Applications of reversible and sustainable amine-based chemistries: carbon dioxide capture, in situ amine protection and nanoparticle synthesis

Ethier, Amy Lynn

12 January 2015

A multidisciplinary approach has been applied to the development of sustainable technologies for three industrially relevant projects. Reversible ionic liquids are novel carbon dioxide capture solvents. These non-aqueous silylamines efficiently capture carbon dioxide through chemical and physical absorption and release carbon dioxide with minimal addition of heat. The development of these capture agents aims to eliminate the need for a co-solvent, while minimizing energy loss and achieving solvent recyclability. Also presented is the use of carbon dioxide for amine protection during chemical syntheses. Amine protection is widely used in almost all sectors of chemical and pharmaceutical industries. The use of carbon dioxide as a reversible protecting group reduces solvent waste during protection and deprotection and improves the atom economy of existing processes. Sustainable chemistry has also been applied to the use of reversible ionic liquids as switchable surfactants for nanoparticle synthesis. The reversible ionic liquid system offers two significant advantages toward a more efficient synthesis and deposition of nanoparticles in that an additional surfactant is not required, and due to the reversible nature of the ionic liquids, a facile and waste-reduced deposition method exists.

Carbon dioxide capture

Amine protection

Nanoparticle synthesis

Reversible ionic Liquids

Organic solvents for catalysis and organic reactions

Blasucci, Vittoria Madonna

15 October 2009

We develop, characterize, and apply novel solvent systems for enhanced separations. The field of separations has long been explored by chemical engineers. One way to optimize separations is through solvent manipulation. Through molecular design, smart solvents can be created which accomplish this task. Smart solvents undergo step or gradual changes in properties when activated by a stimulus. These property changes enable unique chemistry and separations. This thesis explores the application of two different types of smart solvents: switchable and tunable solvents. First we show that a neutral liquid can react with carbon dioxide and be switched into an ionic liquid which can then be thermally reversed back to its molecular form. Each form that the solvent takes has unique properties that can be structurally tuned to span a large range. We also look at a tunable solvent system based on polyethylene glycol/dioxane that is initially homogeneous, but induced to a heterogeneous system through carbon dioxide pressurization. Finally, we look at the advantage of using carbon dioxide as a co-solvent that is easily removed post-reaction for the grafting of silanes onto polyolefin backbones.

Smart solvents

Reversible ionic liquids

Alternative solvents

Tunable solvents

Polymer grafting

Amines

Solvents

Organic compounds

Designing switchable solvents for sustainable process development

Hart, Ryan J.

01 December 2010

Novel solvents utilizing a reversible CO₂ induced property switch are presented. The synthetic procedure for designing the solvents is discussed, along with detailed characterizations on both solvent forms to serve as a tool for optimal solvent identification as well as future solvent design. A reflectance infrared spectroscopic technique is introduced to allow for the examination of CO₂ and solvent composition under high pressures and temperatures. The magnitude of solvent property changes afforded by this "switch" creates opportunities for sustainable processing; discussed are the application to coupling reactions and separations, and CO₂ capture. The switchable solvents are shown to serve as effective media for running reactions, with the switch providing facile recovery of products and catalysts for solvent recycling. Lastly, the switch itself is exploited to provide for the separation of CO₂ from low partial pressure feed streams, and structure-property relationships were successfully used to develop next generation materials with enhanced absorption capacities. The viscosity of the solvents, as a function of temperature and composition, is also presented.

Reversible ionic liquids

CO₂ capture

Reactions

Separations

Solvents

Ionic solutions

Sustainable engineering

Sustainable chemistry solutions for industrial challenges: mechanisms of PVC degradation and stabilization; reversible ionic liquids for CO₂ capture; efficient Suzuki coupling of basic, nitrogen containing substrates

Rumple, Amber C.

08 June 2015

The thermal degradation of polyvinyl chloride (PVC) is a significant processing challenge which can lead to deleterious mechanical and optical properties in a wide range of products. Synergetic studies on PVC model compounds and blends of bulk PVC provide unique insights into the thermal degradation and stabilization pathways in the presence of common additives. Model PVC compounds were selected to replicate specific defects (e.g., allylic, vicinal and tertiary) and tacticity (i.e., utilizing stereochemistry to investigate tacticity) commonly found in PVC. Model studies were conducted neat (solvent-free) with metal carboxylates. Experimental results highlight that the allylic and tertiary defects are more reactive than pristine PVC and isotactic sites are more reactive than their syndiotactic counterparts. Zinc stearate was found to act not in the role of substituent, but as a Lewis acid by facilitating dehydrochlorination of labile chlorides. This prevents the accumulation of hydrogen chloride and autocatalytic chain unzipping. In contrast, calcium stearate delayed the formation of zinc chloride, a much stronger Lewis acid than zinc stearate, through an ion exchange process to form calcium chloride. Thermal weight loss studies using blends of bulk PVC proved critical in transferring mechanistic insights into the context of a polymeric matrix. Post-combustion carbon capture has traditionally involved the use of aqueous alkanol amine solutions. The regeneration of such systems, however, can be costly and energy intensive. We have developed an alternative system utilizing silylated alkylamines to reversibly capture CO2 under near ambient conditions. The silyl amines developed capture CO2 through chemical reaction to form reversible ionic liquids (RevIL). RevILs utilize no added water and are tunable by molecular design allowing us to influence industrially relevant carbon capture properties such as viscosity, temperature of reversal, and enthalpy of regeneration, while maximizing overall CO2 capture capacity. We demonstrate a strong structure-property relationship among the silyl amines where minor structural modifications lead to significant changes in the bulk properties of the RevIL. Amine containing substrates are important building blocks for a variety of biological and pharmaceutical compounds. However, application of the otherwise versatile Suzuki reaction to these substrates has proved challenging due to either ligation of the amine to the palladium or to electronic effects slowing the oxidative addition step. Conventional methods to overcome these challenges involve protection-deprotection strategies or the use of designer ligands to facilitate reaction. We have shown that application of CO2 pressure and adjusting the water content of the reaction system facilitate the Suzuki coupling of 4-amino-2-halopyridines in high yield with the simple Pd(TPP)2Cl2 catalyst. The protocol was expanded to 2-halopyridines. The results of these investigations will be discussed.

Sustainable

PVC

Suzuki

pH

Sustainable chemistry

CO₂ capture

Reversible ionic liquids

CO₂

PVC stabilization

PVC degradation

Two approaches to green chemistry in industrially driven processes: aluminum tert-butoxide as a rate enhancing Meerwein-Ponndorf-Verley reduction catalyst applied to the technological transfer from batch to continuous flow and structural modifications of functionalized trialkylsilylamines as energy efficient carbon dioxide capture solvents

Flack, Kyle M.

14 June 2012

Green chemistry principles have been applied to the enhancement of two industrial chemistry problems. An industrially used reaction to form alcohols from aldehydes and ketones, the Meerwein-Ponndorf-Verley reduction, was improved by introducing a new catalyst Al(OtBu)₃. Due to the lower state of aggregation of this catalyst versus the conventional Al(OiPr)₃ catalyst, reduction rates were found to be faster in both pure iPrOH and mixed solvent systems for three model compounds: benzaldehyde, acetophenone, and a complex, chiral ketone, (S)-CMK. This allowed for the successful implementation of two important milestones; lowering the amount of catalyst needed necessary to complete the reactions (an economic benefit and lower waste) and the conversion from traditional batch reactions to continuous flow (a processing benefit) whereby reactions can be scaled-out rather than scaled-up. Another industrially important field of research that was focused on was CO₂ capture. High energy demands from current CO₂ capture methods such as aqueous amine solvents, specifically from coal-fired power plant flue gas, led to the development of non-aqueous reversible ionic liquids based on silylated amines. Structural modifications of the substitution around the silicon atom, the length of the alkyl chain bonding the silicon and amine, branching along the alkyl backbone, and investigating secondary and primary amines within this class of silylated amines were completed. These amines were reacted with CO₂ and the CO₂ capacity, the ionic liquid viscosity, reversal temperature and reaction enthalpy were all considered as a function of structure. In all cases the capacity was found to be not only greater than that of monethanolamine, an industrial standard, but higher than theoretical predictions through the formation of carbamic acid. Viscosity, reversal temperature, and reaction enthalpy were all found to be tunable through structure. These modifications gave significant insight into the necessary direction for optimization of these solvents as energy-efficient replacements of current CO₂ capture technology.

Silylated amines

Continuous flow

MPV reduction

Reversible ionic liquids

Carbon capture

Carbon sequestration

Chemistry, Organic

Silanes in sustainable synthesis: applications in polymer grafting, carbon dioxide capture, and gold nanoparticle synthesis

Nixon, Emily Cummings

02 October 2012

Vinyltrialkoxysilanes are grafted onto polyolefins via a radical mechanism; in a subsequent step, the pendant alkoxysilanes hydrolyze and condense upon exposure to water, resulting formation of crosslinks. Straight chain hydrocarbons were used as model compounds to investigate the regioselectivity of vinyltrimethoxysilane grafting. To stabilize the water-sensitive grafted products, the methoxy groups were substituted using phenyllithium. It was found that this reaction must be carried out for a minimum of three days to ensure full substitution. The grafted products were then separated on a weight basis using semi-preparative HPLC. Analysis of the di-grafted fraction using edited HSQC and HSQC-TOCSY NMR showed that radical propagation occurs via 1,4- and 1,5-intramolecular hydrogen shifts along the hydrocarbon backbone, resulting in multiple grafts per backbone. Post-combustion carbon capture targets CO₂ emissions from large point sources for capture and sequestration. A new class of potential carbon capture agents known as reversible ionic liquids (RevILs) has been synthesized and evaluated in terms of potential performance parameters (e.g. CO₂ capacity, viscosity, enthalpy of regeneration). These RevILs are silylated amines, which react with CO₂ to form a salt comprising an ammonium cation and a carbamate anion that is liquid at room temperature. Structural modifications of the basic silylamine skeleton result in drastic differences in the performance of the resulting RevIL. Systematic variation of the silylated amines allowed determination of a structure-property relationship, and continued iterations will allow development of an ideal candidate for scale-up. The properties and potential applications of gold nanoparticles (AuNP) are highly dependent on their size and shape. These properties are commonly controlled during liquid-phase synthesis through the use of capping agents, which must be removed following synthesis. Reverse micelles can also be used to control the morphology of AuNP during their synthesis. When RevILs are used in the formation of these reverse micelles, either as the disperse phase or as the surfactant, the built-in switch can be used to release the nanoparticles following their synthesis. This release on command could decrease the post-synthetic steps required to clean and purify AuNP prior to use. We have successfully synthesized AuNP using a number of different RevILs.

Green chemistry

Carbon dioxide capture

Crosslinked polyethylene

Gold nanoparticles

Reversible ionic liquids

Green solvents

Silanes

Carbon dioxide mitigation

Polymerization

Silane compounds

Silane

Elaboration de liquides ioniques (chiraux) réversibles et applications en catalyse organique et en glycochimie. Carbènes N-hétérocycliques chiraux : synthèse et application dans la réaction d'addition conjuguée / Elaboration of reversible (chiral) ionic liquids and applications in organic catalysis and in glycochemistry. Chiral N-heterocyclic carbenes : synthesis and application in the conjugate addition reaction

Bouchardy, Lucie

10 November 2016

Ce travail de thèse porte, dans un premier temps, sur le développement d'une nouvelle synthèse de liquides ioniques chiraux réversibles, en système mono-composant, à partir d'aminoacides naturels. La réversibilité a été démontrée par RMN, par analyse thermogravimétrique et par calorimétrie différentielle à balayage. Ces composés ont été testés comme catalyseurs organiques dans la réaction d’addition de Michael asymétrique. Des rendements modérés ont été obtenus. Les silylamines chirales, précurseurs des liquides ioniques chiraux réversibles, ont été évaluées dans la synthèse de Warfarine via une addition de Michael asymétrique. De bons rendements ont été obtenus. Toutefois, ces catalyseurs n'ont permis de conduire qu'à de faibles énantiosélectivités. L'utilisation de liquides ioniques réversibles comme groupements protecteurs temporaires en glycochimie, pour la synthèse de disaccharides, a été mise en œuvre. Dans un second temps, de nouveaux sels d'imidazolinium chiraux précurseurs de NHCs ont été synthétisés, à partir de l'acide (S)-pyroglutamique en vue de leur application dans la réaction d'addition conjuguée de cétones α, β-insaturées catalysée au cuivre avec des réactifs de Grignard. Les excès énantiomériques sont modestes mais de bons résultats en termes d’activité catalytique et de régiosélectivité ont été obtenus. / At first, this work deals with the synthesis of a novel class of single-component reversible chiral ionic liquids derived from natural aminoacids. Reversibility was demonstrated by NMR, thermogravimetric analysis and differential scanning calorimetry. These compounds were tested as organocatalysts in an asymmetric Michael addition leading to the formation of expected product in moderate yields. Chiral silylamines, precursors to reversible ionic liquids were also evaluated in the synthesis of Warfarin through an asymmetric Michael addition. Good yields were obtained. However, these catalysts have resulted in only low enantioselectivity. Moreover, the use of reversible ionic liquid as a temporary protecting group in glycochemistry, for the synthesis of disaccharides was also implemented. Secondly, some new chiral imidazolinium salts, precursors to NHCs, were synthesized from (S)-pyroglutamic acid, for copper-catalyzed conjugate addition of Grignard reagents to α,β-unsaturated ketones applications. The results have shown moderate enantioselectivity with very good catalytic activity and excellent regioselectivity.

NHC

Carbènes N-hétérocycliques

LICRev

Glycochimie

Liquides ioniques réversibles

Catalyse asymétrique

Aminoacides naturels

Acide (S)-pyroglutamique

NHC

N-heterocyclic carbenes

RevCILs

Glycochemistry

Reversible ionic liquids

Asymmetric catalysis

Natural aminoacids

(S)-pyroglutamic acid