PVC blends to gain a holistic understanding of the processes that take place during the degradation and stabilization of PVC. A bio-based plasticizer was investigated as a replacement for petroleum-based phthalate plasticizers. Additionally, two novel thermal stabilizers for PVC were presented and evaluated. PVC Carbon dioxide Reversible ionic liquid Polyvinyl chloride Carbon capture Protecting groups Chemical syntheses Amine
83	Iron Fluoride-Based Positive Electrode Materials for Secondary Batteries Using Ionic Liquid Electrolytes / イオン液体電解質を用いた二次電池用フッ化鉄系正極材料 Zheng, Yayun 23 March 2022 (has links) 京都大学 / 新制・課程博士 / 博士(エネルギー科学) / 甲第24003号 / エネ博第439号 / 新制\|\|エネ\|\|83(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基礎科学専攻 / (主査)教授萩原理加, 教授佐川尚, 教授野平俊之 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM Secondary batteries Iron fluoride-based positive electrodes Ionic liquid electrolytes Elevated temperatures Phase evolution 501
84	Effects of Extrinsic and Intrinsic Proton Activity on The Mechanism of Oxygen Reduction in Ionic Liquids January 2011 (has links) abstract: Mechanisms for oxygen reduction are proposed for three distinct cases covering two ionic liquids of fundamentally different archetypes and almost thirty orders of magnitude of proton activity. Proton activity is treated both extrinsically by varying the concentration and intrinsically by selecting proton donors with a wide range of aqueous pKa values. The mechanism of oxygen reduction in ionic liquids is introduced by way of the protic ionic liquid (pIL) triethylammonium triflate (TEATf) which shares some similarities with aqueous acid solutions. Oxygen reduction in TEATf begins as the one electron rate limited step to form superoxide, O2-, which is then rapidly protonated by the pIL cation forming the perhydroxyl radical, HO2. The perhydroxyl radical is further reduced to peroxidate (HO2-) and hydrogen peroxide in proportions in accordance with their pKa. The reaction does not proceed beyond this point due to the adsorption of the conjugate base triethylammine interfering with the disproportionation of hydrogen peroxide. This work demonstrates that this mechanism is consistent across Pt, Au, Pd, and Ag electrodes. Two related sets of experiments were performed in the inherently aprotic ionic liquid 1-butyl-2,3-dimethylimidazolium triflate (C4dMImTf). The first involved the titration of acidic species of varying aqueous pKa into the IL while monitoring the extent of oxygen reduction as a function of pKa and potential on Pt and glassy carbon (GC) electrodes. These experiments confirmed the greater propensity of Pt to reduce oxygen by its immediate and abrupt transition from one electron reduction to four electron reduction, while oxygen reduction on GC gradually approaches four electron reduction as the potentials were driven more cathodic. The potential at which oxygen reduction initiates shows general agreement with the Nernst equation and the acid's tabulated aqueous pKa value, however at the extremely acidic end, a small deviation is observed. The second set of experiments in C4dMImTf solicited water as the proton donor for oxygen reduction in an approximation of the aqueous alkaline case. The water content was varied between extremely dry (<0.1 mol% H2O) and saturated (approximately 15.8 mol% H2O}). As the water content increased so too did the extent of oxygen reduction eventually approach two electrons on both Pt and GC. However, additional water led to a linear increase in the Tafel slope under enhanced mass transport conditions up to the point of 10 mol% water. This inhibition of oxygen adsorption is the result of the interaction between superoxide and water and more specifically is proposed to be associated with decomposition of theC4dMIm+ cation by hydroxide at the elevated temperatures required for the experiment. Oxygen reduction on both Pt and GC follows Nernstian behavior as the water content is increased. Separate mechanisms for oxygen reduction on Pt and GC are proposed based on the nature of the Nernstian response in these systems. / Dissertation/Thesis / Ph.D. Materials Science and Engineering 2011 Materials Science Chemistry Energy Fuel Cell Ionic Liquid Metal-Air Oxygen Reduction Proton Activity
85	Tuning the size and surface of InP nanocrystals by microwave-assisted ionic liquid etching Siramdas, Raghavender January 1900 (has links) Doctor of Philosophy / Department of Chemistry / Emily McLaurin / Semiconductors are materials whose conductivity is between metals and insulators. Semiconductor nanocrystals (NCs) have sizes in the range 2 to 10 nm. Because of their unique optical properties like tunable emission wavelength, narrow emission peak, and stability over dyes, they have potential applications in displays. Indium phosphide (InP) is considered a less toxic alternative to commercially used cadmium-based semiconductor NCs. Microwave-assisted (MA) methods using ionic liquids (ILs) afford fast reaction heating rates because of the good MW absorbing capacity of ILs. For tuning size and surface, which are some of the important problems associated with the InP NCs, new synthetic methods are reported herein. In MAIL etching HF generated in the microwave reaction etches the InP NCs surface. Pyridinium and imidazolium based ILs containing tetrafluoroborate (BF₄⁻) and hexafluorophosphate (PF₆⁻) ions yield luminescent NCs. In a silicon carbide (SiC) reaction vessel, which blocks most of the microwaves penetrating into the reaction, bigger NCs form than those from a Pyrex reaction vessel because of the higher reaction temperatures in the SiC vessel. By changing microwave set-power (SP), different reaction times can be achieved. Though a small degree of change in average NC diameter of the NCs is observed at different SPs and reaction temperatures, addition of dodecylamine (DDA) yields NCs with average sizes between 3.2 to 4.2 nm with a broad size distribution. At lower SPs smaller NCs form and at higher SPs bigger NCs form. NC luminescence can be tuned from green (545 nm) to red (630 nm) in the visible region with quantum yields as high as 30%. Rapid heating and InP precursor activation might be responsible for the larger change in NC size. The effect of DDA on NC size is also verified by microwave reactions in SiC vessels. ILs containing PF₆⁻ ions at 280 °C will modify the surface of the NCs so the NC dispersibility changes from non-polar (toluene) to polar (DMSO) as the amount of IL increases. This is due to ligand stripping, which is the removal of large palmitic ligands from the NC surface. These NCs have broad absorption features and emission peaks with QYs of up to 30%. Fourier transform infrared spectroscopy indicates the absence of palmitic acid ligands on the NC surface and zeta potential measurements indicate the presence of anions on the NC surface. From X-ray photoelectron spectroscopy and nuclear magnetic resonance spectroscopy, the inorganic ion PO₂F₂⁻ is identified on the NCs surface. InP nanocrystals Ionic liquid etching Microwave-assisted method Photoluminescence Size and surface
86	Engineering the Electrode-Electrolyte Interface: From Electrode Architecture to Zn Redox in Ionic Liquid Electrolytes January 2011 (has links) abstract: The electrode-electrolyte interface in electrochemical environments involves the understanding of complex processes relevant for all electrochemical applications. Some of these processes include electronic structure, charge storage, charge transfer, solvent dynamics and structure and surface adsorption. In order to engineer electrochemical systems, no matter the function, requires fundamental intuition of all the processes at the interface. The following work presents different systems in which the electrode-electrolyte interface is highly important. The first is a charge storage electrode utilizing percolation theory to develop an electrode architecture producing high capacities. This is followed by Zn deposition in an ionic liquid in which the deposition morphology is highly dependant on the charge transfer and surface adsorption at the interface. Electrode Architecture: A three-dimensional manganese oxide supercapacitor electrode architecture is synthesized by leveraging percolation theory to develop a hierarchically designed tri-continuous percolated network. The three percolated phases include a faradaically-active material, electrically conductive material and pore-former templated void space. The micropores create pathways for ionic conductivity, while the nanoscale electrically conducting phase provides both bulk conductivity and local electron transfer with the electrochemically active phase. Zn Electrodeposition: Zn redox in air and water stable N-ethyl-N-methylmorpholinium bis(trifluoromethanesulfonyl)imide, [C2nmm][NTf2] is presented. Under various conditions, characterization of overpotential, kinetics and diffusion of Zn species and morphological evolution as a function of overpotential and Zn concentration are analyzed. The surface stress evolution during Zn deposition is examined where grain size and texturing play significant rolls in compressive stress generation. Morphological repeatability in the ILs led to a novel study of purity in ionic liquids where it is found that surface adsorption of residual amine and chloride from the organic synthesis affect growth characteristics. The drivers of this work are to understand the processes occurring at the electrode-electrolyte interface and with that knowledge, engineer systems yielding optimal performance. With this in mind, the design of a bulk supercapacitor electrode architecture with excellent composite specific capacitances, as well as develop conditions producing ideal Zn deposition morphologies was completed. / Dissertation/Thesis / Ph.D. Materials Science and Engineering 2011 Engineering Energy Chemistry Electrochemistry Electrodeposition Ionic Liquid Purity Supercapacitor Surface Stress
87	SYNTHESES OF PEG/ALKYL-BASED IMIDAZOLIUM/PYRIDINIUM IONIC LIQUIDS AND APPLICATIONS ON H2S ABSORPTION& SYNTHESES OF POLYSULFONE BASED FUNCTIONALIZED IMIDAZOLIUM IONIC POLYMERS AND APPLICATIONS ON GAS SEPARATION Zhang, Chengda 01 December 2015 (has links) The synthesis method for PEG/alkyl-based imidazolium/pyridinium ionic liquids was studied. Four steps were used to fabricate the membranes: polymerization, chloromethylation, linkage of the polymers with the pendent groups and membrane cast. Permeabilities and CO2/N2 selectivity of two membranes were examined and each showed remarkable CO2/N2 selectivity. CO2 permeability of the [PSM-MIM][Cl] membrane is better than that of the [PSM-MEIM][Cl] membrane, which is due to the steric hindrance of the methoxyethyl group. The syntheses of PEG/alkyl-based imidazolium/pyridinium ionic liquids (IL) were studied. PEG-based ILs were demonstrated to have better H2S solubilities than the alkyl-based ILs. H2S solubilities of the imidazolium ILs and pyridinium ILs were compared. The anion effects on H2S solubilities have been investigated, while the temperature effects on H2S solubilities will need to be studied in the near future. gas absorption hydrogen sulfide solubility imidazolium ionic liquid ionic polymer membrane polyetheylene glycol
88	Récupération électrochimique en milieu liquide ionique de nanoparticules de platine contenues dans les électrodes de PEMFC / Electrochemical recovery of platinum nanoparticles from PEMFC's electrodes using ionic liquids Balva, Maxime 22 November 2017 (has links) Les nanoparticules de platine (Pt) représentent environ la moitié du coût de fabrication des piles à combustible à membrane échangeuses de protons (PEMFC), ce qui constitue un frein à leur commercialisation à grande échelle. La récupération du Pt contenu dans les piles usagées apparaît donc nécessaire. Les voies de traitement habituellement mises en œuvre pour le recyclage de catalyseurs à base de Pt sont des procédés pyro-hydrométallurgiques, générateurs d’émissions polluantes (CO2, NO2). Une voie de traitement électrochimique en milieu liquide ionique (LI), plus respectueuse de l'environnement, est proposée ici. Elle combine dans une seule cellule la lixiviation du Pt par dissolution anodique et sa récupération par électrodéposition, dans des conditions de température "douces", sans émission de gaz nocifs. L’étude de nombreux électrolytes a permis de sélectionner les mélanges BMIMTFSI + BMIMCl (bis(trifluorométhylsulfonyl) imidure + chlorure de 1-butyl-3-méthylimidazolium), en raison du caractère complexant des chlorures facilitant la lixiviation du Pt et de la bonne stabilité électrochimique du BMIMTFSI. L’anion TFSI-, peu coordonnant, permet de moduler le caractère complexant de l’électrolyte, paramètre clé du procédé influant sur la nature et la stabilité électrochimique du complexe de Pt formé par lixiviation. Au cours de ce travail, les conditions expérimentales permettant de lixivier et d’électrodéposer le Pt dans une cellule unitaire ont été définies et appliquées avec succès aux électrodes de PEMFC. L’électrolyte sélectionné, faiblement hygroscopique, permet la récupération du Pt en atmosphère ambiante / The platinum nanoparticles used as catalyst in Proton Exchange Membrane Fuel Cells (PEMFCs) represent around the half of the total price of the cell and is one of the limitations for their large scale commercialization. The treatment of spent PEMFC through the recovery of platinum catalyst is a major concern for their development. Usual recovery routes for platinum-containing catalysts are pyro-hydrometallurgical processes that generate pollutant emissions (CO2, NO2). An electrochemical recovery route by coupling electrochemical leaching and electrodeposition in ionic liquids (ILs) is proposed here, more environmentally friendly, performed in "soft" temperature conditions and without any gases emission. Studies of several electrolytes lead us to select BMIMTFSI + BMIMCl melts (bis(trifluorométhylsulfonyl) imidure + 1-butyl-3-méthylimidazolium chloride), due to the complexing ability of chloride against platinum and the good electrochemical stability of the RMIM+ cation. TFSI-, a weakly coordinate anion, allows us to modulate the complexing ability of the electrolyte, which is a key parameter affecting the nature and the electrochemical stability of the Pt complex formed after leaching. The optimal conditions of the leaching and electrodeposition steps have been determined during this work and successfully applied to PEMFC’s electrode. The selected electrolyte, which is weakly hygroscopic, allows the Pt recovery under ambient atmosphere Recyclage Liquide ionique Électrochimie Platinoïdes Recycling Ionic liquid Electrochemistry Platinum group metals 541.37 669.028 3
89	Magnesium Battery Electrolytes in Ionic Liquids January 2016 (has links) abstract: A lack of adequate energy storage technologies is arguably the greatest hindrance to a modern sustainable energy infrastructure. Chemical energy storage, in the form of batteries, is an obvious solution to the problem. Unfortunately, today’s state of the art battery technologies fail to meet the desired metrics for full scale electric grid and/or electric vehicle role out. Considerable effort from scientists and engineers has gone into the pursuit of battery chemistries theoretically capable of far outperforming leading technologies like Li-ion cells. For instance, an anode of the relatively abundant and cheap metal, magnesium, would boost the specific energy by over 4.6 times that of the current Li-ion anode (LiC6). The work presented here explores the compatibility of magnesium electrolytes in TFSI–-based ionic liquids with a Mg anode (TFSI = bis(trifluoromethylsulfonyl)imide). Correlations are made between the Mg2+ speciation conditions in bulk solutions (as determined via Raman spectroscopy) and the corresponding electrochemical behavior of the electrolytes. It was found that by creating specific chelating conditions, with an appropriate Mg salt, the desired electrochemical behavior could be obtained, i.e. reversible electrodeposition and dissolution. Removal of TFSI– contact ion pairs from the Mg2+ solvation shell was found to be essential for reversible electrodeposition. Ionic liquids with polyethylene glycol chains pendent from a parent pyrrolidinium cation were synthesized and used to create the necessary complexes with Mg2+, from Mg(BH4)2, so that reversible electrodeposition from a purely ionic liquid medium was achieved. The following document discusses findings from several electrochemical experiments on magnesium electrolytes in ionic liquids. Explanations for the failure of many of these systems to produce reversible Mg electrodeposition are provided. The key characteristics of ionic liquid systems that are capable of achieving reversible Mg electrodeposition are also given. / Dissertation/Thesis / Doctoral Dissertation Chemistry 2016 Chemistry Materials Science Physical chemistry Battery Bis(trifluoromethylsulfonyl)imide Electrochemistry Ionic Liquid Magnesium Raman Spectroscopy
90	Surfactants, Ionic liquids and Ionosilicas : functional ionic systems for supramolecular chemistry and elaboration of materials by design (ion exchange and vectorization) / Tensio-actifs, liquides ioniques et ionosilices : systèmes ioniques fonctionnels pour la chimie supramoléculaire et l’élaboration de matériaux par design (échange ionique et vectorisation) Bouchal, Roza 19 October 2016 (has links) Cette thèse s’inscrit dans le cadre de synthèses de matériaux innovants contenant des entités cationiques que sont le guanidinium et l’ammonium. Ces entités cationiques confèrent des propriétés intéressantes et fonctionnelles pour chacun des systèmes ioniques suivants : tensio-actifs, liquides ioniques et ionosilices. A cet effet, nous avons procédé à l’étude de deux familles de composés : les sels de guanidiniums et les ionosilices. Pour les sels de guanidiniums, nous avons étudié la formation et les propriétés d’auto-assemblage de tensio-actifs en utilisant différentes techniques de mesures (conductivité, tension de surface et calorimétrie). Ce remarquable synthon moléculaire qu’est le guanidinium a été aussi mis en avant comme liquide ionique pour l’extraction du méthyl orange, du diclofenac et du chromate. Quant aux ionosilices, bien qu’ils présentent aussi des propriétés intéressantes pour l’extraction ionique et l’adsorption de principes actifs, leur mise en forme reste cependant un paramètre clef pour cibler leur application. En effet, la mise en forme des ionosilices en nanoparticules permet l’extension des applications dans le domaine de la nanomedecine. Ainsi, durant cette thèse, des nanoparticules avec des sous-structures ioniques ammoniums sont synthétisées pour la première fois et utilisées comme nano-vecteur pour le relarguage d’un anti-inflammatoire (diclofenac). Par ailleurs, dans le but d’une extraction ionique en flux continu, des matériaux contenant des fonctions ioniques sous forme de monolithe ont été synthétisés à partir de précurseur ammonium par voie sol gel. Ainsi cette thèse nous a permis de trouver les éléments théoriques, illustratifs et expérimentaux des différentes facettes de la formation de matières à base d’unités cationiques aux propriétés remarquables que sont les sels de guanidiniums et les sels d’ammoniums. / This dissertation deals with innovative synthetic materials bearing cationic entities that are guanidinium and ammonium. These cationic entities give interesting and functional properties for each ionic system studied: surfactant, ionic liquid and ionosilica. For this purpose, we investigated two families groups composed of: guanidiniums salts and ionosilica. Regarding guanidiniums salts, we studied the formation and self-assembly behavior of guanidinium surfactants using different measurement techniques (conductivity, surface tension and calorimetry). This remarkable molecular synthon that represents guanidinium was also highlighted as an ionic liquid for the extraction of methyl orange, diclofenac and chromate. As for ionosilicas, although they also have advantageous properties for ion extraction and adsorption of the active ingredients, however their shaping remains a key parameter for targeting their application. In fact, the design of ionosilica material as nanoparticle allows applications extension in the field of nanomedicine. So during this thesis, nanoparticles containing ammonium substructures were synthesized for the first time and used as a nano-vector to deliver an anti-inflammatory drug (diclofenac). Furthermore, with the aim of ionic extraction in continuous flow, materials containing ionic functions as monolith were synthesized from ammonium precursor via sol gel route. This thesis allowed us to find the theoretical, experimental and illustrative elements of the different aspects of materials formation based on cationic entities with remarkable properties that are guanidiniums and ammonium salts. Surfactant Liquide ionique Ionosilice Guanidinium Ammonium Echange d'anion Surfactant Ionic liquid Ionosilica Guanidinium Ammonium Anion exchange

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