Bibliographies thématiques / Ionic Liquid interaction

Littérature scientifique sur le sujet « Ionic Liquid interaction »

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Publié le 18 mai 2024

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Articles de revues sur le sujet "Ionic Liquid interaction"

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Jorda-Faus, Pepe, Enrique Herrero et Rosa Arán-Ais. « Study of M(hkl)| Ionic Liquid Interfaces in Well-Defined Surroundings ». ECS Meeting Abstracts MA2022-01, no 55 (7 juillet 2022) : 2325. http://dx.doi.org/10.1149/ma2022-01552325mtgabs.

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Ionic liquids have very interesting properties for their use in electrochemistry: they have a wide potential window of stability, high electrical conductivity and can replace water in processes in which water is not an appropriate solvent. Because of that, the number of studies has increased exponentially in recent years. When used in electrocatalytic applications, the structure of the interphase alters the electrocatalytic response of the electrode. For this reason, the characterization of the interphase, and especially the nature of the interaction of the ionic liquid with the metal surface becomes an essential element in the study of these reactions. In most cases, the interaction between the ions and the metal surface is specific, that is, a chemical interaction between the ionic liquid and the surface is established. Then, the interaction will depend on the nature of the ionic liquid and the electronic properties of the surface. This implies that this interaction is structure-sensitive. Practical surfaces are composed of several types of sites, which have different geometries and different interactions with the ionic liquid so that the observed responses are difficult to analyze. The best way to simplify the problem is the use of single crystal electrodes, which have a well-defined surface atomic structure, which allows establishing correlations between surface structure and observed behavior. One of the main disadvantages of using ionic liquids in electrochemistry is their high viscosity, which hinders the diffusion of the electroactive species towards the electrode surface and thus, lowering the reaction rates. This has triggered the study of low viscosity ionic liquids, which are usually those based on the imidazole cation ([Im+]) and/or the bis(trifluoromethyl)sulfonyl imide anion ([NTf2-]). It should be noted that the ionic liquid-electrode interphase is more complex than one in an aqueous medium. Ionic liquids have a higher electrostatic charge and interaction between the ions, which complicates the application of simple double-layer models. It is also important to highlight that, being organic compounds, they are prone to have impurities related to their synthesis processes, which can affect their physicochemical properties. In electrochemical systems in which ionic liquids are used, these liquids play the role of both solvent and electrolyte, which complicates the study of interactions, since the concentration of the ions is very high. To simplify the problem and to have a system with which to compare, ionic liquids can be dissolved in water. In this case, the concentration of the ions is reduced, facilitating their study. In addition, models are available to study and analyze their behavior. Thus, it is possible to analyze the effect of the concentration of the ionic liquid on its behavior and to extrapolate it to concentrations in which water is absent. In addition, due to the high hygroscopicity of ionic liquids, it is very difficult to completely eliminate water in practical applications. Furthermore, the presence of ionic liquids in aqueous solutions has been shown to catalyze some electrochemical reactions where small amounts of these have been shown to significantly increase the reaction rate. Thus, the aim of this work is to characterize the electrochemical behavior in water of the different ions that form the ionic liquids based in [Im]+ cation and ([NTf2]-) anion separately on platinum single crystal electrodes. To determine the role of each ion, different salts composed with at least one of the ions of interest ([Im]+ or ([NTf2]-)) will be used. The interactions of the ions and the electrode will be characterized using electrochemical and spectroelectrochemical techniques.
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Jesus, Ana R., Luís R. Raposo, Mário R. C. Soromenho, Daniela A. S. Agostinho, José M. S. S. Esperança, Pedro V. Baptista, Alexandra R. Fernandes et Patrícia M. Reis. « New Non-Toxic N-alkyl Cholinium-Based Ionic Liquids as Excipients to Improve the Solubility of Poorly Water-Soluble Drugs ». Symmetry 13, no 11 (31 octobre 2021) : 2053. http://dx.doi.org/10.3390/sym13112053.

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In this work, we prepared new biocompatible N-alkyl cholinium-based ionic liquids to be used as cosolvents to improve the solubility of poorly water-soluble drugs, namely, sodium diclofenac and paracetamol. In this set of ionic liquids, we intend to understand the effect of increasing the asymmetry of the ionic liquid cation/anion by growing the length of one of the alkyl chains attached to the nitrogen center/sulfonate center on the dissolution capacity of the ionic liquid. The addition of these new ionic liquids to water increased the dissolution capacity of the drugs up to four-times that in water, and improved the pharmacodynamic properties of these drugs, especially the case of sodium diclofenac. The intermolecular interactions between the drugs and ionic liquids were investigated by NMR. Two-dimensional 1H/1H nuclear overhauser effect spectroscopy (NOESY) revealed an interaction between sodium diclofenac and the alaninate anion from the [C2Ch]2[SucAla]. In the case of paracetamol and [C4Ch][C2SO3], it was possible to observe two intermolecular interactions between the hydroxyl group of paracetamol and two protons from the cation [C4Ch]+. Interestingly, the ionic liquid bearing a succinyl-DL-alaninate anion, [SucAla]2−, and a N-ethyl cholinium cation, [C2Ch]+, which presented the highest ability to dissolve sodium diclofenac, showed no cytotoxicity up to 500 mM. Therefore, this ionic liquid is a potential candidate for drug delivery applications.
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Xu, Qiang, Wei Jiang, Jianbai Xiao et Xionghui Wei. « Absorption of Sulfur Dioxide by Tetraglyme–Sodium Salt Ionic Liquid ». Molecules 24, no 3 (26 janvier 2019) : 436. http://dx.doi.org/10.3390/molecules24030436.

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A series of tetraglyme–sodium salt ionic liquids have been prepared and found to be promising solvents to absorb SO2. The experiments here show that [Na–tetraglyme][SCN] ionic liquid has excellent thermal stability and a 30% increase in SO2 absorption capacity compared to other sodium salt ionic liquids and the previously studied lithium salt ionic liquids in terms of molar absorption capacity. The interaction between SO2 and the ionic liquid was concluded to be physical absorption by IR and NMR.
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Heinze, M. T., J. C. Zill, J. Matysik, W. D. Einicke, R. Gläser et A. Stark. « Solid–ionic liquid interfaces : pore filling revisited ». Phys. Chem. Chem. Phys. 16, no 44 (2014) : 24359–72. http://dx.doi.org/10.1039/c4cp02749c.

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Zhou, Yafei, Junfeng Zhan, Xiang Gao, Cao Li, Konstantin Chingin et Zhanggao Le. « The cation−anion interaction in ionic liquids studied by extractive electrospray ionization mass spectrometry ». Canadian Journal of Chemistry 92, no 7 (juillet 2014) : 611–15. http://dx.doi.org/10.1139/cjc-2014-0023.

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Ionic liquids, known as green solvents, are of sustainable interest in modern chemistry, industry, and many other fields. Here, extractive electrospray ionization has been applied to transfer various room temperature ionic liquids into the gas phase for mass spectrometry analysis. Generated mass spectra display free cations (C+), anions (A–), and small salt clusters, such as C2A+ and CA2–, from strongly diluted ionic liquid samples (<10−8 mol/L) with high sensitivity and tolerance to chemical contamination. The eight ionic liquids based on the 1-butyl-3-methylimidazolium cation with different anions (OH–, HSO4–, Cl–, BF4–, AlCl4–, NO3–, Ac–, and PF6–) are investigated in the present work. Interestingly, the 1-butyl-3-methylimidazolium cation signal intensity is inversely correlated with the hydrogen bonding strength between the anion and cation. Our study indicates that the direct extractive electrospray ionization mass spectrometry analysis is a convenient method to screen ionic liquid libraries with regard to chemical composition, physicochemical properties, and supramolecular organization of ionic liquids.
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Putz, Mihai V., Ana-Maria Lacrama et Vasile Ostafe. « Spectral SAR Ecotoxicology of Ionic Liquids : TheDaphnia magnaCase ». Research Letters in Ecology 2007 (2007) : 1–5. http://dx.doi.org/10.1155/2007/12813.

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Aiming to provide a unified theory of ionic liquids ecotoxicity, the recent spectral structure activity relationship (S-SAR) algorithm is employed for testing the two additive models of anionic-cationic interaction containing ionic liquid activity: the causal and the endpoint,|0+〉and|1+〉models, respectively. As a working system, theDaphnia magnaecotoxicity was characterized through the formulated and applied spectral chemical-ecobiological interaction principles. Specific anionic-cationic-ionic-liquid rules of interaction along the developed mechanistic hypersurface map of the main ecotoxicity paths together with the so-called resonance limitation of the standard statistical correlation analysis were revealed.
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Alguacil, Francisco J., et Félix A. Lopez. « Insight into the Liquid–Liquid Extraction System AuCl4−/HCl/A327H+Cl− Ionic Liquid/Toluene ». Processes 9, no 4 (30 mars 2021) : 608. http://dx.doi.org/10.3390/pr9040608.

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The ionic liquid A327H+Cl− is generated by reaction of the tertiary amine A327 (industrial mixture of tri-octyl and tri-decyl amines) and hydrochloric acid solutions. In this study, the extraction of Au(III) by A327H+Cl− ionic liquid under various variables, including metal and ionic liquid concentrations, was investigated. Results indicate that A327H+AuCl4− is formed by an exothermic (ΔH° = −3 kJ/mol) reaction in the organic solution. Aqueous ionic strength influences the formation constant values, and the specific interaction theory (SIT) was used to estimate the interaction coefficient between AuCl4− and H+. Gold (III) was stripped using thiocyanate media, and from the strip solutions, gold was precipitated as gold nanoparticles.
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Patil, Amol Baliram, et Bhalchandra Mahadeo Bhanage. « Modern ab initio valence bond theory calculations reveal charge shift bonding in protic ionic liquids ». Physical Chemistry Chemical Physics 18, no 23 (2016) : 15783–90. http://dx.doi.org/10.1039/c6cp02819e.

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Verevkin, Sergey P., Dzmitry H. Zaitsau et Ralf Ludwig. « Molecular Liquids versus Ionic Liquids : The Interplay between Inter-Molecular and Intra-Molecular Hydrogen Bonding as Seen by Vaporisation Thermodynamics ». Molecules 28, no 2 (5 janvier 2023) : 539. http://dx.doi.org/10.3390/molecules28020539.

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In this study, we determined the enthalpies of vaporisation for a suitable set of molecular and ionic liquids using modern techniques for vapour pressure measurements, such as the quartz crystal microbalance, thermogravimetric analysis (TGA), and gas chromatographic methods. This enabled us to measure reasonable vapour pressures, avoiding the problem of the decomposition of the ionic liquids at high temperatures. The enthalpies of vaporisation could be further analysed by applying the well-known “group contribution” methods for molecular liquids and the “centerpiece” method for ionic liquids. This combined approach allowed for the dissection of the enthalpies of vaporisation into different types of molecular interaction, including hydrogen bonding and the dispersion interaction in the liquid phase, without knowing the existing species in both the liquid and gas phases.
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Zeindlhofer, Veronika, et Christian Schröder. « Computational solvation analysis of biomolecules in aqueous ionic liquid mixtures ». Biophysical Reviews 10, no 3 (23 avril 2018) : 825–40. http://dx.doi.org/10.1007/s12551-018-0416-5.

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Abstract Based on their tunable properties, ionic liquids attracted significant interest to replace conventional, organic solvents in biomolecular applications. Following a Gartner cycle, the expectations on this new class of solvents dropped after the initial hype due to the high viscosity, hydrolysis, and toxicity problems as well as their high cost. Since not all possible combinations of cations and anions can be tested experimentally, fundamental knowledge on the interaction of the ionic liquid ions with water and with biomolecules is mandatory to optimize the solvation behavior, the biodegradability, and the costs of the ionic liquid. Here, we report on current computational approaches to characterize the impact of the ionic liquid ions on the structure and dynamics of the biomolecule and its solvation layer to explore the full potential of ionic liquids.
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Thèses sur le sujet "Ionic Liquid interaction"

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Biplab, Rajbanshi. « Investigation of host- guest inclusion complexation of some biologically potent molecules and solvent consequences of some food preservations with the manifestation of synthesis, characterization and innovative applications ». Thesis, University of North Bengal, 2020. http://ir.nbu.ac.in/handle/123456789/3963.

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Hossain, Mohammad Zahid. « A new lattice fluid equation of state for associated CO₂ + polymer and CO₂ + ionic liquid systems ». Diss., Georgia Institute of Technology, 2014. http://hdl.handle.net/1853/53475.

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The phase behavior of CO2 + polymer systems is of interest in polymer synthesis, flue and natural gas processing, polymer foam and nanoparticle processing, and drug delivery. Theoretical and experimental evidence suggests that CO2 is able to interact with electron donating functional groups in polymers to form weak Lewis acid – base or EDA (Electron Donor Acceptor) complexes. These complexes can have a significant effect on the phase behavior of associated CO2 + polymer systems. In spite of this, however, the phase equilibria of only a few associated CO2 + polymer systems have been measured. Some success in modeling the phase behavior of polymer solutions has been achieved by various versions of the Statistical Association Fluid Theory (SAFT), as well as by several Lattice Models. However, many of these models incorporate two to four adjustable parameters that often depend on temperature (T), pressure (P), and/or molecular weight (MW). As a result, a large amount of experimental data is required to apply these models. The goal of the present work was therefore to develop a new thermodynamic model for associating systems that would include no more than two temperature-independent adjustable parameters. The new model presented in this work is based on the Guggenheim-Huggins-Miller lattice and includes complex formation in the development of the partition function. The EOS obtained from the resulting partition function includes two mixture parameters – the enthalpy of association or complex formation and a reference value of the equilibrium constant for complex formation . Most importantly, can be obtained from in situ Attenuated Total Reflection Fourier Transform Infrared (ATR – FTIR) measurements. This work therefore demonstrates the use of ATR – FTIR spectra to obtain molecular level information regarding the interaction of CO2 and electron donating functional groups in polymers. Unlike other studies, this work uses the bending vibration of CO2 to estimate the enthalpies of association ( ) of CO2 + polymer systems. Values of were directly incorporated in the new model and were found to lie between -7 and -12 kJ/mol for the systems investigated in this work. They increased (i.e. became more negative) in the order: CO2 + PS-co-PMMA < CO2 + PMMA
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Wang, Yong-Lei. « Electrostatic Interactions in Coarse-Grained Simulations : Implementations and Applications ». Doctoral thesis, Stockholms universitet, Institutionen för material- och miljökemi (MMK), 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:su:diva-92707.

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Electrostatic interactions between charged species play a prominent role in determining structures and states of physical system, leading to important technological and biological applications. In coarse-grained simulations, accurate description of electrostatic interactions is crucial in addressing physical phenomena at larger spatial and longer temporal scales. In this thesis, we implement ENUF method, an abbreviation for Ewald summation based on non-uniform fast Fourier transform technique, into dissipative particle dynamics (DPD) scheme. With determined suitable parameters, the computational complexity of ENUF-DPD method is approximately described as O(N logN). The ENUF-DPD method is further validated by investigating dependence of polyelectrolyte conformations on charge fraction of polyelectrolyte and counterion valency of added salts, and studying of specific binding structures of dendrimers on amphiphilic membranes. In coarse-grained simulations, electrostatic interactions are either explicitly calculated with suitable methods, or implicitly included in effective potentials. The effect of treatment fashion of electrostatic interactions on phase behavior of [BMIM][PF6] ionic liquid (IL) is systematically investigated. Our systematic analyses show that electrostatic interactions should be incorporated explicitly in development of effective potentials, as well as in coarse-grained simulations to improve reliability of simulation results. Detailed image of microscopic structures and orientations of [BMIM][PF6] at graphene and vacuum interfaces are investigated by using atomistic simulations. Imidazolium rings and alkyl side chains of [BMIM] lie preferentially flat on graphene surface. At IL-vacuum interface, ionic groups pack closely together to form polar domains, leaving alkyl side chains populated at interface and imparting hydrophobic character. With the increase of IL filmthickness, orientations of [BMIM] change gradually from dominant flat distributions along graphene surface to orientations where imidazolium rings are either parallel or perpendicular to IL-vacuum interface with tilted angles. The interfacial spatial ionic structural heterogeneity formed by ionic groups also contributes to heterogeneous dynamics in interfacial regions.
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França, João. « Solid-liquid interaction in ionanofluids. Experiments and molecular simulation ». Thesis, Université Clermont Auvergne‎ (2017-2020), 2017. http://www.theses.fr/2017CLFAC077.

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L'un des principaux domaines de recherche en chimie et en ingénierie chimique implique l'utilisation de liquides ioniques et de nanomatériaux comme alternatives à de nombreux produits chimiques et processus chimiques, comme ce dernier étant actuellement considérés comme non respectueux de l'environnement. Leur utilisation potentiel comme nouveaux fluides de transfert de chaleur et matériaux de stockage de chaleur, qui peuvent obéir à la plupart des principes de la chimie verte, nécessite l'étude expérimentale et théorique des mécanismes de transfert de chaleur dans les fluides complexes comme les ionanofluides. Le but de cette thèse était d'étudier les ionanofluides, qui consistent en la dispersion de nanomatériaux dans un liquide ionique.Le premier objectif de ce travail était de mesurer les propriétés thermophysiques des liquides ioniques et ionanofluides, à savoir la conductivité thermique, la viscosité, la densité et la capacité thermique dans une gamme de température comprise entre -10 et 150 ºC et à pression atmosphérique. Dans ce sens, les propriétés thermophysiques d'un ensemble considérable de liquides ioniques et d'ionanofluides ont été mesurées, avec un accent particulier sur la conductivité thermique des fluides. Les liquides ioniques étudiés étaient [C2mim][EtSO4], [C4mim][(CF3SO2)2N], [C2mim][N(CN)2], [C4mim][N(CN)2], [C4mpyr][N(CN)2], [C2mim][SCN], [C4mim][SCN], [C2mim][C(CN)3], [C4mim][C(CN)3], [P66614][N(CN)2], [P66614][Br] et leurs suspensions avec 0.5% et 1% w/w de nanotubes de carbone multi-parois (MWCNTs - de l'anglais multi-walled carbon nanotubes). Les résultats obtenus montrent qu'il y a une augmentation substantielle de la conductivité thermique du fluide de base due à la suspension du nanomatériau, en considérant les deux fractions massiques. Cependant, l'amélioration varie de manière significative lorsqu'on considère différents liquides ioniques de base, avec une gamme comprise entre 2 et 30%, avec une température croissante. Ce fait rend plus difficile l'unification des informations obtenues afin d'obtenir un modèle permettant de prédire l'amélioration de la conductivité thermique. Les modèles actuellement utilisé pour calculer la conductivité thermique des nanofluides présentent des valeurs considérablement sous-estimées par rapport aux valeurs expérimentales, en partie à cause des considérations sur le rôle de l'interface solide-liquide sur le transport de la chaleur.En ce qui concerne la densité, l'impact de l'ajout de MWCNTs sur la densité du fluide de base est très faible, variant entre 0.25% et 0.5% pour 0.5% w/w et 1% w/w MWCNTs, respectivement. Cela était assez attendu et est dû à la différence considérable de densité entre les deux types de matériaux. Cependant, la viscosité était la propriété pour laquelle les valeurs les plus élevées d' augmentation ont été vérifiées, allant de 28 à 245% pour les deux fractions massiques de MWCNT. La capacité calorifique était la seule des quatre propriétés mentionnées ci-dessus à ne pas être étudiée dans ce travail en raison de problèmes techniques avec le calorimètre à utiliser. Néanmoins, la quantité de données recueillies sur les propriétés thermophysiques restantes était extensif. On pense que ce dernier contribue de manière significative à une base de données croissante des propriétés des liquides ioniques et des ionanofluides, tandis que en fournissant un aperçu de la variation des propriétés obtenues à partir de la suspension de MWCNTs dans des liquides ioniques.(...)
One of the main areas of research in chemistry and chemical engineering involves the use of ionic liquids and nanomaterials as alternatives to many chemical products and chemical processes, as the latter are currently considered to be environmentally non-friendly. Their possible use as new heat transfer fluids and heat storage materials, which can obey to most principles of green chemistry or green processing, requires the experimental and theoretical study of the heat transfer mechanisms in complex fluids, like the ionanofluids. It was the purpose of this dissertation to study ionanofluids, which consist on the dispersion of nanomaterials in an ionic liquid.The first objective of this work was to measure thermophysical properties of ionic liquids and ionanofluids, namely thermal conductivity, viscosity, density and heat capacity in a temperature range between -10 e 150 ºC and at atmospherical pressure. In this sense, the thermophysical properties of a considerable set of ionic liquids and ionanofluids were measured, with particular emphasis on the thermal conductivity of the fluids. The ionic liquids studied were [C2mim][EtSO4], [C4mim][(CF3SO2)2N], [C2mim][N(CN)2], [C4mim][N(CN)2], [C4mpyr][N(CN)2], [C2mim][SCN], [C4mim][SCN], [C2mim][C(CN)3], [C4mim][C(CN)3], [P66614][N(CN)2], [P66614][Br] and their suspensions with 0.5% and 1% w/w of multi-walled carbon nanotubes (MWCNTs). The results obtained show that there is a substantial enhancement of the thermal conductivity of the base fluid due to the suspension of the nanomaterial, considering both mass fractions. However, the enhancement varies significantly when considering different base ionic liquids, with a range between 2 to 30%, with increasing temperature. This fact makes it more difficult to unify the obtained information in order to obtain a model that allows predicting the enhancement of the thermal conductivity. Current models used to calculate the thermal conductivity of nanofluids present values that are considerably underestimated when compared to the experimental ones, somewhat due to the considerations on the role of the solid-liquid interface on heat transport.Considering density, the impact from the addition of MWCNTs on the base fluid’s density is very low, ranging between 0.25% and 0.5% for 0.5% w/w and 1% w/w MWCNTs, respectively. This was fairly expected and is due to the considerable difference in density between both types of materials. However, viscosity was the property for which the highest values of enhancement were verified, ranging between 28 and 245% in both mass fractions of MWCNTs. The heat capacity was the only of the four properties mentioned above not to be studied in this work due to technical issues with the calorimeter to be used. Nevertheless, the amount of data collected on the remainder thermophysical properties was extensive. It is believed that the latter contributes meaningfully to a growing database of ionic liquids and ionanofluids’ properties, while providing insight on the variation of said properties obtained from the suspension of MWCNTs in ionic liquids.The second objective of this work consisted on the development of molecular interaction models between ionic liquids and highly conductive nanomaterials, such as carbon nanotubes and graphene sheets. These models were constructed based on quantum calculations of the interaction energy between the ions and a cluster, providing interaction potentials. Once these models were obtained, a second stage on this computational approach entailed to simulate, by Molecular Dynamics methods, the interface nanomaterial/ionic liquid, in order to understand the specific interparticle/molecular interactions and their contribution to the heat transfer. This would allow to study both structural properties, such as the ordering of the ionic fluid at the interface, and dynamic ones, such as residence times and diffusion. (...)
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Cremer, Till [Verfasser], et Hans-Peter [Akademischer Betreuer] Steinrück. « Ionic Liquid Bulk and Interface Properties : Electronic Interaction, Molecular Orientation and Growth Characteristics = Ionische Flüssigkeiten und deren Volumen- und Grenzflächeneigenschaften / Till Cremer. Betreuer : Hans-Peter Steinrück ». Erlangen : Universitätsbibliothek der Universität Erlangen-Nürnberg, 2012. http://d-nb.info/1021259578/34.

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Cho, Chul-Woong [Verfasser], Jorg Akademischer Betreuer] Thöming et Ingo [Akademischer Betreuer] [Krossing. « The contribution of molecular interaction potentials to properties and activities of ionic liquid ions in solution / Chul-Woong Cho. Gutachter : Jorg Thöming ; Ingo Krossing. Betreuer : Jorg Thöming ». Bremen : Staats- und Universitätsbibliothek Bremen, 2012. http://d-nb.info/1071993739/34.

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Ashworth, Claire. « A computational investigation of local interactions within ionic liquids and ionic liquid analogues ». Thesis, Imperial College London, 2015. http://hdl.handle.net/10044/1/58256.

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The potential applications of ionic liquids and related analogues are diverse. However, for large-scale industrial applications low cost ionic liquids are required. Moreover, for the full potential of ionic liquids to be realised, a fundamental link between molecular level interactions, structuring and the bulk phase properties must be established. Deep eutectic solvents (DESs) and protic ionic liquids have been identified as candidates for the potential application of chalcopyrite leaching. The choline chloride – urea DES and 1- butylimidazolium hydrogensulphate protic ionic liquid were selected as systems of primary interest. Local structuring within the selected systems has been investigated, with an emphasis on the hydrogen bonding interactions. The choline chloride – urea mixture is a prototypical example of a DES. Using DFT, the pairwise interactions between the constituent components, and within clusters composed of n.urea.choline-chloride (n = 1-3), have been evaluated. Many different types of hydrogen bond have been identified, exhibiting flexibility in both strength and number. The formation of the commonly proposed [2urea⋅Cl]– complexed anion has been scrutinised and found to be energetically competitive with other interactions. Moreover, contrary to existing proposals, the negative charge is found to remain localised on chloride. The cation-anion and anion-anion interactions within [C4Him][HSO4] and related systems have been compared and contrasted;; ion pairs were evaluated using DFT and the bulk systems modelled using classical MD. Local structuring within [C4Him][HSO4] exhibits features of both the aprotic analogue and alkylammonium protic ionic liquids. [HSO4]–⋅⋅⋅[HSO4]– interactions have been considered and found to be a notable feature of the [HSO4]– ionic liquids studied. It is anticipated that the formation of [HSO4]– aggregates influences the properties of the bulk systems. A QM/MM method for the study of ionic liquids is introduced. Preliminary analysis suggests that this is a viable approach for the investigation of local structuring within ionic liquids.
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Mamusa, Marianna. « Colloidal interactions in ionic liquids ». Phd thesis, Université Pierre et Marie Curie - Paris VI, 2014. http://tel.archives-ouvertes.fr/tel-01058482.

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Ionic liquids (ILs) are a novel class of ionic solvents, which are being used more and more often in chemical systems based on nanoparticles (NP) for several industrial and technological applications. However, at present we are unable to master the state of dispersion or aggregation of NP in these solvents, and the classic theories applied to colloidal stability, such as the DLVO, cannot be applied. In particular, the difficulty is found in the description of the electrostatic interactions in these ionic media. In this work, we try to better understand colloidal interactions in ILs through two systems that have been thoroughly characterized separately: magnetic maghemite nanoparticles, whose surface is well controlled in water, and the ionic liquid ethylammonium nitrate (EAN), known for its resemblance to water. These two systems are finally mixed together and studied at both the macroscopic and microscopic levels. We perform characterizations through several techniques: flame atomic absorption spectroscopy, optical microscopy under magnetic field, scattering methods (neutrons, X-rays and light), magneto-optic birefringence. We discover the importance of having a charged NP surface in order to obtain stable maghemite dispersions in EAN. In particular, the best colloidal stability is reached by adsorbing citrate molecules on the NP surface. We further investigate the effect of the NP's size and concentration, of the cationic counterion used to compensate the charge of citrate, of water content. Finally, we transfer our acquired knowledge to the realization of dispersions in biocompatible ILs.
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Hessey, Stephen. « Surface interactions of ionic liquids ». Thesis, University of Nottingham, 2012. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.664318.

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This thesis presents an investigation into the interactions between IL surfaces and gases through studying the kinetics of absorption, adsorption and desorption. A model for absorption is presented in which a gaseous molecule that impacts the surface first enters a physisorbed state, from which it can either desorb or be absorbed into the bulk IL.
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Choudhury, Subhankar. « Physicochemical study of diverse interactions of ionic liquids and biologically active solutes prevailing in liquid environments ». Thesis, University of North Bengal, 2016. http://ir.nbu.ac.in/handle/123456789/2763.

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Livres sur le sujet "Ionic Liquid interaction"

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Cremer, Till. Ionic Liquid Bulk and Interface Properties : Electronic Interaction, Molecular Orientation and Growth Characteristics. Heidelberg : Springer International Publishing, 2013.

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Zhang, Suojiang, Jianji Wang, Xingmei Lu et Qing Zhou, dir. Structures and Interactions of Ionic Liquids. Berlin, Heidelberg : Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-642-38619-0.

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Ionic Liquid Bulk And Interface Properties Electronic Interaction Molecular Orientation And Growth Characteristics. Springer International Publishing AG, 2013.

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Cremer, Till. Ionic Liquid Bulk and Interface Properties : Electronic Interaction, Molecular Orientation and Growth Characteristics. Springer, 2013.

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Cremer, Till. Ionic Liquid Bulk and Interface Properties : Electronic Interaction, Molecular Orientation and Growth Characteristics. Springer International Publishing AG, 2015.

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Zhou, Qing, Suojiang Zhang, Jianji Wang et Xingmei Lu. Structures and Interactions of Ionic Liquids. Springer London, Limited, 2013.

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Structures And Interactions Of Ionic Liquids. Springer-Verlag Berlin and Heidelberg GmbH &, 2013.

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Structures and Interactions of Ionic Liquids. Springer Berlin / Heidelberg, 2016.

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Chapitres de livres sur le sujet "Ionic Liquid interaction"

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Zhou, Ting, et Guiying Xu. « Aggregation Behavior of Ionic Liquid-Based Gemini Surfactants and Their Interaction with Biomacromolecules ». Dans Ionic Liquid-Based Surfactant Science, 127–49. Hoboken, NJ : John Wiley & Sons, Inc, 2015. http://dx.doi.org/10.1002/9781118854501.ch6.

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Singh, Surya Pratap, Ramalingam Anantharaj et Tamal Banerjee. « UNIFAC Group Interaction Prediction for Ionic Liquid-Thiophene Based Systems Using Genetic Algorithm ». Dans Lecture Notes in Computer Science, 195–204. Berlin, Heidelberg : Springer Berlin Heidelberg, 2010. http://dx.doi.org/10.1007/978-3-642-17298-4_20.

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Berthod, Alain, Ines Girard et Colette Gonnet. « Stationary Phase in Micellar Liquid Chromatography : Surfactant Adsorption and Interaction with Ionic Solutes ». Dans ACS Symposium Series, 130–41. Washington, DC : American Chemical Society, 1987. http://dx.doi.org/10.1021/bk-1987-0342.ch005.

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Cui, Guokai. « Quasi-chemisorption by Ionic Liquids Through Quasi-chemical Interaction ». Dans Encyclopedia of Ionic Liquids, 1–8. Singapore : Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-10-6739-6_139-1.

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Cui, Guokai. « Quasi-chemisorption by Ionic Liquids Through Quasi-chemical Interaction ». Dans Encyclopedia of Ionic Liquids, 1154–60. Singapore : Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-33-4221-7_139.

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Yang, Zhen. « Ionic Liquids and Proteins : Academic and Some Practical Interactions ». Dans Ionic Liquids in Biotransformations and Organocatalysis, 15–71. Hoboken, NJ, USA : John Wiley & Sons, Inc., 2012. http://dx.doi.org/10.1002/9781118158753.ch2.

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Walrafen, G. E., et W. H. Yang. « Fluctuations of Thermodynamic Properties of Supercooled Liquid Water ». Dans Interactions of Water in Ionic and Nonionic Hydrates, 141–43. Berlin, Heidelberg : Springer Berlin Heidelberg, 1987. http://dx.doi.org/10.1007/978-3-642-72701-6_24.

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Hunt, Patricia A. « CHAPTER 16. Noncovalent Interactions in Ionic Liquids ». Dans Catalysis Series, 350–76. Cambridge : Royal Society of Chemistry, 2019. http://dx.doi.org/10.1039/9781788016490-00350.

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Deschamps, Johnny, et Agilio A. H. Pádua. « Interactions of Gases with Ionic Liquids : Molecular Simulation ». Dans ACS Symposium Series, 150–58. Washington, DC : American Chemical Society, 2005. http://dx.doi.org/10.1021/bk-2005-0901.ch011.

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Gomes, M. F. Costa, P. Husson, J. Jacquemin et V. Majer. « Interactions of Gases with Ionic Liquids : Experimental Approach ». Dans ACS Symposium Series, 207–18. Washington, DC : American Chemical Society, 2005. http://dx.doi.org/10.1021/bk-2005-0901.ch016.

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Actes de conférences sur le sujet "Ionic Liquid interaction"

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Takaoka, Gikan, H. Ryuto et M. Takeuchi. « Surface Interaction and Processing Using Polyatomic Cluster Ions ». Dans 13th International Conference on Plasma Surface Engineering September 10 - 14, 2012, in Garmisch-Partenkirchen, Germany. Linköping University Electronic Press, 2013. http://dx.doi.org/10.3384/wcc2.18-21.

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We developed two types of polyatomic cluster ion sources, one of which was a liquid cluster ion source using organic materials with a high-vapor pressure. Vapors of liquid material such as ethanol and water were ejected through a nozzle into a vacuum region, and liquid clusters were produced by an adiabatic expansion phenomenon. Another type was a cluster ion source using ionic liquids with a relatively low-vapor pressure. Positive and negative cluster ions were produced by a high-electric field emission. In addition, the interaction of polyatomic cluster ions with solid surfaces such as Si(100), SiO2, glass, and PMMA surfaces was investigated, and chemical sputtering was predominant for the Si(100) surfaces irradiated by ethanol cluster ion beams. Also, the irradiation damage of the Si(100) surfaces by ethanol and water cluster ion beams was smaller than that by Ar monomer ion irradiation at the same acceleration voltage. With regard to surface modification, PMMA surfaces were chemically modified by water cluster irradiation. Also, glass surfaces changed to electrically conductive surfaces by ionic liquid cluster ion irradiation. Furthermore, to demonstrate engineering applications of high-rate sputtering and low-damage irradiation by ethanol cluster ion beams, micro-patterning was performed on the Si surfaces.
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Kohanoff, Jorge, Emilio Artacho, Károly Tokési et Béla Sulik. « First-principles molecular dynamics simulations of the interaction of ionic projectiles with liquid water and ice ». Dans RADIATION DAMAGE IN BIOMOLECULAR SYSTEMS : Proceedings of the 5th International Conference (RADAM 2008). AIP, 2008. http://dx.doi.org/10.1063/1.3058991.

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Nazaripoor, Hadi, Charles R. Koch et Subir Bhattacharjee. « Dynamics of Thin Liquid Bilayers Subjected to an External Electric Field ». Dans ASME 2014 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2014. http://dx.doi.org/10.1115/imece2014-37302.

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Spatiotemporal evolution of liquid-liquid interface leading to dewetting and pattern formation is investigated for thin liquid bilayeres subjected to the long range electrostatic force and the short range van der Waals forces. Based on the 2D weakly non-linear thin film equation three dimensional structure evolution is numerically simulated. A combined finite difference for the spatial dimensions and an adaptive time step ODE solver is used to solve the governing equation. For initially non-wetting surfaces, the stabilizing effects of viscosity and interfacial tension and the destabilizing effect of the Hamaker constant are investigated. Electrostatic interaction is calculated analytically for both perfect dielectric-perfect dielectric and ionic conductive-perfect dielectric bilayers. Ionic conductive-perfect dielectric bilayers based on the electric permittivity ratio of layers are found to be stabilized or deformed in response to the applied external electric field.
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Perlmutter, Stephen H., David Doroski et Garret Moddel. « Liquid Crystal Device Performance Degradation through Selective Adsorption of Ions by Alignment Layers ». Dans Spatial Light Modulators and Applications. Washington, D.C. : Optica Publishing Group, 1995. http://dx.doi.org/10.1364/slma.1995.lthd3.

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We have found selective adsorption to be responsible for the observed increase in liquid crystal ion populations as test cells are driven. Increasing ion populations correlated well with evidence of increased shielding of an applied voltage. A number of different alignment layers were compared for their tendency toward selective absorption. To investigate the interaction between ions and the alignment layers, in addition to liquid crystals a number of alcane liquids with known ionic components were used in test cells. A computer-implemented simulation of ion behavior was developed and used to verify our interpretations of our experimental results.
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Gan, Yu, et Van P. Carey. « An Exploration of the Effects of Dissolved Ionic Solids on Bubble Merging in Water and Its Impact on the Leidenfrost Transition ». Dans 2010 14th International Heat Transfer Conference. ASMEDC, 2010. http://dx.doi.org/10.1115/ihtc14-23330.

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Theoretical models and MD simulation studies suggest that dissolved salts tend to alter the surface tension at liquid vapor interfaces and affect the stability of the free liquid film between adjacent bubbles. Recent modeling of the Leidenfrost phenomenon also indicates that bubble merging is a key mechanism affecting the Leidenfrost transition conditions. This investigation summarizes the results of an investigation of the effects of dissolved salts on liquid film stability and bubble merging in the aqueous solution. The interaction of pairs of bubbles injected into solution with different dissolved salt concentrations was studied experimentally to determine the probability of merging from statistics for ensembles of bubble pairs. The results of these experiments indicate that very low dissolved salt concentrations can strongly reduce the tendency of adjacent bubbles to merge, implying that the presence of the dissolved salt in such cases strongly enhances the stability of the free liquid film between adjacent bubbles. The trends are compared to predictions of free liquid film stability by wave instability theory and MD simulations. These trends are also compared to experimental data indicating the effects of dissolved salt on the Leidenfrost transition. These comparisons indicate that the suppression of merging due to the effects of some dissolved salts can significantly alter the Leidenfrost transition conditions. The implications of this in quenching of cast aluminum or steel parts using water of variable hardness are also discussed.
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Guo, Hong, Rui Liu, Alfonso Fuentes-Aznar et Patricia Iglesias Victoria. « Friction and Wear Properties of Halogen-Free and Halogen-Containing Ionic Liquids Used As Neat Lubricants, Lubricant Additives and Thin Lubricant Layers ». Dans ASME 2017 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/detc2017-67971.

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The lubricating ability of one halogen-free and one halogen-containing phosphonium-based ionic liquids are investigated as neat lubricants, lubricant additives and thin lubricant layers in steel-steel contact. The use of the ionic liquids in any of the three lubricating methods reduced friction and wear compared to a base mineral oil. The halogen-free ionic liquid outperformed the halogen-containing ionic liquid in the three methods of lubrication. The highest friction and wear reduction were obtained when ionic liquids were used as neat lubricants. Under this condition, friction reductions of 37.21% and 25.73 %, and wear reduction of 47.12% and 41.18% compared to the based mineral oil were obtained for the halogen-free and halogen-containing ionic liquids respectively. The wear mechanisms and surface interactions are discussed in terms of ionic liquid-metal surface interactions from optical and SEM images and EDS analysis.
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Yazdi, Shahrzad, Reza Monazami et Mahmoud A. Salehi. « 3D Numerical Analysis of Velocity Profiles of PD, EO and Combined PD-EO Flows Through Microchannels ». Dans ASME 4th International Conference on Nanochannels, Microchannels, and Minichannels. ASMEDC, 2006. http://dx.doi.org/10.1115/icnmm2006-96039.

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In this paper, a three-dimensional numerical model is developed to analyze flow characteristics of pressure driven, electroosmotic and combined pressure driven-electroosmotic flows through micro-channels. The governing system of equations consists of the electric-field and flow-field equations. The solution procedure involves three steps. The net charge distribution on the cross section of the micro-channel is computed by solving two-dimensional Poisson-Boltzmann equation using the finite element method. Then, using the computed fluid’s charge distribution, the magnitude of the resulting body force due to interaction of an external electric field with the charged fluid is calculated along the micro-channel. Finally, three dimensional Navier-Stokes equations are solved by considering the presence of the electro-kinetic body forces in the flow system for electroosmotic and combined pressure driven electroosmotic flow cases. The results reveal that the flow patterns for combined PD-EO cases are significantly different from the parabolic velocity profile of the laminar pressure-driven flow. The effect of the liquid bulk ionic concentration and the external electric field strength on flow patterns through the square-shaped micro-channels is also investigated over a wide range of external electric field strengths and bulk ionic concentration.
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Sharma, Neeraj, Gerardo Diaz et Edbertho Leal-Quiros. « Effects of Externally Applied Electric Field on the Electric Double Layer Formed in an Electrolyte Layer and its Contribution Towards Joule Heating ». Dans ASME 2011 International Mechanical Engineering Congress and Exposition. ASMEDC, 2011. http://dx.doi.org/10.1115/imece2011-63329.

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Joule heating of liquid films in the presence of an externally applied electric field is influenced by the formation of the electric double layer. The thickness and charge distribution inside the electric double layer determine the extent of interaction of the charge in the electric double layer with the externally applied electric field and the Joule heating of the electrolyte layer. For this reason, the effects of externally applied electric field (both parallel and along the normal to the surface) on the electric double layer are being studied in the present paper. In the absence of the externally applied electric field, the distribution of the electric potential in the double layer is given by Poisson equation. Assuming Boltzmann distribution for the ionic concentration in the double layer, one arrives at Poisson-Boltzmann equation for the electric potential distribution. The externally applied electric field changes this electric potential distribution. Hence, the contribution of the externally applied electric field is studied by including it in the Poisson-Boltzmann equation.
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Khan, Rizwan Ahmed, Hafiz Mudaser Ahmad, Mobeen Murtaza, Abdulazeez Abdulraheem, Muhammad Shahzad Kamal et Mohamed Mahmoud. « Impact of Multi-Branched Ionic Liquid on Shale Swelling and Hydration for High Temperature Drilling Applications ». Dans SPE/IADC Middle East Drilling Technology Conference and Exhibition. SPE, 2021. http://dx.doi.org/10.2118/202143-ms.

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Abstract Shale swelling and hydration during the drilling operation have adverse effects on the stability of a wellbore. Hydrophilic interactions of shale results in swelling and disintegration of the shale formation. This paper discusses wettability changes and hydration characteristics of shale to improve the wellbore stability. The use of multibranched ionic liquid as drilling fluid for high temperature applications was investigated. The novel multibranched ionic liquid (Trihexyltetradecyl phosphonium bis (2,4,4-trimethyl pentyl) phosphinate, denoted as Tpb-P) water-based drilling fluid was prepared by mixing different concentrations of ionic liquid and other additives such as filtration controller, rheological modifier, and pH controller. The wettability of bentonite powder was determined using a contact angle in the presence of various concentrations of ionic liquids. Several other experimental techniques, such as linear swelling, hot rolling recovery, and bentonite swell index, were used to examine the inhibition performance of ionic liquid. The rheology and filtration properties of ionic liquid-based drilling fluid were also examined. Various concentrations of multibranched ionic liquid were used to formulate the drilling fluids ranging from (0.1 to 0.5 wt.%), and their performances were compared with the base drilling fluid prepared without ionic liquid. The hydrophobicity of the shale surface was determined by measuring the contact angle, and results showed that drilling fluid having 0.1 wt.% concentration of ionic liquid has a maximum contact angle indicating the highly hydrophobic shale surface. The hot rolling shale recovery experiment was conducted at 150°F, and it was observed that adding ionic liquid improved the shale recovery (24.4%) compared to the base fluid recovery (12.8%). The linear swelling was evaluated over the time of 24 hours, and the least swelling of bentonite was noticed with 0.1 wt.% ionic liquid (98.1%) compared to linear swelling in deionized water (125%). The results suggested that the ionic liquid in the drilling fluid chemically interacted with the clay surface and reduced the hydrophilicity of clay, which restricts the exchange of water onto the clay surface.
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Davidson, Jacob D., et N. C. Goulbourne. « Actuation and Charging Characteristics of Ionic Liquid-Ionic Polymer Transducers ». Dans ASME 2010 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. ASMEDC, 2010. http://dx.doi.org/10.1115/smasis2010-3892.

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Ionic polymer transducers (IPTs) are soft sensors and actuators which operate through a coupling of micro-scale chemical, electrical, and mechanical interactions. The use of an ionic liquid as solvent for an IPT has been shown to dramatically increase transducer lifetime in free-air use, while also allowing for higher applied voltages without electrolysis. In this work we model charge transport in an ionic liquid IPT by considering both the cation and anion of the ionic liquid as mobile charge carriers, a phenomenon which is unique to ionic liquid IPTs compared to their water-based counterparts. The electrochemical behavior of the large ionic liquid ions is described by use of a modified Nernst-Planck equation which accounts for steric effects in double layer packing. The method of matched asymptotic expansions is applied to solve the resulting system of equations, and analytical expressions are derived for the nonlinear charge transferred and capacitance of the IPT as a function of the applied voltage. The boundary layer ionic concentration and charge density profiles and the leading order dynamics are also computed for the ionic liquid IPT. A simple equivalent circuit model is constructed in order to facilitate a comparison with experimental results. The implications of these model results in regards to actuation and charging performance characteristics of ionic liquid IPTs are noted.
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Rapports d'organisations sur le sujet "Ionic Liquid interaction"

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Fayer, Michael D. Dynamics and Interactions in Room Temperature Ionic Liquids, Surfaces and Interfaces. Fort Belvoir, VA : Defense Technical Information Center, janvier 2016. http://dx.doi.org/10.21236/ad1003769.

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Eucker, IV, et William. Probing the Interaction of Ionic Liquids with CO2 : A Raman Spectroscopy and Ab Initio Study. Fort Belvoir, VA : Defense Technical Information Center, mai 2008. http://dx.doi.org/10.21236/ada486611.

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