Captage et valorisation du CO2 par voie chimique : application à la synthèse de carbonates cycliques à partir d’époxydes / Capture and valorisation of CO2 by using a chemical way : application to the synthesis of cyclic carbonates from epoxides

Contreras Moreno, Viviana

09 December 2016

L'utilisation du CO2 comme matière première pour la synthèse de produits à haute valeur ajoutée, comme les carbonates cycliques, est aujourd'hui l'une des alternatives proposées dans la réduction des émissions gazeuses à effet de serre. Ce travail de thèse vise à comprendre et concevoir un procédé de valorisation de CO2 à partir de la modélisation de la thermodynamique et des cinétiques de transfert de matière et de réactions, qui sont engendrées dans la synthèse de carbonates cycliques à partir des époxydes et un composé hétérocyclique comme catalyseur. Grâce à ce nouveau système, les carbonates cycliques très utilisés dans l'industrie de polymères, cosmétique ou pharmaceutique, sont obtenus avec de bons rendements, dans des conditions opératoires douces et en absence de solvants. Des propriétés thermodynamiques telles que la solubilité et la constante de Henry ont été estimées pour les systèmes binaires CO2/époxyde. L'étude du transfert de matière sans ou avec réactions a permis de déterminer respectivement le coefficient de transfert de matière en phase liquide et le régime de la réaction. Des suivis cinétiques ont été réalisés afin de proposer un modèle cinétique capable de représenter la réaction et d'estimer les paramètres cinétiques. Ces derniers ont été utilisés pour la conception préliminaire et la simulation du procédé de production du carbonate d' épichlorohydrine sur Aspen Hysys. / Today, the utilisation of CO2 as raw material for the synthesis of high-value added products like cyclic carbonates, is one of the alternatives used for reducing greenhouse gases. This thesis aims to understand and design a CO2 valorisation process by modelling the thermodynamic and the mass transfer/reaction kinetics generated during the cyclic carbonates synthesis from CO2, epoxides and a heterocyclic compound as catalyst. By using this new catalytic system, cyclic carbonates, which are used in the polymeric, pharmaceutic or cosmetic industry, can be produced with good yields at low temperatures and pressures and without any solvent. Thermodynamic properties as solubility and Henry's law constant have been estimated for CO2/epoxide binary systems. Mass transfer occurring without and with reaction has been studied in order to determine respectively the liquid volumetric mass transfer coefficient and the reaction regime. A kinetic study has been performed to propose a model able to represent the reaction and to estimate the kinetic parameters. This information has been used in the design and the simulation of the production process of epichlorohydrin carbonate on Aspen Hysys.

Constante de Henry

Valorisation du CO2

Henry's law constant

CO2 valorisation process

Cyclic carbonates

Mass transfer/reaction kinetics

Epoxide

Thermodynamic properties

Solubility

Chemical kinetics

Carbon dioxide

Ring formation (Chemistry)

Lagrangian Coherent Structures in Vortex Ring Formation

Harter, Braxton Nicholas

January 2019

No description available.

Aerospace Engineering

Fluid Dynamics

vortex ring

vortex ring formation

fluid dynamics

Lagrangian coherent structures

LCS

finite-time Lyapunov exponent

FTLE

vortex identification

Target identification and validation studies in chemical biology & Synthesis of medium-sized ring containing compounds via oxidative fragmentation

Liu, Gu

January 2010

Part I of this thesis describes the development of bioactive small molecules of relevance to the study of the apicomlexan parasite Toxoplasma gondii into useful chemical tools. The research includes the target identification and validation studies, using both chemical and biological methods. Chapter 1 provides an overview of chemical genetics with a particular emphasis on methods for the identification of the protein targets of bioactive small molecules. The concept of biochemical protein target identification techniques was introduced with a detailed discussion of interesting applications from the literature. Chapter 2 focuses on the development of a tetrahydro-β-carboline based lead molecule into a chemical tool through target identification studies. The structure activity relationship (SAR) data associated with this core structure, the design of a chemical inducer of dimerisation (CID) and the synthesis of this CID are discussed in detail. Chapter 3 described work done to identify the potential protein target(s) of Conoidin A. Experiments to assess whether Conoidin A can inhibit a proposed target in vitro are also included. Further optimisation of this structural class to develop more potent inhibitors is discussed in the second part of this chapter. Part II of this thesis describes the development of methods for the synthesis of medium-sized ring containing compounds using oxidative fragmentation and rearrangement strategies. Chapter 5 provides an overview of the existing oxidative fragmentation methodology, with an emphasis on the use of oxidative fragmentation reactions for the synthesis of medium-sized ring systems (8-11 ring atoms). Chapter 6 focuses on using the established oxidative fragmentation method in the oxizino carbazolone system to investigate the diasteroselectivity of this reaction. Possible mechanisms for this transformation are investigated and discussed using both chemical and computational methods. An interesting rearrangement reaction has also been observed during this study. Chapter 7 focuses on developing an asymmetric oxidative fragmentation method, for use in the diazabenz[e]aceathrylenes system. Asymmetric oxidative fragmentation reactions using [Ru(pybox)(pydic)] catalysts are discussed. Attempts to optimise the enantiomeric excesses of the reaction by varying reaction conditions and substituents in the substrate are also included.

572

Exploring Structure and Reactions : Computational Studies on Three-Membered Rings, Metal-Boron Multiple Bonds and Biradical Reactions

Mallick, Dibyendu

January 2013

The utility of computational study lies not only in rationalizing a chemical phenomenon but also in its predictive value. Broadly, the scope of my research work includes understanding of the structure and bonding of molecules as well as reaction mechanisms using computational techniques. Here I will discuss three research problems where computational results successfully rationalize and predict the experimental outcome. Firstly, we will describe the electronic structure and bonding of all the possible cyclic isomers of B2AlHnm (where n =3D 3 =96 6 and m =3D -2 to 1) = which is isoelectronic to the cyclopropenyl cation.1 A comparative study among all the isomers of homocyclic and heterocyclic three- membered boron and aluminum hydrides has also been done to understand the factors that differentiate their hydride chemistry. We will also discuss about two different approaches to stabilize neutral planar B3R3 rings. In a mechanistic study, we have designed a a priori system which can undergo two competing biradical generating processes, namely the Myers-Saito (MS) and Garratt-Braverman (GB) Cyclizations.2,3 We will present a detailed mechanistic study of both the reactions, which indicates the preference of the GB cyclization over MS cyclization. The theoretical prediction is in agreement with the experimental findings. We will also describe a conformational constraint-based strategy to switch the selectivity from GB to MS/Schmittel pathway.4 In another study, we will talk about a DFT study to illustrate the effect of the a) solvent, b) ancillary ligand, (L) c) leaving group, (Hal) and d) metal (M) on the equilibrium between metal boryl (1) and borylene (2) complexes (Scheme 1).5,6

Biradical Reactions

Ring Chemistry

Cyclic Isomers - Electronic Structure

Cyclization (Chemistry)

Ring Formation (Chemistry)

Metal-Borone Multiple Bonds

Cyclic Isomers - Bonding

Three-membered Boron Hydrides

Three-membered Aluminium Hydrides

Neutral Planar Rings

Three-Membered Ring Chemistry

Molecules - Structure and Bonding

Myers-Saito Cyclization

Garratt-Braverman Cyclization

Myers-Saito Cyclization

Inorganic Chemistry