Ruthenium(II)-Catalyzed C-H Arylations of Arenes

Hubrich, Jonathan

30 September 2016

No description available.

540

ruthenium

arylation

C-H activation

bioactive compounds

biaryl

Chemie  (PPN62138352X)

Fonctionnalisation de liaisons C(sp3)-H non activées catalysées par le palladium / Palladium catalyzed functionalization of nonactivated C(sp3)-H bonds

Renaudat, Alice

04 October 2010

La fonctionnalisation de liaisons C-H réputées peu réactives ouvre de nouvelles perspectives en synthèse organique. Une stratégie efficace consiste en l’utilisation d’un métal de transition. Les travaux de thèse présentés dans ce mémoire s’inscrivent dans ce contexte. Dans un premier temps, la réaction étudiée, catalysée par le palladium, vise à étendre une méthodologie mise au point au laboratoire, permettant la synthèse de benzocyclobutènes par activation intramoléculaire de liaisons C(sp3)-H de groupements méthyles benzyliques, à des composés non aromatiques. Plusieurs substrats ont été synthétisés pour être ensuite placés dans les conditions de la réaction d’activation C(sp3)-H, dans le but d’induire la formation du cyclobutène ou du cyclobutane désiré. Le processus n’est pas sélectif et de nombreux produits secondaires sont obtenus par des réactions péricyliques ou par des réarrangements suite à l’ouverture du palladacycle intermédiaire. Dans un deuxième temps, nos travaux ont permis de mettre à jour une nouvelle réaction de fonctionnalisation C(sp3)-H, catalysée par le palladium permettant l’arylation d’esters en position β par un mécanisme original. Les investigations portent sur l’optimisation complète de cette réaction, la compréhension du mécanisme et le développement d’une version énantiosélective prometteuse. Le mécanisme de cette réaction, confirmé par des calculs DFT réalisés en collaboration avec C. Kefalidis et E. Clot, se rapproche formellement de celui observé en α-arylation, puisqu’il repose sur la formation d’un énolate de palladium. La stratégie mise au point permet le couplage, dans des conditions douces, d’esters simples et commerciaux avec des halogénures d’aryles contenant un groupement électronégatif en position ortho, donnant ainsi accès à des intermédiaires de synthèse intéressants tels qu’un analogue de la phénylalanine ou des composés fluorés. / The direct functionalization of C-H bonds represents an atom- and step-economical alternative to more traditional synthetic methods based on functional group transformation, which often require multi-step sequences. In particular, transition-metal catalysis has recently emerged as a powerful tool to functionalize otherwise unreactive C-H bonds. In this context, we first investigated the extension of a methodology that has been developed in our laboratory for the synthesis of benzocyclobutenes via C(sp3)-H activation, to non aromatic compounds. Substrates have been synthesized in order to be evaluated in the reaction to form cyclobutenes or cyclobutanes. The process was not selective and several by-products were formed via pericylic reactions or rearrangements of the intermediate palladacycle. Our research has also focused on a conceptually new palladium catalyzed β-C-H arylation of carboxylic esters method. The investigations consisted of a complete optimization of the reaction conditions, an evaluation of the scope and elucidation of the mechanism. It was found that this type of [bêta]-arylation is mechanistically related to α-arylation because it involves the formation of a palladium-enolate. Computational studies (DFT calculations, C. Kefalidis et E. Clot) confirmed the proposed mechanism. Our strategy allowed a mild and efficient intermolecular arylation reaction from aryl halides bearing an ortho electronegative group, giving rise to a range of synthetically useful functionalized carboxylic esters such as phenylalanine analogues and new fluorinated building blocks.

Fonctionnalisation C-H

Activation C-H

Cyclobutènes

Cyclobutanes

Catalyse organométallique

Formation de liaisons C-C

Palladium

Ester

Énolate

Α-arylation

Β-arylation

Β-H élimination

C-H functionalization

C-H activation

Cyclobutenes

Cyclobutanes

Organometallic catalysis

C-C bond formation

Palladium

Ester

Enolate

Α-arylation

Β-arylation

Β-H elimination

La catalyse au palladium pour l'obtention d'indoles fonctionnalisés : application à une synthèse monotope d'indoloquinones par catalyse hétérogène

Batail, Nelly

08 October 2010

Depuis le début des années 1990, l'hétéroannélation de Larock est apparue comme une méthode de choix pour obtenir, en une seule étape, des indoles 2,3-disubstitués. Cependant, bien qu'efficace, certains inconvénients restaient associés à cette stratégie comme l'utilisation d'un système catalytique homogène associé à l'emploi de sels. Pour cette raison, nous avons développé une nouvelle méthodologie sans sels ou additifs par catalyse hétérogène. Différents catalyseurs commerciaux ou faciles d'accès (Pd/C ou [Pd]/NaY) ainsi que de nouveaux complexes au palladium immobilisés sur SBA-15 ont été testés. De façon surprenante, ces nouvelles conditions ont permis une activation de 2-bromoanilines et ce, sans l'emploi d'additifs. Une autre méthode d'obtention de ces hétérocycles a émergé ces dernières années et se pose comme une alternative aux couplages traditionnels : l'arylation d'indoles. Malgré de nombreuses améliorations, aucun travail ne décrivait une procédure permettant une arylation complémentaire C2 ou C3 d'indoles libres avec un système catalytique unique. Nous avons développé un tel système, basé sur une pallado-catalyse dans l'eau. Cette stratégie permet d'atteindre des sélectivités C2/C3 ou C3/C2 élevées avec de bons rendements isolés par un simple contrôle du couple {base/halogénure d'aryle}.Enfin, dans le cadre de nos travaux visant la synthèse par catalyse hétérogène de produits à haute valeur ajoutée, nous avons initié des études sur l'obtention de pyrroloiminoquinones. La méthode consistant en une catalyse hétérogène monotope en seulement deux grandes étapes devrait permettre un accès rapide à de nombreux dérivés bioactifs isolés d'organismes marins.

[CHIM:OTHE] Chemical Sciences/Other

Indole

Palladium

Catalyse homogène et hétérogène

Matériaux mésostructurés

Arylation

CH-activation

Oxydation

Pyrroloiminoquinones

Méthodologies de synthèse diastéréosélectives d'ortho-1,2-diaminoalkylphénols, vers la synthèse totale des bioxalomycines - réaction tandem de N-arylation / Heck compétitive.

Rondot, Christophe

28 November 2005

Ces travaux de thèse portent sur la mise au point de méthodologies de synthèses diastéréosélectives inter- et intramoléculaires d'ortho-1,2-diaminoalkylphénols, motif présent dans la structure des bioxalomycines, cyanocyclines et naphthyridinomycine. Stratégies intermoléculaires: une nouvelle réaction de Mannich phénolique diastéréodivergente à trois composants, catalysée par des acides de Lewis doux de type triflate d'ytterbium, a été mise au point pour la synthèse d' ortho-1,2-diaminoalkylphénols chiraux, à partir d'un phénol, d'un N,N-dibenzyl-alpha-amino aldéhyde et d'une amine. Stratégies intramoléculaires: une nouvelle réaction de cyclisation intramoléculaire de bis-trichloroacétimidates de 2-amino-1,3-diols chiraux, permet l'accès au motif trans-5-amino-4-aryl-5,6-dihydro-4H-1,3-oxazine, par un mécanisme SN1. L'application de cette méthodologie sur un substrat plus avancé de type tétrahydroisoquinoléine a permis d'obtenir une dihydrooxazine avec le motif diamine vicinale de configuration syn présente dans le squelette des bioxalomycines. A partir de la cristallisation d'un composé macropalladacycle peptidique bis-sigma-arylpalladium impliqué dans une réaction tandem de N-arylation intramoléculaire / activation C-H / couplage Caryl-Caryl développée au laboratoire pour la synthèse de diazaphénanthrènes-benzodiazépinones, des conditions divergentes ont été développées, basées sur la compétitivité d'une réaction de Heck. Cette nouvelle méthode ouvre la voie au motif 3-(N-méthylphényl)acrylate benzodiazépinone.

Méthodologies

Diastéréosélectif

Diamines vicinales

Mannich

Trichloroacétimidate

Bioxalomycine

N-Arylation

Heck

Palladium(II)-Catalyzed Oxidative Cyclization Strategies : Selective Formation of New C-C and C-N Bonds

Persson, Andreas K. Å.

January 2012

The main focus of this thesis has been directed towards preparation and oxidative carbocyclization of en-, dien- and aza-enallenes. In the first part of this thesis, a stereoselective oxidative carbocyclization of dienallenes was realized. By employing cheap and readily available palladium trifluoroacetate we were able to efficiently cyclize a variety of dienallenes into hydroxylated carbocycles in high yield and high selectivity. This oxidative process was compatible with two different reoxidation protocols: one relying on p-benzoquinone (BQ) as the oxidant and the other employing molecular oxygen as the oxidant. In the second part of the thesis the carbocyclization methodology was extended to include carbocyclization of aza-enallenes. This was achieved in two distinct steps. First, a copper-catalyzed coupling of allylic sulfonamides with bromoallenes was developed, giving access to the corresponding aza-enallenes. Subjecting these substrates to catalytic amounts of palladium acetate, along with BQ as the oxidant, rendered N-heterocycles in good yield. The reactivity of these N-heterocycles towards activated dienophiles was later exploited in a tandem (aerobic) oxidative carbocyclization/Diels-Alder reaction. The third topic involves efficient oxidative arylative/borylative carbocyclization of enallenes. These reactions, catalyzed by palladium acetate, relies on transmetallation of a (σ-alkyl)palladium(II) intermediate with diboranes or arylboronic acids. With this novel methodology we were able to obtain an array of arylated or borylated carbocycles, as single diastereomers, in high yield. Finally, we developed a palladium(II)-catalyzed cyclization of allylic carbamates. This mild, operationally simple, and scalable catalytic reaction opens up access to an array of oxazolidinones in high yield and excellent diastereoselectivity. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 6: Manuscript.</p>

Carbocyclization

Palladium Catalysis

Oxidation

Cyclization

Enallenes

Aza-Enallenes

Dienallenes

Allenylation

Oxazolidinones

Biomimetic

Arylation

Borylation

Transmetallation

Part 1: Transition Metal Catalyzed Functionalization of Aromatic C-H Bonds / Part 2: New Methods in Enantioselective Synthesis

Schipper, Derek

25 July 2011

Part 1: Transition-metal-catalyzed direct transformations of aromatic C-H bonds are emerging as valuable tools in organic synthesis. These reactions are attractive because of they allow for inherently efficient construction of organic building blocks by minimizing the pre-activation of substrates. Of these processes, direct arylation has recently received much attention due to the importance of the biaryl core in medicinal and materials chemistry. Also, alkyne hydroarylation has garnered interest because it allows for the atom-economical synthesis of functionalized alkenes directly from simple arenes and alkynes. Described in this thesis are number of advancements in these areas. First, palladium catalyzed direct arylation of azine N-oxides using synthetically important aryl triflates is described. Interesting reactivity of aryl triflates compared to aryl bromides was uncovered and exploited in the synthesis of a compound that exhibits antimalarial and antimicrobial activity. Also reported is the efficient, direct arylation enabled (formal) synthesis of six thiophene based organic electronic materials in high yields using simple starting materials. Additionally, the site-selective direct arylation of both sp2 and sp3 sites on azine N-oxide substrates is described. The arylation reactions are carried out in either a divergent manner or a sequential manner and is applied to the synthesis of the natural products, Papaverine and Crykonisine. Mechanistic investigations point towards the intimate involvement of the base in the mechanism of these reactions. Next, the rhodium(III)-catalyzed hydroarylation of internal alkynes is described. Good yields are obtained for a variety of alkynes and arenes with excellent regioselectivity for unsymmetrically substituted alkynes. Mechanistic investigations suggest that this reaction proceeds through arene metalation with the cationic rhodium catalyst, which enables challenging intermolecular reactivity. Part 2: Access to single enantiomer compounds is a fundamental goal in organic chemistry and despite remarkable advances in enantioselective synthesis, their preparation remains a challenge. Kinetic resolution of racemic products is an important method to access enantioenriched compounds, especially when alternative methods are scarce. Described in this thesis is the resolution of tertiary and secondary alcohols, which arise from ketone and aldehyde aldol additions. The method is technically simple, easily scalable, and provides tertiary and secondary alcohols in high enantiomeric ratios. A rationale for the unique reactivity/selectivity associated with (1S,2R)-N-methylephedrine in the resolution is proposed. Organocatalysis is a rapidly developing, powerful field for the construction of enantioenriched organic molecules. Described here is a complimentary class of organocatalysis using simple aldehydes as temporary tethers to perform challenging formally intermolecular reactions at room temperature. This strategy allows for the enantioselective, intermolecular cope-type hydroamination of allylic amines with hydroxyl amines. Also, interesting catalytic reactivity for dichloromethane is revealed.

direct arylation

enantioselective

hydroarylation

kinetic resolution

C-H functionalization

organocatalysis

palladium

rhodium

Palladium-Catalyzed C(sp2)-C(sp3) Bond Formation

Rousseaux, Sophie

16 July 2012

Palladium-catalyzed reactions for carbon-carbon bond formation have had a significant impact on the field of organic chemistry in recent decades. Illustrative is the 2010 Nobel Prize, awarded for “palladium-catalyzed cross couplings in organic synthesis”, and the numerous applications of these transformations in industrial settings. This thesis describes recent developments in C(sp2)-C(sp3) bond formation, focusing on alkane arylation reactions and arylative dearomatization transformations. In the first part, our contributions to the development of intramolecular C(sp3)-H arylation reactions from aryl chlorides are described (Chapter 2). The use of catalytic quantities of pivalic acid was found to be crucial to observe the desired reactivity. The reactions are highly chemoselective for arylation at primary aliphatic C-H bonds. Theoretical calculations revealed that C-H bond cleavage is facilitated by the formation of an agostic interaction between the palladium centre and a geminal C-H bond. In the following section, the development of an alkane arylation reaction adjacent to amides and sulfonamides is presented (Chapter 3). The mechanism of C(sp3)-H bond cleavage in alkane arylation reactions is also addressed through an in-depth experimental and theoretical mechanistic study. The isolation and characterization of an intermediate in the catalytic cycle, the evaluation of the roles of both carbonate and pivalate bases in reaction mechanism as well as kinetic studies are reported. Our serendipitous discovery of an arylation reaction at cyclopropane methylene C-H bonds is discussed in Chapter 4. Reaction conditions for the conversion of cyclopropylanilines to quinolines/tetrahydroquinolines via one-pot palladium(0)-catalyzed C(sp3)-H arylation with subsequent oxidation/reduction are described. Initial studies are also presented, which suggest that this transformation is mechanistically unique from other Pd catalyzed cyclopropane ring-opening reactions. Preliminary investigations towards the development of an asymmetric alkane arylation reaction are highlighted in Chapter 5. Both chiral carboxylic acid additives and phosphine ligands have been examined in this context. While high yields and enantiomeric excesses were never observed, encouraging results have been obtained and are supported by recent reports from other research groups. Finally, in part two, the use of Pd(0)-catalysis for the intramolecular arylative dearomatization of phenols is presented (Chapter 7). These reactions generate spirocyclohexadienones bearing all-carbon quaternary centres in good to excellent yields. The nature of the base, although not well understood, appears to be crucial for this transformation. Preliminary results in the development of an enantioselective variant of this transformation demonstrate the influence of catalyst activation on levels of enantiomeric excess.

palladium catalysis

C-H functionalization

alkane arylation

dearomatization

asymmetric catalysis

mechanistic studies

Utilisation de ligands ferrocéniques associés au palladium pour l'arylation directe d'hétéroaromatiques par des chlorures ou bromures d'aryle

Roy, David

25 October 2012

Au cours de ce travail de thèse, nous nous sommes intéressés à l'arylation directe d'hétéroaromatiques par des halogénures d'aryle catalysée par des complexes du palladium. Comparativement aux autres types de couplages croisés tels que les réactions de Suzuki, Negishi ou Stille, l'arylation directe est plus attractive d'un point de vue économique et écologique puisqu'elle nécessite moins d'étapes et produit moins de déchets. Nous avons démontré que des bromures d'aryle ortho- et di-ortho-substitués pouvaient donner accès aux produits de couplages avec de très bons rendements même avec des charges très faibles en catalyseur, de l'ordre de 0,05 mol%. De nombreux composés impossibles à former auparavant ont pu être synthétisés. Nous avons ensuite démontré que des chlorures d'aryle pouvaient réagir en positions C2 ou C5 de furanes, thiophènes, pyrroles et thiazoles, par l'utilisation de seulement 0,5 mol% de Pd(OAc)2 associé à un ligand ferrocénique. Enfin, nous avons démontré qu'en présence d'un autre type de catalyseur Pd-ligand ferrocénique, dans des conditions similaires, des chlorures d'aryle pouvaient aussi être couplés en positions C3 ou C4 d'isoxazoles, d'indoles, de benzofuranes ou de pyrazoles.

[CHIM:CATA] Chemical Sciences/Catalysis

Arylation

Catalyse homogène

Ligands

Ferrocène

Catalyseurs au palladium

Part 1: Transition Metal Catalyzed Functionalization of Aromatic C-H Bonds / Part 2: New Methods in Enantioselective Synthesis

Schipper, Derek

25 July 2011

Part 1: Transition-metal-catalyzed direct transformations of aromatic C-H bonds are emerging as valuable tools in organic synthesis. These reactions are attractive because of they allow for inherently efficient construction of organic building blocks by minimizing the pre-activation of substrates. Of these processes, direct arylation has recently received much attention due to the importance of the biaryl core in medicinal and materials chemistry. Also, alkyne hydroarylation has garnered interest because it allows for the atom-economical synthesis of functionalized alkenes directly from simple arenes and alkynes. Described in this thesis are number of advancements in these areas. First, palladium catalyzed direct arylation of azine N-oxides using synthetically important aryl triflates is described. Interesting reactivity of aryl triflates compared to aryl bromides was uncovered and exploited in the synthesis of a compound that exhibits antimalarial and antimicrobial activity. Also reported is the efficient, direct arylation enabled (formal) synthesis of six thiophene based organic electronic materials in high yields using simple starting materials. Additionally, the site-selective direct arylation of both sp2 and sp3 sites on azine N-oxide substrates is described. The arylation reactions are carried out in either a divergent manner or a sequential manner and is applied to the synthesis of the natural products, Papaverine and Crykonisine. Mechanistic investigations point towards the intimate involvement of the base in the mechanism of these reactions. Next, the rhodium(III)-catalyzed hydroarylation of internal alkynes is described. Good yields are obtained for a variety of alkynes and arenes with excellent regioselectivity for unsymmetrically substituted alkynes. Mechanistic investigations suggest that this reaction proceeds through arene metalation with the cationic rhodium catalyst, which enables challenging intermolecular reactivity. Part 2: Access to single enantiomer compounds is a fundamental goal in organic chemistry and despite remarkable advances in enantioselective synthesis, their preparation remains a challenge. Kinetic resolution of racemic products is an important method to access enantioenriched compounds, especially when alternative methods are scarce. Described in this thesis is the resolution of tertiary and secondary alcohols, which arise from ketone and aldehyde aldol additions. The method is technically simple, easily scalable, and provides tertiary and secondary alcohols in high enantiomeric ratios. A rationale for the unique reactivity/selectivity associated with (1S,2R)-N-methylephedrine in the resolution is proposed. Organocatalysis is a rapidly developing, powerful field for the construction of enantioenriched organic molecules. Described here is a complimentary class of organocatalysis using simple aldehydes as temporary tethers to perform challenging formally intermolecular reactions at room temperature. This strategy allows for the enantioselective, intermolecular cope-type hydroamination of allylic amines with hydroxyl amines. Also, interesting catalytic reactivity for dichloromethane is revealed.

direct arylation

enantioselective

hydroarylation

kinetic resolution

C-H functionalization

organocatalysis

palladium

rhodium

Development and Applications of Hypervalent Iodine Compounds : Powerful Arylation and Oxidation Reagents

Jalalian, Nazli

January 2012

The first part of this thesis describes the efficient synthesis of several hypervalent iodine(III) compounds. Electron-rich diaryliodonium salts have been synthesized in a one-pot procedure, employing mCPBA as the oxidant. Both symmetric and unsymmetric diaryliodonium tosylates can be isolated in high yields. An in situ anion exchange also enables the synthesis of previously unobtainable diaryliodonium triflates. A large-scale protocol for the synthesis of a derivative of Koser’s reagent, that is an isolable intermediate in the diaryliodonium tosylate synthesis, is furthermore described. The large-scale synthesis is performed in neat TFE, which can be recovered and recycled. This is very desirable from an environmental point of view. One of the few described syntheses of enantiopure diaryliodonium salts is discussed. Three different enantiopure diaryliodonium salts bearing electron-rich substituents are synthesized in moderate to high yields. The synthesis of these three salts shows the challenge in the preparation of electron-rich substituted unsymmetric salts. The second part of the thesis describes the application of both symmetric and unsymmetric diaryliodonium salts in organic synthesis. A metal-free efficient and fast method for the synthesis of diaryl ethers from diaryliodonium salts has been developed. The substrate scope is wide as both the phenol and the diaryliodonium salt can be varied. Products such as halogenated ethers, ortho-substituted ethers and bulky ethers, that are difficult to obtain with metal-catalyzed procedures, are readily prepared. The mild protocol allows arylation of racemization-prone a-amino acid derivatives without loss of enantiomeric excess. A chemoselectivity investigation was conducted, in which unsymmetric diaryliodonium salts were employed in the arylation of three different nucleophiles in order to understand the different factors that influence which aryl moiety that is transferred to the nucleophile. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Accepted. Paper 5: Submitted. Paper 6: Manuscript.</p>

hypervalent iodine compounds

diaryliodonium salts

oxidation

Koser's reagent

arylation

phenols

diaryl ethers

chemoselectivity