Comparison of lipid membrane-water partitioning with various organic solvent-water partitions of neutral species and ionic species: Uniqueness of cerasome as a model for the stratum corneum in partition processes

Zhang, K., Fahr, A., Abraham, M.H., Acree, W.E. Jr., Tobin, Desmond J., Liu, Xiangli

08 June 2015

Yes / Lipid membrane-water partitions (e.g., immobilized artificial membrane systems where the lipid membrane is a neutral phospholipid monolayer bound to gel beads) were compared to various organic solvent-water partitions using linear free energy relationships. To this end, we also measured the retention factors of 36 compounds (including neutral and ionic species) from water to liposomes made up of 3-sn-phosphatidylcholine and 3-sn-phosphatidyl-l-serine (80:20, mol/mol), employing liposome electrokinetic chromatography in this work. The results show that lipid membranes exhibit a considerably different chemical environment from those of organic solvents. For both neutral species and ionic species, partitions into the more polar hydroxylic solvents are chemically closer to partition into the lipid membrane as compared to partitions into the less polar hydroxylic solvents and into aprotic solvents. This means that solutes partition into the polar parts of lipid membranes, regardless of whether they are charged or not. In addition, cerasome (i.e., liposome composed mainly of stratum corneum lipids) was compared with regular phospholipid liposomes as a possible model for human stratum corneum in partitions. It was found that the cerasome-water partition exhibits a better chemical similarity to skin permeation. This is probably due to the unique structures of ceramides that occur in cerasome and in the stratum corneum lipid domain. We further show that membranes in membrane-water partitions exhibit very different properties.

Ionic species

Lekc

Lfer

Liposomes

Partition

Physicochemical properties

In-line Fiber Polarizer

Perumalsamy, Priya

12 August 1998

Polarizers and polarization devices are important components in fiber optic communication and sensor systems. There is a growing need for efficient low loss components that are compatible with optical fibers. An all fiber in-line polarizer is a more desirable alternative that could be placed at appropriate intervals along communication links. An in-line fiber polarizer was fabricated and tested. The in-line fiber polarizer operates by coupling optical energy propagating in the fiber to a surface plasmon on a metallic film, which has been deposited onto the surface of the fiber. The device was constructed by polishing a short section of the lateral surface of the cladding to within the evanescent field present around the fiber core. Several thin films including a metal film are applied to the polished section of the fiber. Ionic self-assembled monolayer method was used to coat the polished fiber with thin film. / Master of Science

Fiber polarizer

Surface plasmon

Ionic self-assembled process.

Lipid Bilayer Formation in Aqueous Solutions of Ionic Liquids

Young, Taylor Tront

01 November 2012

The formation of lipid bilayer membranes between droplets of ionic liquid is presented as a means of forming functional bimolecular networks for use in sensor applications. Ionic liquids are salts that have a number of useful properties, such as low melting points making them liquid at room temperature and exceedingly low vapor pressure. Ionic liquids have seen recent popularity as environmentally friendly industrial solvent alternatives. Our research demonstrates that it is possible to consistently form lipid bilayers between droplets of ionic liquid solutions. Analysis shows that the ionic liquids have negligible effects on the physical stability and electrical properties of the bilayer. It is also shown that the magnitude of the conductance levels of Alamethicin peptide are altered by some ionic liquids. / Master of Science

Alamethicin

Ionic Liquid

Lipid Bilayer

Droplet Interface Bilayer

Micro-Manipulation and Bandwidth Characterization of Ionic Polymer Actuators

Kothera, Curt S.

12 December 2002

Ionic polymer materials are a class of electroactive polymers that have been used in recent applications that take advantage of their large bending deflection. Although these materials have been around since the 1960s, it has only been in the last decade that their electromechanical coupling has been discovered. Because their life as a transducer has been relatively short, the underlying mechanisms for their mechanical motion have not yet been fully characterized. Modeling has been performed with ionic polymers, but there is no existing model, to date, that explains all the physical phenomena associated them. The work presented in this document will contribute to the characterization of these materials. To better understand the dehydration effect of ionic polymers operating in an open air environment, research was performed to help characterize this effect. Through the use of frequency response analysis, trends were established showing how the material's response characteristics varied with time, as the polymer dehydrated. These tests were also run at different humidity levels to assess the impact environmental conditions had on the response. It was shown that lower humidity levels cause the system parameters to shift at a higher rate. The two configurations tested were clamped-free and clamped-clamped, in an effort to bound the performance of the actuators for engineering applications. The clamped-clamped condition also facilitated applying tension to the polymers for evaluation of the dehydrating effects. Several comparisons to beam theory were made throughout the analysis, using it as a baseline condition illustrator. Though qualitative results were obtained with the polymers, there was much discrepancy in quantitative measures. This was to be expected though, because ionic polymers are composite actuators that exhibit nonlinear behavior, while uniform beams are linear. Environmental testing was not all that was done, however. Control techniques were applied to improve the closed-loop performance of the actuators. Using proportional-integral control, it was demonstrated that ionic polymers are capable of tracking reference inputs better than it was previously thought. This result will validate future experimentation with ionic polymers for micro-manipulation applications. The simplicity of integral control also eliminated the need for cumbersome model derivations and control system designs, reducing the time necessary to implement and test an actuator. Through the use of this control algorithm, the closed-loop bandwidth was also characterized for the cantilever and clamped-clamped polymers. / Master of Science

bandwidth

micro-manipulation

IPMC

electroactive polymer

ionic polymer

Nano-Confined Room-Temperature Ionic Liquids for Electrochemical Applications

He, Yadong

28 February 2018

Room-temperature ionic liquids (RTILs) and their derivatives are promising electrolytes for electrochemical devices including supercapacitors. Understanding the behavior of RTILs in these devices is critical for improving their performance. The energy density of supercapacitors can be improved greatly by using RTILs as electrolytes and nanoporous carbon as electrodes, but the mechanism of the charge storage using these materials is not well understood. In this dissertation, the diffusion and charging dynamics of RTILs in nanopores are studied. The results show that ion packing typically plays the most important role in ion diffusion. The study also demonstrates that the cyclic charging and discharging of a pore can exhibit a number of interesting features (e.g., sloshing of ionic charge along the pores during cyclic scans), which help explain experimental observations such as the negligible contribution of co-ions to charge storage at high scan rates. Solid electrolytes with both high ionic conductivities and excellent mechanical strength are needed in many electrochemical devices. The invention of ion gels featuring aligned polyanions immersed inside RTILs has shown promise in meeting this demand, but the mechanism behind their superior mechanical strength remains elusive. Using molecular simulations, it is discovered that the high elastic moduli of model PBDT ion gels originate from the RTIL-mediated interactions between the polyanions. This insight is useful for future design of ion gels to improve their transport and mechanical properties. / Ph. D. / Room-temperature ionic liquids (RTILs) and their derivatives are promising electrolytes for electrochemical devices including supercapacitors. Understanding the behavior of RTILs in these devices is critical for improving their performance. The energy density of supercapacitors can be improved greatly by using RTILs as electrolytes and nanoporous carbon as electrodes, but the mechanism of the charge storage using these materials is not well understood. In this dissertation, the diffusion and charging dynamics of RTILs in nanopores are studied. The results show that ion packing typically plays the most important role in ion diffusion. The study also demonstrates that the cyclic charging and discharging of a pore can exhibit a number of interesting features (e.g., sloshing of ionic charge along the pores during cyclic scans), which help explain experimental observations such as the negligible contribution of co-ions to charge storage at high scan rates. Solid electrolytes with both high ionic conductivities and excellent mechanical strength are needed in many electrochemical devices. The invention of ion gels featuring aligned polyanions immersed inside RTILs has shown promise in meeting this demand, but the mechanism behind their superior mechanical strength remains elusive. Using molecular simulations, it is discovered that the high elastic moduli of model PBDT ion gels originate from the RTIL-mediated interactions between the polyanions. This insight is useful for future design of ion gels to improve their transport and mechanical properties.

Room-temperature ionic liquids

nanopore

ion gel

molecular dynamics

Caractérisation multi-échelle de la structure et du transport de cristaux liquides ioniques : vers des électrolytes solides innovants pour batteries lithium / Innovative solid electrolytes for Li-ion battery : multiscale structure and transport properties in ionic liquid crystals

Bernard, Laurent

30 January 2019

Le remplacement des électrolytes liquides conventionnels des batteries lithium-ion est un enjeu majeur pour améliorer leurs performances et leur sécurité. Dans ce contexte, ce travail de thèse est focalisé sur la synthèse d’une nouvelle classe d’électrolytes solides organiques : les cristaux liquides ioniques thermotropiques, ainsi que la caractérisation multi-échelle des nanostructures obtenues et du transport ionique. Tout d’abord, nous présentons les structures chimiques choisies pour créer des assemblages de molécules cristal liquide à conduction « single-ion ». Ensuite, nous détaillons l’étude structurale et fonctionnelle, qui a permis d’établir l’organisation supramoléculaire sous forme de phase colonnaire avec des canaux de conduction ionique nanométriques. Des conductivités pouvant atteindre 10-4 S.cm-1 à 70°C ont été obtenues. La dynamique des ions au sein de ces électrolytes a été étudiée à l’échelle moléculaire et nous avons mis en évidence un mécanisme de conduction par saut. La polymérisation des cristaux liquides ioniques pourrait permettre le développement d’électrolytes polymères de type single-ion pour les batteries. / One major issue towards large-scale application of lithium-based batteries concerns their safety which is directly related to the nature of the electrolyte. Solid electrolytes are at present considered as a promising approach to avoid the risks related to the commonly employed liquids. Herein we report the synthesis and the characterization of a promising class of electrolytes: Thermotropic Ionic Liquid Crystals (TILCs). We describe the design and the synthesis of new self-assembled single-ion materials in function of their chemical architecture. We performed a systematic structural and functional properties study, demonstrating the crystal-liquid properties as well as the supramolecular organization into columnar phases. One of the most promising TILC shows a conductivity of 10-4 S.cm-1 at 70°C. The ion dynamics was probed at molecular scale to establish the main features of hopping conduction mechanism. Further polymerization of the TILCs could be applied to develop high performance single-ion polymer electrolytes for Li-ion batteries.

Électrolyte

Single-Ion

Cristal liquide

Batterie

Saxs

Ionic transport

Electrolyte

Single-Ion

Liquid crystal

Battery

Saxs

Ionic transport

530

Novos líquido iônico e poli(líquido iônico) para aplicação em dispositivos eletroquímicos / Novel ionic liquid and poly(ionic liquid) for eletrochemical devices

Corrêa, Cintia Marques

12 December 2018

Líquidos iônicos (LI) e Poli(líquidos íonicos) (PLI) apresentam propriedades moduláveis extremamente interessantes, devido a possibilidade de infinitas combinações entre cátions e ânions, além da possibilidade de funcionalização tanto do cátion quanto do ânion para a inserção de propriedades de interesse, transformando esses LI e PLI em materiais de tarefa específica (task-LI e task-PLI). Nesta tese de doutorado, um PLI sólido, eletrocrômico e inédito foi sintetizado a partir de um LI funcionalizável e polimerizável (brometo de 1-cloropropil-3-vinilimidazólio) e o viologênio 4,4-bipiridina. Essa reação resultou em um monômero que teve sua estrutura intensamente elucidada e, em seguida, foi polimerizado, formando um polieletrólito sólido eletrocrômico estável mecanicamente e termicamente (309 °C). Os estudos espectroeletroquímicos a partir de um filme fino depositado sobre ITO revelaram um processo redox reversível com redução e oxidação nos potenciais de -0.45 e -0,3 V, respectivamente. O processo redox foi acompanhado por variação de coloração de transparente (estado totalmente oxidado) para roxo (estado reduzido/cátion radical) com contraste ótico de 19 % (525 nm), switching time de 20 s e eficiência da coloração (CE) de 60 cm2 C-1. A estabilidade eletroquímica do filme foi estudada via cronoamperometria e o material permaneceu eletroativo e eletrocrômico por 4 horas e 400 ciclos sem perdas consideráveis de eletroatividade. Além disso, mesmo após 16 h e 1600 ciclos o material apresentou eletroatividade com um decréscimo pequeno de corrente e variação de transmitância. Adicionalmente, o monitoramento do material com uma microbalança a cristal de quartzo com dissipação (QCM-D) indicaram que a compensação de carga do polímero é acompanhada por uma considerável variação de viscoelasticidade do filme e a principal espécie responsável pela compensação é o ânion, sendo o ânion volumoso [Tf2N] incapaz de compensar a carga do sistema impedindo o processo redox de ocorrer. Ainda com relação a capacidade de funcionalização dos LI, um LI inédito foi preparado a partir de um segundo LI funcionalizável (brometo de 1-cloropropil-1-metilpirrolidíneo) que foi elucidado por diversas técnicas incluindo ressonância magnética nuclear em duas dimensões de 1H, 13C e 15N (RMN 2D: COSY, NOESY, HSQC e HMBC) e RMN 15N. Dessa forma, um LI funcionalizado com aza-éter de coroa (LIcoroa) foi preparado a partir da reação do LI funcionalizável e o aza-18-coroa-6 e, novamente, a estrutura foi elucidada, incluindo RMN 2D. O LIcoroa apresentou boa estabilidade térmica (371 °C) e eletroquímica (janela de 4 V). A densidade do LI foi obtida no valor de 1,5 g cm-3 (25 °C). No entanto, a viscosidade do LI foi elevada afetando diretamente sua condutividade elétrica quando comparado com o LI bis(trifluorosulfonil)imida de 1-bultil-1-metilpirrolidíneo já amplamente estudado na literatura. Para aplicações, este LI coroa está sendo estudado para atuar como eletrólito em baterias de íon lítio devido a sua possível capacidade de complexar com este íon e diminuir a interação do Li+ com os oxigênios da espécie aniônica [Tf2N]. / Ionic Liquids (ILs) and poly(Ionic Liquids) (PoILs) have fully tunable properties due to their different ion combinations as well as cation or anion functionalization, which results in smart materials with endless possibilities. In this study, a solid electrochromic PoIL was synthesized using a novel functionalizable and polymerizable IL (1-propyl-3-vinylimidazolium chloride bromide) and a viologen (4,4\'-bipyridine) that reacted to form a monomer. Its subsequent polymerization resulted in a mechanically stable, highly ionically and electronically conductive electrochromic polyelectrolyte with a thermal decomposition temperature higher than 309°C and a glass transition temperature of 13°C. Spectroelectrochemical studies of the polymer deposited as a thin film over a transparent conductive substrate demonstrated a reversible redox process with reduction and oxidation potentials of -0.45 and -0.3V, respectively, which was accompanied by a reversible color change from colorless (oxidized state) to purple (reduced state) with an optical contrast of 19% at 525nm, a switching time of nearly 20s and a coloration efficiency of 60 cm2 C-1. Additionally, the film was repetitively switched from colorless to purple and began to lose electroactivity after approximately 4h and 400cycles. However, electroactivity was still observed after 16h or 1600cycles. Moreover, quartz crystal microbalance with dissipation monitoring indicated that the polymer charge compensation process was accompanied by a huge viscoelastic change in the film, as demonstrated by the spread of the harmonics and important changes in dissipation. Moreover, the anion is the most important specie in the charge compensation process, the large anion [Tf2N] is unable to compensate the charge, preventing the redox process from occurring. Also regarding the functionalization capacity of LI, a novel LI was prepared from a second functionalizable LI (1-chloropropyl-1-methylpyrrolidinium bromide) which was intensively elucidated by several techniques including two-dimensional nuclear magnetic resonance 1H, 13C and 15N (2D NMR: COSY, NOESY, HSQC and HMBC). Thus, a functionalized LI with aza-crown ether (LIcrown) was prepared from the reaction of the functionalizable LI and aza-18-crown-6 and, again, the structure was elucidated, including 2D NMR. LIcrown presented good thermal stability (371 ° C) and electrochemistry (4 V window). The density of the IL was 1,5 g cm-3. However, the viscosity of the LI was elevated by directly affecting its electrical conductivity when compared to the 1-butyl-1-methylpyrrolidinium bis(trifluorosulfonyl)imide already widely studied in the literature. For applications, this LIcrown is being studied to act as an electrolyte in lithium ion batteries because of its possible ability to complex with this ion and to decrease the interaction of Li+ with the oxygen of the anionic species [Tf2N].

Crown ether

Electrochromism

Eletrocromismo

Éter de coroa

Funcionalização

Functionalization

Ionic liquids

Líquido iônico

Poli(líquido iônico)

Poly(Ionic liquids)

Viologen

Viologênio

Functional ionic liquids in crystal engineering and drug delivery

Bansode, Ratnadeep Vitthal

January 2016

The objective of this research is to explore the use of ionic liquds in crystal engineering and drug delivery. Ionic liquids have a wide range of applications in pharmaceutical field due to their unique physicochemical propertie ssuch as chemical, thermal stability, low melting point, nonvolatility, nonflamability, low toxicity and recyclability which offer unique and interesting potential for pharmaceuitcal applications. Currently, many research groups are working on the development of ionic liquids to use in this field but there is need to develop systematic understanding about new techniques for synthesis and applications of ionic liquids to obtain new crystal form and potential of drug ionic salts. The synthesis of fifteen phosphonium ionic liquids under microwave irradiation and their physicochemical properties was investigated. The reaction time was significantly reduced compared to conventional methods, and higher yields were reported. The crystallisation of pharmaceutical drugs such as sulfathiazole, chlorpropamide, phenobarbital and nifedipine were investigated using imidazolium ionic liquids. The supramolecular complex of sulfathiazole and phenobarbital with imidazolium ionic liquids and polymorphic change in chlorpropamide was achieved. The ionic liquids provides unique environment for the crystallisation. The imidazolium salts of ibuprofen and diclofenac were synthesised and evaluated for physicochemical properties and their pharmaceutical performances especially transdermal absorption. The investigation of physicochemcal properties and pharmaceutical performance of imidazolium drug salts indicated opportunity to optimise lipophilicity and other physicochemical properties such as molecular size, osmolality, viscosity to achieve desired skin deposition and permeation. This study will provide a new approach to design of new drug salts develop using the interdisciplinary knowledge of chemical synthesis and drug delivery.

570

Supported ionic liquid phase catalysis in continuous supercritical flow

Duque, Ruben

January 2013

The separation of the expensive catalysts from the solvent and reaction products remains one of the major disadvantages of homogeneous catalytic reactions, which are otherwise advantageous because of their high activity, tuneable selectivity and ease of study. Ideally, the homogeneous reactions would be carried out in continuous flow mode with the catalyst remaining in the reactor at all times, whilst the substrates and products flow over the catalyst. The system we have been studying is one where the catalyst is dissolved in a thin film of an ionic liquid, and this is supported within the pores of a microporous silica. This supported ionic liquid phase (SILP) catalyst is then placed in a tubular flow reactor, similar to that used for heterogeneous reactions. The raw materials are then injected into the rig, pass through the reactor and the products and the raw materials that have not reacted are collected at the other end of the rig. Supercritical CO₂ is used to transport the raw materials and products along the catalyst bed, allowing a continuous flow mode with low leaching for both the catalyst and the ionic liquid. We have applied this procedure first to alkene metathesis catalysed by a ruthenium complex that has been especially designed to dissolve in 1-butyl-3-methyimidazolium triflamide (BMIM NTf₂), which was used as ionic liquid. Activity is observed for the ring closing metathesis of diethyl 2,2-diallylmalonate, but the catalyst is not stable, only allowing about 300 turnovers. This instability is attributed to the formation of Ru=CH₂ moieties, which dimerise to an inactive species. More success is achieved with internal alkenes such as 2-octene and especially methyl oleate. Self metathesis of methyl oleate continues for >10.000 turnovers over 10 h, with only small decreases in activity. The cross metathesis of methyl oleate with dimethyl maleate has also been studied. Cross metathesis dominates in the early stages of the reaction but the cross metathesis products diminish with time. Surprisingly, the catalyst does not deactivate since self metathesis of methyl oleate continues. The phase behaviour of the reaction was monitored and gave us an insight into the reasons for this change in selectivity. Methoxycarbonylation reactions in continuous flow proved to be a much more difficult process than the previous metathesis reactions. Higher catalyst loading was needed to reduce the reaction times. The first continuous flow reactions showed conversion predominantly, if not exclusive, of 1-octene isomerised products. The presence of ionic liquid (IL) in the SILP system was essential, otherwise the catalyst leached out of the reactor very quickly. Batch reactions showed that none of the studied parameters (absence of presence of either BMIM NTf₂, OMIM NTf₂, silica or CO₂) had any influence on the reaction, but when observing the results it was noticed that the reactions that gave the best results were performed in a close range of pressures between 55 and 70 bar, indicating that the reaction might be pressure dependent. Further continuous flow reactions in that range of pressures gave the best conversions to methoxycarbonylation products. Unfortunately, at these pressures and without CO₂ the reaction took place in a liquid phase and thus substantial IL and catalyst leaching was observed, causing a decrease in conversion and making the reaction not feasible under continuous flow conditions. Nevertheless, the catalyst system composed of Pd, 1,2-bis(di-tert-butylphosphinomethyl)benzene (DTBPMB) ligand and acid showed an excellent linear selectivity, usually higher than 90%, both in batch and continuous flow reactions. Hydrogenation reactions of dimethyl itaconate (DMI) and dibutyl itaconate (DBI) using Rh-MeDuPhos showed excellent activity and enantioselestivity in a batch mode. In a continuous flow mode IL leaching caused a decrease of the enantioselectivity. The best results were obtained when CO₂ was not present. On the other hand, the absence of CO₂ implied that the reaction was performed in a liquid phase and therefore abundant IL leaching was observed along with a decrease in the enantioselectivity. A study of the reaction behaviour when using CO₂ in its different phases (liquid, gas and supercritical) was carried out. Under supercritical conditions IL leaching was avoided but conversion was not observed. When using CO₂ in its liquid phase some conversion was observed and full conversion occurred in its gas phase, but abundant IL leaching caused a decrease in the enantioselectivity. Better results were obtained by immobilising a Rh-MeDuPhos catalyst onto alumina via heteropoly acids. The effect of pressure, H₂ flow and substrate flow were studied and the stability of the reaction in the long term was examined under optimal conditions. More than 12,900 TONs were achieved after 4 days of continuous reaction, with conversions higher than 90% during the 3 first days and e.e. higher than 99% during the 2 first days.

541

Sensing materials based on ionic liquids

Saheb, Amir Hossein

08 July 2008

The first chapter of this thesis describes the motivation behind using room temperature ionic liquids (RTILs) in gas sensor research and reviews current applications of RTILs in various sensors. The second chapter describes electrochemical polymerization of aniline in room temperature 1-butyl-3-methylimmidazolium ionic liquids without addition of any acid. It is shown that the polymerization of aniline in BMI(BF4) does require small but controlled amounts of water whereas the polymerization in BMI(PF6) and in BMI(TF2N) does not require any water addition. The third chapter describes the construction of reference electrodes for RTIL applications that have a known and reproducible potential versus the ferrocene/ ferrocenium couple. They are based on reference electrodes of the first kind, Ag/Ag+ couple type, or of the second kind, based on Ag/AgCl in M+Cl-. The stability, reproducibility, and temperature behavior of the two reference systems have been characterized. The fourth chapter describes the electrochemical preparation and spectral analysis of gold clusters by adding gold atoms one-by-one through polyaniline s ability to form a strong complex with chloroaurate at the protonated imine sites. Our results confirm that both the amount and the size of gold clusters affects the properties of the composite material. The fifth chapter describes the development and characterization of a CHEMFET sensing layer based on a composite of CSA-doped polyaniline (PANI), and the room temperature ionic liquid BMI(TF2N) for the sensing of ammonia gas. The work function responses of the cast films with and without IL are analyzed by step-wise changes of ammonia gas concentration from 0.5 to 694 ppm in air as a function of the mole fraction of IL to PANI. The PANI CSA/BMI(TF2N) layers shows enhanced sensitivities, lower detection limit and shorter response times. The final chapter describes the preparation and characterization of field-effect transistors with mixed ionic-electronic conductors that have been created by varying the ratio of room temperature ionic liquid and emeraldine salt of polyaniline. Transistor with high electronic conductivity (32mol% ES-PANI) and Au gate contact exhibited theoretical behavior of an IGFET; whereas, the purely ionic gate behaved irreproducibly, indicating that a capacitive divider has been formed in the gate.

Gas sensor

Reference electrode

Ammonia

FET

Electropolymerization

Gold clusters

Conducting polymer

CHEMFET

Polyaniline

Ionic liquids

Ionic solutions

Detectors

Polymerization

Aniline