Enantioselective hydrogenation using ruthenium complexes of tridentate ligands

Phillips, Scott D.

January 2011

This thesis describes the development of the [RuCl₂(P N N)L] catalytic system for asymmetric hydrogenation. It has been demonstrated that the current system is efficient in preparing a range of bulky chiral alcohols in good enantioselectivity, many of which are likely to be inaccessible using the more classic [RuCl₂(P P)N N)] system developed by Noyori and coworkers. It has been shown that the current system is tolerant of a range of substrate electronic effects as well as the presence of heteroaromatic functionality, thus showing its applicability in synthesis. This has been extended to prepare a number of bulky derivatives of synthetically important molecules. The demonstration of this is significant as in drug design, for example, studies that aim to extend lipophilicity or steric bulk make the ability to prepare alcohols across the full range of steric properties important. We have shown that chiral alcohols with adjacent gem-dimethyl groups can be prepared in high enantioselectivity and their conversion into other valuable molecules, such as chiral lactones has been demonstrated. Detailed mechanistic studies have been undertaken for the present system in order to aid rational design of new, more active and selective catalysts. A number of achiral variants of the original system have been prepared and the key features of ligand structure for efficient catalysis have been identified. This was accomplished by rigorous kinetic analysis of each complex, using specialist gas-uptake monitoring equipment. The key features of catalyst structure and optimal reaction conditions for efficient asymmetric hydrogenation have been identified. Our greater understanding of the present system allowed us to rationally design new catalysts of for enantioselective hydrogenation. Our aim was to be able to tune the catalyst structure to carry out hydrogenation of a greater variety of ketone substrate with high activity and selectivity. We have successfully prepared second generation catalysts that show enhanced enantioselectivity for a variety of substrates, many of which were problematic with the Noyori system.

541.39

The synthesis and application of bulky S-stereogenic and P- stereogenic chiral ligands

Doran, Seán

14 December 2012

This doctoral thesis was focused on the design and synthesis of novel chiral ligands for application in asymmetric catalysis. One of the best examples of asymmetric catalysis is the asymmetric hydrogenation reaction for its atom economy, ease of access to both S and R enantiomers and almost ultimate enantiomeric excess obtainable in a multitude of substrates. There has been much investigation into this reaction and there has been a plethora of chiral ligands designed which catalyze this reaction in high enantiomeric excess using metals such as rhodium, iridium and ruthenium. The vast majority of these ligands are diphosphines with their chirality lying either on the backbone of the ligand or on the coordinating phosphorus atom itself. In the beginning of this work investigation was undertook to explore the possibility of successfully employing a new type of ligand class in the asymmetric hydrogenation reaction, namely the N-phosphino sulfinamide or PNSO ligands. PNSO ligands had been successfully applied to the asymmetric Pauson-Khand reaction in the Riera group yielding cyclopentenone Pauson-Khand adducts in high yield and very high enantioselectivity. The family of PNSO ligands prepared in the Riera group was attractive because apart from the high yields and enantioselectivities obtained from the reactions in which they were used, they proved to be easily prepared in short syntheses from commercially available starting materials. It was believed if they could be successfully applied in asymmetric hydrogenation for their ease of preparation they would be an attractive alternative to the diphosphine ligand class. Unfortunately the first two PNSO-Rh complexes successfully prepared provided low enantioselectivities and difficulties were encountered while trying to prepare further analogues. After some time trying to achieve PNSO-Rh complex analogues unsuccessfully the direction of the project was shifted away from the N-phosphino sulfinamide ligand class in asymmetric hydrogenation. The MaxPhos ligand had recently been developed in the group and had proven highly promising. A study was demanded of its substrate scope as applied in rhodium catalyzed asymmetric hydrogenation. Substrates already described in the literature were prepared and the asymmetric hydrogenation of them catalyzed by the MaxPhos-Rh precatalyst was performed and conditions to do so were optimized. Of seven substrates prepared the MaxPhos-Rh proved to hydrogenate five of those with high enantioselectivity. The TOF of the MaxPhos rhodium catalyst applied in the hydrogenation of the Z-MAC substrate was examined by monitoring the flux of hydrogen and was calculated at 0.065 s-1. MaxPhos complexes of cobalt and palladium were prepared to form part of the investigation into widening the reaction scope of the ligand. [(MaxPhos)Co2(CO)4(C2H2)] proved to catalyze the Pauson-Khand reaction of norbornadiene and 1-hexyne with 24 % yield and 28 %, a noteworthy enantiomeric excess for the catalytic asymmetric Pauson-Khand reaction. Chalcogenated derivatives of MaxPhos were prepared. The diselenide was used to explore the electronic nature of the ligand. The MaxPhos-rhodium carbonyl stretching was examined. MaxPhos-BH3 was used to prepare mono-chalcogenated MaxPhos derivatives. They were applied also in asymmetric hydrogenation once complexed to rhodium but enantiomeric excess of no more than 21 % was obtained in the hydrogenation of the substrate Z-MAC. The aminophosphine, a chiral building block and key intermediate in the preparation of the MaxPhos ligand, was used in the attempt to prepare bulky chiral amidine ligands and although two such species were prepared they proved inapplicable in asymmetric catalysis. / Se desarrollaron los ligandos N-fosfino sulfinamida (PNSO) en el grupo de Riera para su aplicación en la reacción Pauson-Khand asimétrica. Se probaron que estos ligandos eran muy eficaces en esta reacción y daban rendimientos y enantioselectividades muy altos de los aductos Pauson-Khand. Probar la eficacia de estos ligandos PNSO en hidrogenación asimétrica formó parte de este trabajo. Se prepararon dos ligandos PNSO, se complejaron con rodio formando complejos neutros. Se protonaron los complejos neutros con ácido tetraflorobórico para formar los complejos catiónicos. Se usaron estos complejos de rodio- PNSO, tanto los complejos neutros como los catiónicos como catalizadores en la hidrogenación asimétrica del sustrato Z-MAC. Los complejos de rodio con el ligando PNSO substituido por el grupo tolilo en azufre no hidrogenaba el sustrato pero los complejos de rodio con el ligando PNSO dotado de tres grupos tert-butilos hidrogenaba el sustrato aunque con baja selectividad. Después de un tiempo intentando conseguir análogos de ligandos tipo PNSO sin éxito se cambió la dirección del proyecto. Se decidió centrarse en el ligando MaxPHOS el cual había sido desarrollado recientemente en el grupo Riera. El ligando MaxPHOS demostró gran eficacia en hidrogenación asimétrica con dos sustratos pero se deseaba un estudio mas amplio del potencial del ligando así que se sintetizaron siete sustratos y se probó el catalizador MaxPHOS en la hidrogenación asimétricas de esos sustratos. El catalizador MaxPHOS-Rh proporcionó excesos enantioméricos muy altos en cinco de los siete sustratos. Se hizo un estudio de las propiedades electrónicas del ligando MaxPHOS aprovechando los estudios de (31)P RMN y el MaxPHOS diselenuro lo cual se preparó anteriormente. También se estudió el “stretching” carbonilo del complejo MaxPHOS-Rh. Se demostró que el ligando MaxPHOS era menos rico en electronos que el ligando trichickenfootphos. Se prepararon complejos de MaxPHOS con paladio y cobalto para examinar la eficacia del ligando en reacciones mas allá de hidrogenación asimétrica como la reacción Pauson–Khand catalítica asimétrica. Se sintetizaron varios derivados del ligando MaxPHOS a partir de los intermedios clave en la preparación del ligando y se probaron en hidrogenación asimétrica proporcionando excesos enantioméricos bajos.

Catàlisi asimètrica

Enantioselective catalysis

Catálisis asimétrica

Lligands

Ligandos

Ligands

MaxPHOS

Hidrogenació

Hidrogenación

Hydrogenation

Rodi

Rodio

Rodium

Ciències Experimentals i Matemàtiques

547

Synthese und Charakterisierung neuer metall-organischer Gerüstverbindungen und deren Anwendung in der asymmetrischen Katalyse und Gasspeicherung

Gedrich, Kristina

16 February 2011

Ziel der durchgeführten Arbeiten war die Etablierung neuer Synthesestrategien zur Gewinnung chiraler metall-organischer Gerüstverbindungen (engl: Metal-Organic Frameworks, MOFs). Hierfür wurden drei verschiedene Ansätze verfolgt. Zunächst sollte die Einbringung einer chiralen Dicarbonsäure mit einem 2,2´-Spirobiindan-Gerüst in ein MOF-Netzwerk untersucht werden. Im Rahmen einer Kooperation wurden neue mit chiralen Oxazolidinonen substituierte 4,4´,4´´-Benzol-1,3,5-triyl-tribenzoesäuren H3ChirBTB-n (n = 1, 2) entwickelt, die ebenfalls zur Synthese neuer chiraler MOFs dienten. Die Modifizierung bekannter nicht-chiraler metall-organischer Gerüstverbindungen mit koordinativ ungesättigten Metallatomen durch Anbindung chiraler Amine stellte die dritte Synthesestrategie dar. Im Rahmen der letztgenannten Syntheseroute wurde für MIL-101 (MIL = Matérial Institut Lavoisier) eine sehr hohe katalytische Aktivität in der Cyanosilylierung von Benzaldehyd nachgewiesen. Die Umsetzung mit chiralen Aminen führte jedoch nicht zu einem enantioselektiven Katalysator. Im Gegensatz dazu konnten die ersten beiden Synthesewege zur Gewinnung neuer chiraler metall-organischer Gerüstverbindungen erfolgreich beschritten werden. Durch solvothermale Reaktion von (S)-2,2´-Spirobiindan-5,5´-dicarbonsäure ((S)-H2Spiro-BIDC) mit Zinknitrat in N,N-Dimethylformamid (DMF) wurde eine neue chirale metall-organische Gerüstverbindung namens DUT-7 (DUT = Dresden University of Technology) der Zusammensetzung Zn4O((S)-Spiro-BIDC)3 dargestellt. Neben einer unerwarteten, zweifach interpenetrierten Netzwerkstruktur mit hexagonalen Kanälen weist DUT-7 eine für MOFs bislang noch nicht beobachtete temperaturinduzierte, reversible Strukturänderung auf. Die zweite neue Strategie zur Gewinnung chiraler MOFs beinhaltete die Umsetzung der chiralen Tricarbonsäuren H3ChirBTB-n, die entweder (S)-4-iso-Propyl- (n = 1) oder (S)-4-Benzyl-1,3-Oxazolidin-2-on-Substituenten (n = 2) tragen. Die beiden gewonnenen Verbindungen Zn3(ChirBTB-1)2 und Zn3(ChirBTB-2)2 weisen trotz gleicher Zusammensetzung völlig unterschiedliche Kristallstrukturen auf. Beide Materialien wurden erfolgreich in der Mukaiyama-Aldol-Reaktion von Benz- bzw. 1-Naphthaldehyd mit 1-Methoxy-2-methyl-1-(trimethylsiloxy)propen eingesetzt, wobei ihre katalytische Aktivität mit verschiedenen Referenzkatalysatoren verglichen wurde. Die erzielten Enantiomerenüberschüsse (ee) liegen zwischen 6 und 16%. Auf der Suche nach neuen, für die Einbringung der ChirBTB-n-Liganden geeigneten MOF-Strukturen wurde auch die Umsetzung der reinen, nicht chiralen 4,4´,4´´-Benzol-1,3,5-triyl-tribenzoesäure (H3BTB) untersucht. Die Reaktion mit Nickelnitrat führte zur Bildung einer neuen hochporösen Verbindung namens DUT-9 mit der Zusammensetzung Ni5O2(BTB)2(DEF,DMF)4(H2O)4. DUT-9 weist neben den auf dem Gebiet der MOF-Forschung bislang unbekannten Ni5O2-Clustern eine noch nicht beschriebene dreidimensionale (3,6)-Netzwerktopologie auf. Das neue Material zeigt zudem exzellente Speicherkapazitäten für Wasserstoff, Methan und Kohlenstoffdioxid. / The present work aims on the search for new synthesis strategies towards chiral Metal-Organic Frameworks (MOFs). Three different approaches were pursued. Initially, the integration of a chiral dicarboxylic acid with a 2,2´-spirobiindane backbone into a MOF network was investigated. Within a cooperation, new 4,4´,4´´-benzene-1,3,5-triyl-tribenzoic acids H3ChirBTB-n (n = 1,2) with chiral oxazolidinone substituents were developed which were also used for the assembly of chiral MOFs. The third synthesis strategy involved the tethering of chiral amines to coordinatively unsaturated metal atoms of known non-chiral Metal-Organic Frameworks. Within the last-mentioned approach, the very high catalytic activity of MIL-101 (MIL = Matérial Institut Lavoisier) towards the cyanosilylation of benzaldehyde was demonstrated. Treatment with chiral amines did not lead to an enantioselective catalyst. In contrast, the first two synthesis strategies could be performed successfully. A new MOF named DUT-7 (DUT = Dresden University of Technology) with composition Zn4O((S)-Spiro-BIDC)3 was obtained by solvothermal reaction of (S)-2,2´-spirobiindane-5,5´-dicarboxylic acid ((S)-H2Spiro-BIDC) with zinc nitrate in N,N-dimethylformamide (DMF). Besides an unexpected, two-fold interpenetrated framework structure with hexagonal channels, DUT-7 shows a temperature induced, reversible structure transformation not yet observed. The other new strategy to obtain chiral Metal-Organic Frameworks involved the conversion of the chiral tricarboxylic acids H3ChirBTB-n bearing either a (S)-4-iso-propyl- (n = 1) or a (S)-4-benzyl-1,3-oxazolidin-2-one substituent (n = 2). Though having the same framework composition, the new compounds Zn3(ChirBTB-1)2 and Zn3(ChirBTB-2)2 exhibit completely different crystal structures. Both materials were tested in the Mukaiyama aldol reaction between benzaldehyde or 1-naphthaldehyde, respectively, and 1-methoxy-2-methyl-1-(trimethylsiloxy)propene and their catalytic activity was compared to different reference catalysts. Enantiomeric excess values (ee) between 6 and 16% were obtained. In search of new MOF structures being suitable for the integration of the ChirBTB-n linkers, the conversion of the pure, non chiral 4,4´,4´´-benzene-1,3,5-triyltribenzoic acid (H3BTB) was investigated. The reaction with nickel nitrate lead to the formation of a new, highly porous compound Ni5O2(BTB)2(DEF,DMF)4(H2O)4 named DUT-9. Besides Ni5O2 clusters which are a novelty in MOF chemistry, DUT-9 exhibits a three dimensional (3,6)-network topology not yet described. In addition, the new material shows excellent storage capacities for hydrogen, methane and carbon dioxide.

Metall-organische Gerüstverbindungen

MOFs

chiral

Gasspeicherung

enantioselektive Katalyse

Metal-Organic Frameworks

MOFs

chiral

gas storage

enantioselective catalysis

ddc:540

rvk:VE 7047

Enantioselective homogeneous catalysts for the synthesis of fluorinated organic compounds

Jones, Charlotte E. S.

January 2011

This thesis is divided into three main results chapters that reflect the path my research took. In the first results chapter, the first organocatalyst for the carbonyl-ene reaction was discovered and found to give high conversion using 1,3-bis(3,5-bis(trifluoromethyl)phenyl)thiourea. Various carbonyl and alkene precursors were examined in the ene reaction in both catalysed and uncatalysed reactions. It was found that ene reactions using fluoral and ethyl trifluoropyruvate give higher rates of reaction when compared to other carbonyl compounds. A novel enantiopure thiourea was synthesised and the ene reaction was catalysed enantioselectively to 33% e.e. In an attempt to catalyse the reaction to a further extent a new thiourea bonded to a P(=S)R2 group was developed. However, the intramolecular hydrogen bonding of this catalyst was thought to be so strong that this it did not catalyse the reaction. The synthesis of a chiral phosphoric acid was achieved but this was an unsuccessful catalyst in the ene reaction. Two component achiral thiourea and chiral acids were also examined in the ene and Mannich-type reaction. The new easily synthesised thiourea for this reaction has an interesting intermolecular hydrogen bonding coordination in the solid state. Asymmetric fluorination of ketoesters using palladium is a dynamic kinetic resolution. In the 2nd chapter cationic palladium complexes were synthesised and used to determine the optimum parameters for bidentate ligands in this reaction. Four carbon chain phosphines were found to give the highest conversion for this reaction among those ligands tested such as 1,4-bisdiphenylphosphinobutane (bite angle 99º). A new bis-phosphinous amide chiral ligand was developed with a bite angle of 96.7º. The dichloropalladium complex of this phosphine was isolated and structurally characterised. The use of the palladium complex in asymmetric fluorination was attempted however this was found to be unsuccessful. Mechanistic studies reveal that the formation of the desired cationic catalyst did not occur under conditions shown to work well for other palladium phosphine complexes. The ligand was investigated further in hydrogenation reactions. The phosphinous amide was protected as its borane and was used in the rhodium catalysed hydrogenation of alkenes to give high conversion and up to 93% e.e. The borane protected phosphinous amide was also found to catalyse the hydrogenation of acetophenone using copper complexes with up to 84% e.e for the hydrogenation of acetophenone, although conversion was quite low.

541.39

Syntéza a využití N-heterocyklických karbenových ligandů na bázi helicenů / Synthesis and application of helicene-based N-heterocyclic carbene ligands

Gay Sánchez, Isabel

January 2021

The aim of my PhD Thesis was to explore the potential of helically chiral N-heterocyclic carbene (NHC) ligands in asymmetric catalysis. Helicenes and helicene-like molecules are inherently chiral. Their application in this field has been rather limited. To date, only a few examples of enantiopure helically chiral NHCs have been described in the literature. Using a well-established method based on the diastereoselective metal catalysed [2+2+2] cycloisomerisation of centrally chiral triynes as the key step, I have synthesised a series of optically pure 2H-pyran based penta- and hexahelicenes bearing an amino group on the terminal benzene ring. The triynes were prepared by a sequence of Sonogashira and Mitsunobu coupling reactions using the commercially available (S)-but-3-yn-2-ol as the source of chirality. The resulting aminooxa[5]- and aminooxa[6]helicenes were then converted into the corresponding 1,3-disubstituted imidazolium salts, from which, upon deprotonation, the helically chiral N- heterocyclic carbenes were generated. To evaluate the performance of the new helically chiral ligands, the enantioselective Ni0 - catalysed [2+2+2] intramolecular cycloisomerisation of prochiral triynes to nonracemic dibenzohelicenes was chosen as a model reaction. All the synthesised imidazolium salts provided,...

Synthese und Charakterisierung neuer metall-organischer Gerüstverbindungen und deren Anwendung in der asymmetrischen Katalyse und Gasspeicherung

Gedrich, Kristina

01 February 2011

Ziel der durchgeführten Arbeiten war die Etablierung neuer Synthesestrategien zur Gewinnung chiraler metall-organischer Gerüstverbindungen (engl: Metal-Organic Frameworks, MOFs). Hierfür wurden drei verschiedene Ansätze verfolgt. Zunächst sollte die Einbringung einer chiralen Dicarbonsäure mit einem 2,2´-Spirobiindan-Gerüst in ein MOF-Netzwerk untersucht werden. Im Rahmen einer Kooperation wurden neue mit chiralen Oxazolidinonen substituierte 4,4´,4´´-Benzol-1,3,5-triyl-tribenzoesäuren H3ChirBTB-n (n = 1, 2) entwickelt, die ebenfalls zur Synthese neuer chiraler MOFs dienten. Die Modifizierung bekannter nicht-chiraler metall-organischer Gerüstverbindungen mit koordinativ ungesättigten Metallatomen durch Anbindung chiraler Amine stellte die dritte Synthesestrategie dar. Im Rahmen der letztgenannten Syntheseroute wurde für MIL-101 (MIL = Matérial Institut Lavoisier) eine sehr hohe katalytische Aktivität in der Cyanosilylierung von Benzaldehyd nachgewiesen. Die Umsetzung mit chiralen Aminen führte jedoch nicht zu einem enantioselektiven Katalysator. Im Gegensatz dazu konnten die ersten beiden Synthesewege zur Gewinnung neuer chiraler metall-organischer Gerüstverbindungen erfolgreich beschritten werden. Durch solvothermale Reaktion von (S)-2,2´-Spirobiindan-5,5´-dicarbonsäure ((S)-H2Spiro-BIDC) mit Zinknitrat in N,N-Dimethylformamid (DMF) wurde eine neue chirale metall-organische Gerüstverbindung namens DUT-7 (DUT = Dresden University of Technology) der Zusammensetzung Zn4O((S)-Spiro-BIDC)3 dargestellt. Neben einer unerwarteten, zweifach interpenetrierten Netzwerkstruktur mit hexagonalen Kanälen weist DUT-7 eine für MOFs bislang noch nicht beobachtete temperaturinduzierte, reversible Strukturänderung auf. Die zweite neue Strategie zur Gewinnung chiraler MOFs beinhaltete die Umsetzung der chiralen Tricarbonsäuren H3ChirBTB-n, die entweder (S)-4-iso-Propyl- (n = 1) oder (S)-4-Benzyl-1,3-Oxazolidin-2-on-Substituenten (n = 2) tragen. Die beiden gewonnenen Verbindungen Zn3(ChirBTB-1)2 und Zn3(ChirBTB-2)2 weisen trotz gleicher Zusammensetzung völlig unterschiedliche Kristallstrukturen auf. Beide Materialien wurden erfolgreich in der Mukaiyama-Aldol-Reaktion von Benz- bzw. 1-Naphthaldehyd mit 1-Methoxy-2-methyl-1-(trimethylsiloxy)propen eingesetzt, wobei ihre katalytische Aktivität mit verschiedenen Referenzkatalysatoren verglichen wurde. Die erzielten Enantiomerenüberschüsse (ee) liegen zwischen 6 und 16%. Auf der Suche nach neuen, für die Einbringung der ChirBTB-n-Liganden geeigneten MOF-Strukturen wurde auch die Umsetzung der reinen, nicht chiralen 4,4´,4´´-Benzol-1,3,5-triyl-tribenzoesäure (H3BTB) untersucht. Die Reaktion mit Nickelnitrat führte zur Bildung einer neuen hochporösen Verbindung namens DUT-9 mit der Zusammensetzung Ni5O2(BTB)2(DEF,DMF)4(H2O)4. DUT-9 weist neben den auf dem Gebiet der MOF-Forschung bislang unbekannten Ni5O2-Clustern eine noch nicht beschriebene dreidimensionale (3,6)-Netzwerktopologie auf. Das neue Material zeigt zudem exzellente Speicherkapazitäten für Wasserstoff, Methan und Kohlenstoffdioxid. / The present work aims on the search for new synthesis strategies towards chiral Metal-Organic Frameworks (MOFs). Three different approaches were pursued. Initially, the integration of a chiral dicarboxylic acid with a 2,2´-spirobiindane backbone into a MOF network was investigated. Within a cooperation, new 4,4´,4´´-benzene-1,3,5-triyl-tribenzoic acids H3ChirBTB-n (n = 1,2) with chiral oxazolidinone substituents were developed which were also used for the assembly of chiral MOFs. The third synthesis strategy involved the tethering of chiral amines to coordinatively unsaturated metal atoms of known non-chiral Metal-Organic Frameworks. Within the last-mentioned approach, the very high catalytic activity of MIL-101 (MIL = Matérial Institut Lavoisier) towards the cyanosilylation of benzaldehyde was demonstrated. Treatment with chiral amines did not lead to an enantioselective catalyst. In contrast, the first two synthesis strategies could be performed successfully. A new MOF named DUT-7 (DUT = Dresden University of Technology) with composition Zn4O((S)-Spiro-BIDC)3 was obtained by solvothermal reaction of (S)-2,2´-spirobiindane-5,5´-dicarboxylic acid ((S)-H2Spiro-BIDC) with zinc nitrate in N,N-dimethylformamide (DMF). Besides an unexpected, two-fold interpenetrated framework structure with hexagonal channels, DUT-7 shows a temperature induced, reversible structure transformation not yet observed. The other new strategy to obtain chiral Metal-Organic Frameworks involved the conversion of the chiral tricarboxylic acids H3ChirBTB-n bearing either a (S)-4-iso-propyl- (n = 1) or a (S)-4-benzyl-1,3-oxazolidin-2-one substituent (n = 2). Though having the same framework composition, the new compounds Zn3(ChirBTB-1)2 and Zn3(ChirBTB-2)2 exhibit completely different crystal structures. Both materials were tested in the Mukaiyama aldol reaction between benzaldehyde or 1-naphthaldehyde, respectively, and 1-methoxy-2-methyl-1-(trimethylsiloxy)propene and their catalytic activity was compared to different reference catalysts. Enantiomeric excess values (ee) between 6 and 16% were obtained. In search of new MOF structures being suitable for the integration of the ChirBTB-n linkers, the conversion of the pure, non chiral 4,4´,4´´-benzene-1,3,5-triyltribenzoic acid (H3BTB) was investigated. The reaction with nickel nitrate lead to the formation of a new, highly porous compound Ni5O2(BTB)2(DEF,DMF)4(H2O)4 named DUT-9. Besides Ni5O2 clusters which are a novelty in MOF chemistry, DUT-9 exhibits a three dimensional (3,6)-network topology not yet described. In addition, the new material shows excellent storage capacities for hydrogen, methane and carbon dioxide.

info:eu-repo/classification/ddc/540

ddc:540

TADDOLs and derivatives : synthesis and applications in enantioselective processes / TADDOLs et dérivés : synthèse et applications en processus enantioselectifs

Gherase, Dragos

16 December 2011

Dans cette thèse les résultats dans le domaine de la synthèse des dérivée des TADDOL et leur capacité d’induction chirale sont présentés. Une librairie des TADDOLs a été synthétisée et une analyse conformationnelle par VCD a été faite. Ces composés enantiopurs ont été testés dans la réaction de cyanosilylation enantioselective en donnant des résultats moyens. En partant de TADDOL nous avons synthétisé des dérivée phosphorés, des amines et des (thio)urées. Les dérivés de P(III) ont été utilisés comme ligands pour le palladium dans l’alkylation allylique asymétrique et les amines dans le réarrangement des époxydes meso. Les (thio)urées ont été testées pour leur capacité de complexation des anions carboxylates. / In this thesis are presented the results in the field of synthesis of TADDOL derivatives and their chiral induction capacity. A family of TADDOLs was synthesized and a conformational analysis was performed by VCD. These enantipure compounds were tested in enantioselective cyanosilylation reactions obtaining moderate results. Starting from TADDOL we obtained phosphorus derivatives, amines and (thio)ureas. The P(III) derivatives were tested as ligands for palladium in asymmetric allylic alkylation and the amines in the rearrangement of meso-epoxides. The (thio)ureas were screened for complexation capacity for carboxylate anions.

TADDOL

VCD

CLHP chirale

Catalyse énantioselective

Reconnaissance chirale

Discrimination chirale

ATG

DSC

Cyanosilylation

Alkylation allylique

Chirality

TADDOL

VCD

Chiral HPLC

Enantioselective catalysis

Chiral recognition

Chiral discrimination

TGA

DSC

Cyanosilylation

Allylic alkylation

Synthèse de [gamma]-lactones polyfonctionnelles chirales par catalyse énantiosélective / Catalytic enantioselective syntheses of polyfunctional chiral [gamma]-lactones

Bos, Maxence

07 December 2015

La mise au point de méthodologies de synthèse permettant d’obtenir des substances énantiopures présentant une diversité structurale importante est une préoccupation majeure de la chimie contemporaine. L’efficacité de ces approches doit être désormais évaluée au regard de critères tel que la pureté optique et l’analyse de l’impact écologique des processus mis en jeu. Au cours de ce travail nous avons développé de nouvelles méthodologies permettant d’accéder à des γ-lactones polyfonctionnelles chirales. La 5-hydroxyfuran-2(5H)-one, petite molécule bio-sourcée, a servi d’élément clé pour la construction du cycle γ-lactone. Dans une première approche, des γ-lactones chirales possédant une grande diversité structurale ont été obtenues par une séquence réactionnelle « one pot ». Une première étape de catalyse organique a permis d’activer le transfert énantiosélectif d’acides boroniques sur la 5-hydroxyfuran-2(5H)-one ; l’adduit chiral obtenu a ensuite été engagé dans une réaction de Passerini pour construire le cycle lactone. Dans une deuxième partie, nous avons mis au point des réactions d’alkylation de γ-lactones, catalytiques et énantiosélectives, pour la formation de γ-lactones possédant un centre quaternaire. L’utilisation de complexes du palladium et de l’iridium a permis d’effectuer des réactions d’Alkylation Allylique Asymétrique avec un très bon contrôle de l’induction asymétrique. Le squelette carboné des lactones obtenues par AAA a permis d’effectuer une fonctionnalisation inédite d’hétérocycles aromatiques par des réactions sigmatropiques [3,3]. Enfin des réactions d’alkylations énantiosélectives induites par un catalyseur organique ont été évaluées. / The development of new synthetic pathway leading to enantiopure compounds with significant structural diversity is an ongoing challenge in many fields of chemistry. The efficiency of these processes has to be evaluated, not only in term of quantitative criteria, such as yields and/or optical purities of obtained compounds, but also by analyzing the environmental impact of the different processes involved. In this work, we sought to develop new methodologies for the synthesis of polyfunctional chiral γ-lactones. The 5-hydroxyfuran-2(5H)-one, a bio-based molecule, was used as a platform to the construction of the γ-lactone ring. In the first part of our work, a variety of chiral γ-lactone displaying a great structural diversity were obtained by a one-pot sequential reaction. First, a step of enantioselective organocatalysis allowed the activation for the transfer of boronic acids on the hydroxyfuran-2(5H)-one; then the chiral adduct formed was engaged in a Passerini reaction leading to the construction of the lactone ring. In a second part, our efforts focused then on the development of catalytic asymmetric alkylation reactions leading to the construction of γ-lactones bearing an all-carbon quaternary stereocenter. Asymmetric allylic reactions were carried out with a very good control of the selectivity of the reaction by the use of palladium and iridium complexes catalysts. Theses lactones bearing an [1,5]-diene scaffold were then engaged in a sigmatropic [3,3] reaction opening a path for a new approach to the functionalization of aromatic heterocycles. Finally, the use of organic enantioselective catalysis was envisioned for the creation of all-quaternary stereocenters.

[GAMMA]-Lactone

5-Hydroxyfuran-2(5H)-One

Catalyse Énantiosélective

Acides Boroniques

Réaction de Passerini

Alkylation Allylique Asymétrique

[GAMMA]-Lactone

5-Hydroxyfuran-2(5H)-One

Enantioselective Catalysis

Boronic Acids

Passerini Reaction

Asymmetric Allylic Reaction

C₂-Symmetric Pyrazole-Bridged Ligands and Their Application in Asymmetric Transition-Metal Catalysis

Böhnisch, Torben

23 July 2015

No description available.

540

Pyrazole-Bridged Ligands

Asymmetric Transition-Metal Catalysis

Cooperative Asymmetric Catalysis

Enantioselective Catalysis

Two-Center Catalysis

Pyrazole

PyrBOX

PyrBPyBOX

ProPyrazole

Tsuji-Trost

Allyl Palladium

Asymmetric Allylic Substitutions

Asymmetric Allylic Alkylations

Solvation Effects

Cooperative Effects

EXSY

Helicate

Mesocate

Cluster Helicate

Atropisomerism

Atropselective Oxidative Coupling

2-Napthol

Chemie  (PPN62138352X)

The modification of brucine derivatives as chiral ligands and its application in the asymmetric synthesis

Li, Jian-yuan

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The modification of brucine derivatives as chiral ligands and the use of a multifaceted chiral ligand, brucine diol, under different reaction conditions to produce various optical isomers is described. In Chapter 1, the generation of a number of brucine derivatives is described. Taking the advantage of brucine-diol’s excellent molecular recognition capability for multiple organic functional groups, we focused on the synthetic modifications of brucine-diol and the synthesis of brucine N-oxide. We also produced various brucine derivatives with different functional moieties in good yields and selectivities. In Chapter 2, we described the investigation of brucine N-oxide catalyzed Morita-Baylis-Hillman (MBH) reaction of alkyl/aryl ketones. Brucine N-oxide was used as a nucleophilic organic catalyst in the MBH reaction of alkyl vinyl ketone. In addition, asymmetric MBH reactions of alkyl vinyl ketones with aldehydes were investigated using a dual catalysis of brucine N-oxide and proline. In this dual catalyst system, proline was found to form iminium intermediates with electron-deficient aryl aldehydes, while the N-oxide activated vinyl ketones provided enolates through the conjugate addition. Our dual catalysis approach also allowed the development of MBH reaction of aryl vinyl ketones. In Chapter 3, brucine diol-copper complex catalyzed asymmetric conjugate addition of glycine (ket)imines to nitroalkenes is discussed. Stereodivergent catalytic asymmetric conjugate reactions for glycine (ket)imines with nitroalkenes were achieved using various chiral catalysts derived from a single chiral source, brucine diol. Both syn- and anti-conjugate addition products were obtained with high diastereoselectivity and enantioselectivity. In Chapter 4, enantiodivergent production of endo-pyrrolidines from glycine (ket)imines using brucine diol-copper complex is described. The [3+2] cycloaddition reaction of glycine imines and activated alkenes was performed to produce endo-pyrrolidines. The reversal of enantioselectivity was observed for endo-pyrrolidines between concerted and stepwise reaction pathways. The three new brucine derivatives produced in this study would potentially work as organocatalysts and chiral ligands with metal ion in asymmetric synthesis. The brucine diol-metal complex catalyzed reactions laid a good foundation for catalytic asymmetric reactions, where a single chiral source was used to control the absolute and the relative stereochemical outcomes of reactions. Understanding the molecular-level interactions between catalyst and substrates will provide insightful mechanistic details for the stereodivergent approaches in asymmetric catalysis.

Nux vomica -- Research -- Analysis

Organic compounds -- Synthesis

Chirality -- Research -- Analysis

Chemical reactions -- Research

Catalysis -- Research

Ketones -- Research -- Analysis

Aldehydes -- Analysis

Proline