Étude mécanistique computationnelle des réactions d’amination catalysées par des dimères de rhodium

Azek, Emna

01 1900

Catalytic amination reactions are a powerful tool in organic synthesis. They aim to introduce nitrogen atom to alkane, alkene or thioether moieties, giving rise to amine products that have various medical and industrial applications. The Lebel group has developed catalytic amination reactions in the presence of rhodium dimers using N-sulfonyloxycarbamates as nitrene precursors. In the presence of a base, N-sulfonyloxycarbamates presumably afforded rhodium nitrenes which underwent C-H insertions, C=C additions or reactions with the sulfur atom of thioethers resulting in acyclic and cyclic carbamates, aziridines and sulfilimines respectively. In addition, good diastereoselectivities were observed in the presence of a chiral N-sulfonyloxycarbamate reagent and a chiral rhodium dimer for all three reactions. In this dissertation, we are interested in the mechanistic aspects of these amination reactions. Given the absence of experimental proofs of in-situ generated rhodium nitrene species, playing the role of the amination agent, nor of its precomplex, the rhodium nitrenoid, the different amination reactions mechanisms remain uncertain. Our approach is based on the scan of the potential energy surfaces of different mechanistic paths, for each of the amination reactions, well established on the experimental level, by resorting to the Functional Theory of Density (DFT). The Ernzerhof research group is expert on the development of exchange-correlation functionals, therefore relevant strict criteria have been considered when choosing and validating the theoretical model used during the mechanistic studies. The correlation exchange functional developed by Perdew-Burke-Ernzerhof (PBE) was established as the best to study reactions involving rhodium dimers where the electronic correlation is strong. We studied the formation and reactivity of rhodium nitrene species considering their two lower energy spin states. Singlet rhodium nitrenes appeared to be the most reactive intermediates for the C-H amination reaction. In addition, singlet rhodium nitrenes were shown responsible for the formation of secondary products such as carbonyls and primary carbamates derived from the corresponding N-mesyloxycarbamates. In sharp contrast, in the aziridination reaction, both singlet and triplet rhodium nitrene species acted as aminating agents in a process involving an intersystem spin crossover. To further rationalize the asymmetric induction of catalytic aziridination reactions, we have undertaken the calculation of the diastereoselectivity ratios in the presence of the chiral catalyst Rh2[(S)-nttl]4. An exhaustive study was performed and it revealed that the asymmetric induction was due to a reactive conformation of rhodium nitrene species in which the ligand adopts C4 symmetry. Up to now, no mechanistic study involving DFT calculations have been reported in the literature for the amination of thioethers, no matter what catalytic system is used. To study catalytic sulfimidation reactions, we calculated the different mechanistic paths of rhodium catalyzed thioanisole imidation with and without DMAP and bis(DMAP)CH2Cl2 additives. The study showed a 'classical' insertion mechanism of rhodium nitrene species into the thioether in absence of bis(DMAP)CH2Cl2. In the presence of the latter, the mechanism diverged to a thioether insertion/salt (bis(DMAP)CH2Cl-OMs) elimination reaction where the rhodium nitrenoid complex was, henceforth, the imidation reagent. / Les réactions d’amination catalytiques sont un outil très efficace en synthèse organique. Elles consistent à introduire un azote sur différents composés organiques, permettant de synthétiser des produits aminés qui peuvent être utilisés pour différentes applications médicales et industrielles. Le groupe de recherche du Pr Lebel a développé des réactions d’amination faisant appel aux dimères de rhodium comme catalyseurs et en utilisant les Nsulfonyloxycarbamates, comme précurseurs de nitrènes métalliques. En effet, en présence d’une base, les N-sulfonyloxycarbamates forment possiblement un intermédiaire de type nitrène de rhodium qui peuvent s’insérer dans un lien C-H, s’additionner sur un lien C=C ou réagir avec un atome de soufre d’un thioéther. On peut ainsi préparer des carbamates cycliques et acycliques, des aziridines et des sulfilimines respectivement. Dans le cas où les réactions d’amination sont catalysées par des dimères de rhodium chiraux, on obtient de bonnes diastéréosélectivités en présence d’un réactif N-sulfonyloxycarbamate chiral. Dans cette dissertation, nous nous sommes intéressés aux aspects mécanistiques de ces réactions d’amination. À défaut de preuves expérimentales solides pour prouver la génération in-situ des espèces nitrènes de rhodium, lesquelles sont les agents d’amination clés, ni de celle du pré-complexe, nitrénoïde de rhodium, des incertitudes subsistaient toujours concernant les mécanismes des différentes réactions d’amination. Notre approche se base sur l’étude des surfaces d’énergies potentielles de différents chemins mécanistiques possibles pour chacune des réactions d’amination, bien établie sur le plan expérimental, en faisant recours à la Théorie des Fonctionnelles de la Densité (DFT). Le groupe de recherche du Pr Ernzerhof est expert dans le développement des fonctionnelles d’échange-corrélation. Pour ce, des critères strictes et pertinents ont été pris en compte lors du choix et de la validation du modèle théorique utilisé dans ces études mécanistiques. La fonctionnelle d’échange corrélation développée par Perdew–Burke– Ernzerhof (PBE) s’est révélé être la meilleure pour décrire ces systèmes réactionnels faisant intervenir les dimères de rhodium dont la corrélation électronique est forte. À l’aide de cette fonctionnelle pure, nous avons étudié la formation et la réactivité des espèces nitrènes de rhodium en fonction de leurs deux états de spin de plus basse énergie. Les nitrènes de rhodium singulet se sont révélés être les intermédiaires les plus réactifs dans l`amination de liens C-H. De plus, les nitrènes de rhodium à l’état singulet sont responsables de la formation des produits secondaires tels que les carbonyles et les carbamates primaires dérivés des Nmésyloxycarbamates correspondants. Dans la réaction d’aziridination, les espèces nitrènes de rhodium à l’état singulet et triplet peuvent toutes les deux agir comme agents d'amination et les processus font intervenir un croisement intersystème de spin. Afin de rationaliser l’induction asymétrique des réactions d’aziridination catalytiques, nous avons entrepris le calcul des ratios de diastéréosélectivités en présence du catalyseur chiral Rh2[(S)-nttl]4. L’étude exhaustive de cette réaction a permis de déterminer que l’induction asymétrique provient d’une conformation réactive de l’espèce nitrène de rhodium de symétrie C4. Aucune étude mécanistique s’appuyant sur la chimie computationnelle n’a été rapportée dans la littérature pour la réaction d’amination de thioéthers et ce peu importe le système catalytique. Afin d’étudier les réactions de sulfimidation catalytiques, nous avons calculé les différents chemins mécanistiques de l’imidation du thioanisole catalysée par un complexe de rhodium avec et sans les additifs DMAP et bis(DMAP)CH2Cl2. L’étude montre que le mécanisme procède via une insertion ‘classique’ des espèces nitrènes de rhodium dans le thioéther en absence de bis(DMAP)CH2Cl2. En présence de ce dernier, le mécanisme diverge vers une réaction d’insertion du thioéther/élimination d’un sel (bis(DMAP)CH2Cl-OMs) où le complexe nitrénoïde de rhodium devient, désormais, l’agent d’imidation.

Dimères de rhodium

N-Mésyloxycarbamates

DFT

Amination de Liens C-H

PBE

Aziridination Catalytique

MECP

Dimères de Rhodium Chiraux

Espèces Nitrènes de Rhodium

Complexe Nitrénoïde

Sulfimidation

Bis(DMAP)CH2Cl2

Rhodium Dimers

N-Mesyloxycarbamates

Chiral Rhodium Dimer

Rhodium Nitrene Species

Nitrenoid Complex

C-H Bond Amination

Catalytic Aziridination

Multi-States Reactivity

Diastereoselective Aziridination

Novel approach to biscarbazole alkaloids via Ullmann coupling – synthesis of murrastifoline-A and bismurrayafoline-A

Börger, Carsten, Kataeva, Olga, Knölker, Hans-Joachim

January 2012

Unprecedented Ullmann couplings of murrayafoline-A with either 6-bromo- or 4-bromocarbazole derivatives provide highly efficient synthetic routes to the biscarbazole alkaloids murrastifoline-A (6 steps, 66% overall yield) and bismurrayafoline-A (6 steps, 28% overall yield). / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.

info:eu-repo/classification/ddc/540

ddc:540

The Investigation of Reactions of Atomic Metal Anions with Small Hydrocarbons and Alcohols in the Gas Phase

Halvachizadeh, Jaleh

21 February 2014

Hydrocarbons are an abundant resource of carbon and hydrogen. For example, fossil can be used to produce useful organic compounds. However hydrocarbons seem to be inert. Thus, the activation of the C-H bond is a popular research area. Metals play the main role in most catalysts that convert hydrocarbons to starting materials in industry. The study of metals is important because the properties of the metal core greatly influences the reactivity of a catalyst.1 The study of the chemistry of metals in the gas phase provides valuable information about the properties of metals. This information can be expanded to the chemistry of metals in the condensed phase. Furthermore, it is often both more accurate and more manageable to study the profile of a reaction in the gas phase than in the condensed phase.2,3 There are many studies about metal cations in the gas phase due to ease of their production. However metals have low electronegativity, limiting the study of gas phase metal anions. Recently, a simple and efficient method to generate atomic metal anions was developed at the University of Ottawa in Dr. Mayer's research laboratory.4-6 Atomic metal anions of Fe-, Co-, Cu-, Ag-, Cs- and K- were generated in an electrospray ionization (ESI) source of a mass spectrometer (MS). In this thesis study generated metal anions were reacted with small hydrocarbons of pentane, 1-pentene, 2-pentene and 1-pentyne to investigate the role of different metal anions in the activation of the C-H bond. Also metal anions were reacted with small alcohols of 1-butanol, 2-butanol and 2-methyl-2-propanol to compare the results. Metal anions showed a variety of reactions with these hydrocarbons and alcohols. Fe- was the only metal anion to show the electron transfer reaction, indicating that alcohols are more electronegative than Fe- and less electronegative than other metal anions. Fe-, Co- and Ag- showed the complex formation reaction. All metal anions showed the deprotonation reaction. A deprotonation reaction follows the harpoon mechanism, the long range proton abstraction7, and depends on the gas phase acidity of fragments. The most informative reaction observed was the dehydrogenation reaction because a metal-containing fragment is observed as a product in the spectrum of this reaction. The observation of a metal-containing fragment in the spectrum is significant because it emphasizes the important role that metal anions play in this reaction. This suggests that a dehydrogenation reaction involves metal insertion into a C-H bond. Among the transition metal anions, it was observed that Fe- and Cu- are more reactive than Co- and Ag- with regards to the dehydrogenation reaction, probably because Fe- and Cu- have a greater hydrogen affinity than Co- and Ag- that facilitates the hydrogen abstraction reaction. Another reason could be that Fe- and Cu- have a greater gas phase acidity that leads to a more stable intermediate in the course of the reaction. The results of this thesis study revealed that Cs- and K- could not abstract H from these substrates, probably due to the absence of occupied d orbitals that would facilitate insertion into a C-H bond. Some metal anions not only can insert into a C-H bond of alcohols but also can insert into a C-O bond of alcohols to form metal hydroxide anions. Alcohols are more reactive than hydrocarbons with regards to reactions with metal anions because they contain a functional group. This thesis study shows that some atomic metal anions are able to activate the C-H bond and abstract two hydrogens to form a double bond in hydrocarbons. It is probable that the electronic configuration, gas phase acidity and hydrogen affinity of the metal anions governs their reactivity.

Metal anions

Mass spectrometry

Metal dihydride anion

Metal hydride anion

Metal hydroxide anion

Metal insertion mechanism

Activation of C-H bond

Bisdehydrogenation

Collision cell

CID

Dehydrogenation

Deprotonation

ESI

Enthalpy

Gas phase

Gas phase acidity

Dissociation of deprotonated alcohol

Hydrogen affinity

Reactions in gas phase

Reactions of metal anions

Spontaneous dissociation in gas phase

Triple quadrupole

The Investigation of Reactions of Atomic Metal Anions with Small Hydrocarbons and Alcohols in the Gas Phase

Halvachizadeh, Jaleh

January 2014

Hydrocarbons are an abundant resource of carbon and hydrogen. For example, fossil can be used to produce useful organic compounds. However hydrocarbons seem to be inert. Thus, the activation of the C-H bond is a popular research area. Metals play the main role in most catalysts that convert hydrocarbons to starting materials in industry. The study of metals is important because the properties of the metal core greatly influences the reactivity of a catalyst.1 The study of the chemistry of metals in the gas phase provides valuable information about the properties of metals. This information can be expanded to the chemistry of metals in the condensed phase. Furthermore, it is often both more accurate and more manageable to study the profile of a reaction in the gas phase than in the condensed phase.2,3 There are many studies about metal cations in the gas phase due to ease of their production. However metals have low electronegativity, limiting the study of gas phase metal anions. Recently, a simple and efficient method to generate atomic metal anions was developed at the University of Ottawa in Dr. Mayer's research laboratory.4-6 Atomic metal anions of Fe-, Co-, Cu-, Ag-, Cs- and K- were generated in an electrospray ionization (ESI) source of a mass spectrometer (MS). In this thesis study generated metal anions were reacted with small hydrocarbons of pentane, 1-pentene, 2-pentene and 1-pentyne to investigate the role of different metal anions in the activation of the C-H bond. Also metal anions were reacted with small alcohols of 1-butanol, 2-butanol and 2-methyl-2-propanol to compare the results. Metal anions showed a variety of reactions with these hydrocarbons and alcohols. Fe- was the only metal anion to show the electron transfer reaction, indicating that alcohols are more electronegative than Fe- and less electronegative than other metal anions. Fe-, Co- and Ag- showed the complex formation reaction. All metal anions showed the deprotonation reaction. A deprotonation reaction follows the harpoon mechanism, the long range proton abstraction7, and depends on the gas phase acidity of fragments. The most informative reaction observed was the dehydrogenation reaction because a metal-containing fragment is observed as a product in the spectrum of this reaction. The observation of a metal-containing fragment in the spectrum is significant because it emphasizes the important role that metal anions play in this reaction. This suggests that a dehydrogenation reaction involves metal insertion into a C-H bond. Among the transition metal anions, it was observed that Fe- and Cu- are more reactive than Co- and Ag- with regards to the dehydrogenation reaction, probably because Fe- and Cu- have a greater hydrogen affinity than Co- and Ag- that facilitates the hydrogen abstraction reaction. Another reason could be that Fe- and Cu- have a greater gas phase acidity that leads to a more stable intermediate in the course of the reaction. The results of this thesis study revealed that Cs- and K- could not abstract H from these substrates, probably due to the absence of occupied d orbitals that would facilitate insertion into a C-H bond. Some metal anions not only can insert into a C-H bond of alcohols but also can insert into a C-O bond of alcohols to form metal hydroxide anions. Alcohols are more reactive than hydrocarbons with regards to reactions with metal anions because they contain a functional group. This thesis study shows that some atomic metal anions are able to activate the C-H bond and abstract two hydrogens to form a double bond in hydrocarbons. It is probable that the electronic configuration, gas phase acidity and hydrogen affinity of the metal anions governs their reactivity.

Metal anions

Mass spectrometry

Metal dihydride anion

Metal hydride anion

Metal hydroxide anion

Metal insertion mechanism

Activation of C-H bond

Bisdehydrogenation

Collision cell

CID

Dehydrogenation

Deprotonation

ESI

Enthalpy

Gas phase

Gas phase acidity

Dissociation of deprotonated alcohol

Hydrogen affinity

Reactions in gas phase

Reactions of metal anions

Spontaneous dissociation in gas phase

Triple quadrupole