Corrosion Inhibition Performance of Imidazolium Ionic Liquids and Their Influence On Surface Ferrous Carbonate Layer Formation

Yang, Dongrui

07 June 2016

No description available.

Chemical Engineering

Materials Science

Mild steel

CO2 corrosion

corrosion inhibitor

EIS

polarization

interfaces

Imidazolium

ionic liquid

Synthesis of Room Temperature Ionic Liquid Based Polyimides for Gas Separations

Li, Pei

14 June 2010

No description available.

Chemical Engineering

Chemistry

membrane

gas separation

room temperature ionic liquid

polyimide

Catalytic Conversion of Hemicellulosic Sugars into Furfural in Ionic Liquid Media

Shittu, Akinwale A.

January 2010

No description available.

Alternative Energy

Chemical Engineering

xylose

furfural

ionic liquid

xylulose

biomass

pentose

Preparation, Characterization, and Application of Molecular Ionic Composites for High Performance Batteries

Yu, Deyang

03 November 2021

A solid electrolyte is a crucial component of any solid state battery. Polymer gel electrolytes have received increasing attention in recent years due to their high ionic conductivity, flexibility, and improved safety. However, a general tradeoff usually exists between the mechanical properties and ionic conductivity in such materials. Molecular ionic composites (MICs) are a new type of rigid polymer gel electrolyte based on ionic liquids (ILs) and a double helical rigid-rod polyamide, poly(2,2′-disulfonyl-4,4′-benzidine terephthalamide) (PBDT). MICs have high ionic conductivity, high thermal and electrochemical stability, and widely tunable and high tensile modulus even at relatively low polymer content. MICs show great promise as solid electrolytes for solid state batteries. This dissertation describes the preparation and characterization of MIC electrolyte membranes. These transparent, flexible, and tough membranes are prepared through a convenient solvent casting process. A large variety of ILs, including both hydrophilic and hydrophobic examples, are suitable to prepare MIC electrolyte membranes by adjusting the solvents used in the casting process. The prepared membranes show a biphasic internal structure consisting of a PBDT-rich “bundle” phase and an IL-rich “puddle” (interconnected fluid) phase. Similar to the bulk MIC ingots prepared previously through an interfacial ion exchange process, the MIC membranes also have high ionic conductivity and tensile modulus at low polymer content. A MIC membrane composed of 1-butyl-1-methylpyrrolidinium bis(trifluoromethylsulfonyl)imide (Pyr₁₄TFSI), LiTFSI, and PBDT in a mass ratio of 8:1:1 is tested as a solid electrolyte for lithium metal batteries. This electrolyte membrane shows high ionic conductivity and high rigidity. The shear storage modulus of this MIC electrolyte membrane only decreases by 35% when heated to 200 °C from room temperature, suggesting great mechanical stability at high temperatures. The electrolyte membrane is successfully used as solid electrolyte for a Li/LiFePO₄ battery working over a large temperature range from 23 to 150 °C, and the discharge capacity retention of the cell is as high as 99% after 50 cycles at 150 °C. By replacing the IL in the MIC with a charge-neutral liquid, single-ion-conducting polymer gel electrolyte composed of PBDT and polyethylene glycol (PEG) oligomer are obtained. Similar to the MICs, these single-ion-conducting materials also have high Young’s modulus and biphasic internal structures. This study reveals that the counter ion (Li⁺ or Na⁺) of the PBDT has a major effect on both the ionic conductivity and modulus of the materials. Due to the stronger intermolecular interactions, LiPBDT-PEG demonstrates lower ionic conductivity but higher Young’s modulus. This dissertation also evaluates the viability of rigid PBDT as a polymer binder for electrodes. Aqueous solution-processed LiFePO₄ electrodes with only 3 wt% PBDT demonstrate stable cycling over 1000 cycles without obvious capacity decay, and the rate capacity of these aqueous solution-processed electrodes are comparable to the electrodes prepared with conventional poly(vinylidene difluoride) (PVDF) as the binder, suggesting PBDT can serve as a potential electrode binder for commercial applications. / A solid electrolyte is a crucial component of any solid state battery. Polymer gel electrolytes have received increasing attention in recent years due to their high ionic conductivity, flexibility, and improved safety. However, a general tradeoff usually exists between the mechanical properties and ionic conductivity in such materials. Molecular ionic composites (MICs) are a new type of rigid polymer gel electrolyte based on ionic liquids (ILs) and a double helical rigid-rod polyamide, poly(2,2′-disulfonyl-4,4′-benzidine terephthalamide) (PBDT). MICs have high ionic conductivity, high thermal and electrochemical stability, and widely tunable and high tensile modulus even at relatively low polymer content. MICs show great promise as solid electrolytes for solid state batteries. This dissertation describes the preparation and characterization of MIC electrolyte membranes. These transparent, flexible, and tough membranes are prepared through a convenient solvent casting process. A large variety of ILs, including both hydrophilic and hydrophobic examples, are suitable to prepare MIC electrolyte membranes by adjusting the solvents used in the casting process. The prepared membranes show a biphasic internal structure consisting of a PBDT-rich "bundle" phase and an IL-rich "puddle" (interconnected fluid) phase. Similar to the bulk MIC ingots prepared previously through an interfacial ion exchange process, the MIC membranes also have high ionic conductivity and tensile modulus at low polymer content. A MIC membrane composed of 1-butyl-1-methylpyrrolidinium bis(trifluoromethylsulfonyl)imide (Pyr14TFSI), LiTFSI, and PBDT in a mass ratio of 8:1:1 is tested as a solid electrolyte for lithium metal batteries. This electrolyte membrane shows high ionic conductivity and high rigidity. The shear storage modulus of this MIC electrolyte membrane only decreases by 35% when heated to 200 °C from room temperature, suggesting great mechanical stability at high temperatures. The electrolyte membrane is successfully used as solid electrolyte for a Li/LiFePO4 battery working over a large temperature range from 23 to 150 °C, and the discharge capacity retention of the cell is as high as 99% after 50 cycles at 150 °C. By replacing the IL in the MIC with a charge-neutral liquid, single-ion-conducting polymer gel electrolyte composed of PBDT and polyethylene glycol (PEG) oligomer are obtained. Similar to the MICs, these single-ion-conducting materials also have high Young's modulus and biphasic internal structures. This study reveals that the counter ion (Li+ or Na+) of the PBDT has a major effect on both the ionic conductivity and modulus of the materials. Due to the stronger intermolecular interactions, LiPBDT-PEG demonstrates lower ionic conductivity but higher Young's modulus. This dissertation also evaluates the viability of rigid PBDT as a polymer binder for electrodes. Aqueous solution-processed LiFePO4 electrodes with only 3 wt% PBDT demonstrate stable cycling over 1000 cycles without obvious capacity decay, and the rate capacity of these aqueous solution-processed electrodes are comparable to the electrodes prepared with conventional poly(vinylidene difluoride) (PVDF) as the binder, suggesting PBDT can serve as a potential electrode binder for commercial applications. / Doctor of Philosophy / Solid state batteries are widely considered as the pathway to next-generation high performance batteries. In a solid state lithium battery, the liquid organic carbonate electrolyte is replaced with a solid electrolyte. Polymer gel electrolytes are a type of potential solid electrolyte that have been widely studied in recent decades. This dissertation describes the application of a rigid polymer in preparing polymer gel electrolytes. This highly charged and rigid polymer is a water-soluble polyamide known as PBDT with a double helical structure akin to DNA. Through a modified solvent casting process, a new type of polymer gel electrolyte, known as molecular ionic composite (MIC), is prepared using PBDT and various ionic liquids. Extra salt (which can contain lithium) can also be incorporated into the MIC membrane. This type of new polymer gel electrolyte is rigid with high tensile modulus even at high temperatures and low polymer (PBDT) content. MIC membranes are used as solid electrolytes for lithium metal batteries working over a wide temperature range from 23 to 150 °C. A rigid polymer gel electrolyte can also be obtained by replacing the ionic liquids in MICs with polyethylene glycol. Besides the application in preparing solid electrolytes, PBDT is also evaluated as a polymer binder for aqueous processed electrodes. Preliminary study reveals that PBDT holds great potential for a range of commercial energy storage applications.

polymer electrolyte

ion gel

solid state battery

high temperature

ionic liquid

single-ion conducting

electrode binder

Synthesis and Characterization of Zwitterion-Containing Acrylic (Block) Copolymers for Emerging Electroactive and Biomedical Applications

Wu, Tianyu

12 October 2012

Conventional free radical polymerization of n-butyl acrylate with 3-[[2-(methacryloyloxy)ethyl](dimethyl)-ammonio]-1-propanesulfonate (SBMA) and 2-[butyl(dimethyl)amino]ethyl methacrylate methanesulfonate (BDMAEMA MS), respectively, yielded zwitterionomers and cationomers of comparable chemical structures. Differential scanning calorimetry (DSC), small-angle X-ray scattering (SAXS), and atomic force microscopy (AFM) revealed that zwitterionomers promoted more well-defined microphase-separation than cationic analogs. Dynamic mechanical analyses (DMA) of the copolymers showed a rubbery plateau region due to physical crosslinks between charges for zwitterionomers only. We attributed improved microphase-separation and superior elastomeric performance of the zwitterionomers to stronger association between covalently tethered charged pairs. Zwitterionomer / ionic liquid binary compositions of poly(nBA-co-SBMA) and 1-ethyl-3-methylimidazolium ethylsulfate (EMIm ES) were prepared using both the 'swelling– and the –cast with– methods. Dynamic mechanical analysis revealed that the 'swollen– membranes maintained their thermomechanical performance with up to 18 wt% EMIm ES incorporation, while that of the –cast with– membranes decreased gradually as the ionic liquid concentration in the composite membranes increased. Small-angle X-ray scattering results indicated that the 'swollen– and the –cast with– membranes have different morphologies, with the ionic liquid distributed more evenly inside the –cast with– membranes. Impedance spectroscopy results showed that the –cast with– membranes had better ionic conductivity than the 'swollen– membrane at high ionic liquid concentration, in agreement with our proposed model. The results indicated that the different processing methods had a significant impact on thermomechanical properties, ionic conductivities, as well as morphologies of the zwitterionomer / ionic liquid binary compositions. Reversible addition-fragmentation chain transfer polymerization (RAFT) strategy afforded the synthesis of well-defined poly(sty-b-nBA-b-sty). 2-(Dimethylamino)ethyl acrylate (DMAEA), a tertiary amine-containing acrylic monomer, exhibited radical chain transfer tendency toward itself, which is undesirable in controlled radical polymerization processes. We employed a higher [RAFT] : [Initiator] ratio of 20 : 1 to minimize the impact of the chain transfer reactions and yielded high molecular weight poly[sty-b-(nBA-co-DMAEA)-b-sty] with relatively narrow PDIs. The presence of the tertiary amine functionality, as well as their quaternized derivatives, in the central blocks of the triblock copolymers afforded them tunable polarity toward polar guest molecules, such as ionic liquids. Gravimetric measurements determined the swelling capacity of the triblock copolymers for EMIm TfO, an ionic liquid. DSC and DMA results revealed the impact of the ionic liquid on the thermal and thermomechanical properties of the triblock copolymers, respectively. Composite membranes of DMAEA-derived triblock copolymers and EMIm TfO exhibited desirable plateau moduli of ~ 100 MPa, and were hence fabricated into electromechanical transducers. RAFT synthesized poly(sty-b-nBA-b-sty) triblock copolymer phase separates into long-range ordered morphologies in the solid state due to the incompatibility between the poly(nBA) phases and the poly(sty) phases. The incorporation of DMAEA into the central acrylic blocks enabled subsequent quaternization of the tertiary amines into sulfobetaine functionalities. Both DSC and DMA results suggested that the electrostatic interactions in the low Tg central blocks of poly(sty-b-nBA-b-sty) enhanced block copolymer phase separation. SAXS results indicated that the presence of the sulfobetaine functionalities in acrylate phases increased electron density differences between the phases, and led to better defined scattering profiles. TEM results confirmed that the block copolymers of designed molecular weights exhibited lamellar morphologies, and the lamellar spacing increased with the amount of electrostatic interactions for the zwitterionic triblock copolymers. Acrylic radicals are more susceptible to radical chain transfer than their styrenic and methacrylic counterparts. Controlled radical polymerization processes (e.g. RAFT, ATRP and NMP) mediate the reactivity of the acrylic radical and enable the synthesis of well-defined linear poly(alkyl acrylate)s. However, functional groups such as tertiary amine and imidazole on acrylic monomers interfere with the controlled radical polymerization of functional acrylates. Model CFR and RAFT polymerization of nBA in the presence of triethylamine and N-methyl imidazole revealed the interference of the functional group on the polymerization of acrylate. Various RAFT agents, RAFT agent to initiator ratios, degree of polymerization and monomer feed concentrations were screened with an imidazole-containing acrylate for optimized RAFT polymerization conditions. The results suggest that the controlled radical polymerization of functional acrylates, such as 2-(dimethylamino)ethyl acrylate and 4-((3-(1H-imidazole-1-yl)propanoyl)oxy)-butyl acrylate (ImPBA), remained challenging. / Ph. D.

electromechanical transducer

zwitterion

functional acrylate

ionic liquid

morphology

RAFT polymerization

block copolymer

Bridging Mesoscale Phenomena and Macroscopic Properties in Block Copolymers Containing Ionic Interactions and Hydrogen Bonding

Chen, Mingtao

08 August 2018

Anionic polymerization and controlled radical polymerization enabled the synthesis of novel block copolymers with non-covalent interactions (electrostatic interaction and/or hydrogen bonding) to examine the relationships between mesoscale phenomenon and macroscopic physical properties. Non-covalent interactions offer extra intra- and inter-molecular interactions to achieve stimuli-responsive materials in various applications, such as artificial muscles, thermoplastic elastomers, and reversible biomacromolecule binding. The relationship between non-covalent interaction promoted mesoscale phenomenon (such as morphology) and consequent macroscopic physical properties is the key to optimize material design and improve end-use performance for emerging applications. Pendant hydrogen bonding in ABA block copolymers promoted microphase separation and delayed the order-disorder transition, resulting in tunable morphologies (through composition changes) and extended rubbery plateaus. Reversible addition-fragmentation chain transfer (RAFT) polymerization afforded a facile synthesis of ABA triblock copolymers with hydrogen bonding (urea sites) and electrostatic interactions (pyridinium groups). Pyridine groups facilitated hydrogen bonding through a preorganization effect, leading to highly ordered, long-range lamellar morphology and a significant increase of flow temperature (Tf) 80 °C above the hard block Tg. After quaternization of pyridine groups, electrostatic interaction, as a second physical crosslinking mechanism, disrupted ordered lamellar morphology and decreased Tf. Yet, extra physical crosslinking from electrostatic interactions pertained ordered hydrogen bonding at high temperature and exhibited improved stress-relaxation properties. Both conventional free radical polymerization and RAFT polymerization generated a library of poly(ionic liquid) (PIL) homopolymers with imidazolium groups as bond charge moieties. A long chain alkyl spacer between imidazolium groups and the polymer backbones ensured a low glass transition temperature (Tg), which is beneficial to ion conductivity. Four different counter anions enabled readily tunable Tgs all below room temperature and showed promising ion conductivities as high as 2.45 × 10⁻⁵ S/cm at 30 °C. For the first time, the influence of counter anions on radical polymerization kinetics was observed and investigated thoroughly using in situ FTIR, NMR diffusometry, and simulation. Monomer diffusion and aggregation barely contributed to the kinetic differences, and the Marcus theory was applied to explain the polymerization kinetic differences which showed promising simulation results. RAFT polymerization readily prepared AB diblock, ABA triblock and (AB)3 3-arm diblock copolymers using the ionic liquid (IL) monomers discussed above and deuterated/hydrogenated styrene. We demonstrated the first example of in situ morphology studies during an actuation process, and counter anions with varied electrostatic interactions showed different mesoscale mechanisms, which accounted for macroscopic actuation. The long chain alkyl spacer between imidazolium groups and polymer backbones decoupled ion dynamics and structural relaxation. For the first time, composition changes of block copolymers achieved tunable viscoelastic properties without altering ion conductivity, which provided an ideal example for actuation materials, solid electrolytes, and ion exchange membranes. / Ph. D. / My research focuses on the synthesis of novel soft materials with a special interest in responsive polymers. The incorporation of responsive chemistry, such as hydrogen bonding and ionic interactions, enables soft materials with complex responsive behavior were achieved. Polymers with ion pairs promise great potential as solid-state electrolytes (which transfer ions to generate current) to eliminate potential fire hazard in batteries, which has been an arising concern for modern cellphone and electric car industry. The introduction of strong dipoles into polymers allows the fabrication of actuators, which convert electric signals to physical movement. Under applied voltage, polymers bend within seconds while holding physical loads. Actuator studies in polymers paves the way towards artificial muscles as well as soft robotics. Temperature responsive hydrogen bonding in polymers offers drastically different viscoelastic properties at different temperature and serves as the key mechanism in holt-melt adhesives, controlled drug release, and high performance materials.

poly(ionic liquid)s

electrostatic interactions

block copolymers

hydrogen bonding

RAFT polymerization

anionic polymerization

Actuation and Charge Transport Modeling of Ionic Liquid-Ionic Polymer Transducers

Davidson, Jacob Daniel

15 March 2010

Ionic polymer transducers (IPTs) are soft sensors and actuators which operate through a coupling of micro-scale chemical, electrical, and mechanical mechanisms. The use of 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. This work aims to further the understanding of the dominant mechanisms of IPT actuation and how these are affected when an ionic liquid is used as solvent. A micromechanical model of IPT actuation is developed following a previous approach given by Nemat-Nasser, and the dominant relationships in actuation are demonstrated through an analysis of electrostatic cluster interactions. The elastic modulus of Nafion as a function of ionic liquid uptake is measured using uniaxial tension tests and modeled in a micromechanical framework, showing an excellent fit to the data. Charge transport is modeled by considering both the cation and anion of the ionic liquid as mobile charge carriers, a phenomenon which is unique to ionic liquid IPTs as compared to their water-based counterparts. Numerical simulations are performed using the finite element method, and a modified theory of ion transport is discussed which can be extended to accurately describe electrochemical migration of ionic liquid ions at higher applied voltages. The results presented here demonstrate the dominant mechanisms of IPT actuation and identify those unique to ionic liquid IPTs, giving directions for future research and transducer development. / Master of Science

Nafion

ionic polymer-metal composite

Ionic polymer transducer

electroactive polymer

ionic polymer

ionic liquid

The ionic liquid ethyltri-n-butylphosphonium tosylate as solvent for the acid-catalysed hetero-Michael reaction.

Karodia, Nazira, Liu, Xihan, Ludley, Petra, Pletsas, Dimitrios, Stevenson, Grace

January 2006

No / A new and convenient method for the acid-catalysed Michael addition reactions of alcohols, thiols and amines to methyl vinyl ketone has been developed using the ionic liquid ethyltri-n-butylphosphonium tosylate. The reaction conditions are mild and obviate the need for toxic and expensive Lewis acid catalysts, offering advantages over more commonly used systems.

Methyl vinyl ketone

Michael reaction

Solutions de cellulose et matériaux hybrides/composites à base de liquides ioniques et solvants alcalins / Cellulose solutions and hybrid/composite materials from ionic liquid and alkaline solvents

Liu, Weiqing

18 January 2013

La cellulose, composé organique le plus courant et polysaccharide le plus abondant sur Terre, est une ressource naturelle très importante. Les initiatives pour remplacer totalement ou partiellement les polymères pétrochimiques conventionnels avec des bio-polymères à base de cellulose ont donc attiré l'intérêt des chercheurs ces dernières décennies, non seulement parce que la cellulose est renouvelable et biodégradable, mais aussi en raison de ses propriétés intéressantes telles que la biocompatibilité et la stabilité chimique. De plus, les propriétés de cellulose peuvent être encore améliorées par des procédés chimiques, des modifications physiques ou en préparant des composites avec des charges fonctionnelles.Les études concernant d'étudier plusieurs aspects fondamentaux comme la dissolution de la cellulose afin de produire des matériaux et le test de nouveaux concepts autour de la modification de surface ou des revêtements, à l'échelle du laboratoire. Nous présentons dans ce manuscrit nos travaux concernant la caractérisation de solutions de cellulose dans deux solvants différents (hydroxyde de sodium aqueux et un liquide ionique) et la préparation de deux nouveaux types de matériaux à base de cellulose (un matériau hybride cellulose-amidon et un composite cellulose-noir de carbone), qui sont tous les deux préparés à partir de ces solutions de cellulose. / Cellulose, as the most common organic compounds on Earth, and also the most abundant polysaccharide, is definitely an important natural resource. With the initiatives of replacing (partially) the conventional petrochemical polymers by bio-based polymers, cellulose has regained the researchers' interests in the last few decades, not only because it is renewable and biodegradable, but also due to interesting properties such as biocompatibility and chemical stability. Additionaly, cellulose properties can be further enhanced by chemical/physical modification or making composites with functional fillers.This study was to investigate several fundamental scientific aspects as cellulose dissolution, making cellulose-based materials from solutions, and test of new concepts as surface modification or coating at laboratory scale. We studied and will present in this manuscript the characterization and properties of both cellulose solutions in different solvents (aqueous sodium hydroxide and ionic liquid) and two types of cellulose-based hybrid materials (one with starch and the other with carbon black), which were all prepared from dissolved cellulose.

Cellulose

Amidon

Liquide ionique

Hydroxyde de sodium

Noir de carbone

Matériaux hybrides

Cellulose

Starch

Ionic liquid

Sodium hydroxide

Carbon black

Hybrid materials

Utilisation de nanotubes de carbone pour la préparation de catalyseurs confinés / Use of carbon nanotubes for the preparation of confined catalysts

Nguyen, Tuyet Trang

23 July 2013

Ce travail de thèse est d’utilisation de nanotubes de carbon (NTCs) comme support pour confiner de nanoparticules métalliques ou comme gabarit pour le confinement de la phase active. Le chapitre I présente l’état actuel des connaissances sur les effets de confinement dans les NTCs. Le chapitre II décrit la préparation et la caractérisation de catalyseurs métalliques à base de ruthénium, de cobalt et de palladium, confinées à l’intérieur de NTCs. Dans ce cadre, l’étude de l’influence de différents paramètres tels que les conditions opératoires, la nature du métal ou du précurseur, ou un prétraitement du support NTC, sur la sélectivité du confinement est présentée. Le chapitre III comporte deux parties : l’une est consacrée à l’utilisation de NTCs comme gabarit pour la synthèse de nanotubes de silice (NTSs, en présence ou non de particules de ruthénium confinées dans leur canal). L’autre partie concerne l’immobilisation du catalyseur (complexe métallique de rhodium) dans une phase liquide ionique comme phase catalytique active avant le remplissage dans les NTCs. Le chapitre IV concerne l’application tous les systèmes catalytiques à base de catalyseurs confinés à l’intérieur de nanotubes dans les réactions d’hydrogénation du cinnamaldéhyde et du 1-hexène. L’effet de confinement sur les performances catalytiques est présenté. / This thesis is refer of carbon nanotubes (CNTs) as a support to confine metal nanoparticles or as a template for the confinement of the active phase. Chapter I give a comprehensive review of the state of knowledge on the effects of confinement in CNTs. Chapter II describes the preparation and characterization of the metals (ruthenium, palladium and cobalt) confined inside CNTs catalysts. In this context, the study of the influence of various parameters such as operating conditions, nature of the metal or precursor or nanosupport pretreatment, on the selectivity of confinement is presented. Chapter III consists of two parts: one is devoted to the using of CNTs as a template for the synthesis of silica nanotubes (SNTs in the presence or absence of ruthenium particles confined in their channel). The other part is the immobilization of the catalyst (rhodium metallic complex) in an ionic liquid phase as active catalytic phase before filling in CNTs. Chapter IV concernes the application all catalyst-filled CNTs systems in the hydrogenation of cinnamaldehyde and 1-hexene reaction. The confinement effect on the catalytic performance is presented.

Nanotubes de carbone multi-parois

Nanoparticules métalliques

Confinement

Catalyseur

Liquide ionique

Multi-walled carbon nanotubes

Metallic nanoparticles

Confinement

Catalyst

Ionic liquid