Exploring small bite-angle PNP and PCP ligands for the rhodium-catalysed intermolecular hydroacylation of b-s-substituted aldehydes with alkenes and alkynes

Pernik, Indrek

January 2014

This thesis discusses the intermolecular hydroacylation reaction using cationic rhodium bis- phosphine complexes as catalysts. A series of small bite-angle rhodium bis-phosphine complexes have been prepared and characterised. The reactivity of these complexes has been investigated in order to gather information about the effect of subtle changes in the ligand design and they are compared to the previously reported catalysts. Chapter 2 presents the challenges involved in the synthesis of small bite-angle isopropyl and cyclohexyl PNP and PCP bis-phosphine ligand containing rhodium complexes. These complexes have been fully characterised and screened in intermolecular hydroacylation reaction using 2- (methylthio)benzaldehyde (<strong>E</strong>) and 1-octene or 1-octyne as substrates. The formed complexes were shown to be very efficient and regioselective alkyne hydroacylation catalysts. The mechanism of the hydroacylation reaction was investigated using the isopropyl PNP complex [Rh(ⁱPrPNMePⁱPr₂)(C₆H₅F)][BAr^F₄] (<strong>11b</strong>). Chapter 3 concentrates on developing new rhodium bis-phosphine complexes that involve a ligand incorporating the small bite-angle motif with the one of hemilability. The PNP complex [Rh((2-OMe-C₆H₄)₂PNMeP(2-OMe-C₆H₄)2)(C₆H₅F)][BAr^F₄] (<strong>41</strong>) was synthesised and analytically characterised. <strong>41</strong> was shown to be an active alkyne hydroacylation catalyst with more stability towards the catalyst deactivation pathway, reductive decarbonylation, compared to the previously investigated <strong>11b</strong>. Additionally mechanistic studies using <strong>41</strong> were carried out. The final chapter moves on to study the C-S activation ability of small bite-angle rhodium bis- phosphine complexes to remove the sulfur tether from the hydroacylation products at the end of the hydroacylation reaction. A screening is conducted to compare the reactivity of different small bite-angle ligands. Additionally, a detailed investigation is carried out to see the effect the C-S activation has on the hydroacylation reaction.

547

Controlling selectivity in the rhodium-catalysed intermolecular hydroacylation reaction

Pawley, Rebekah J.

January 2012

This thesis explores the area of the intermolecular hydroacylation reaction, catalysed by rhodium diphosphine complexes. A range of latent low-coordinate rhodium diphosphine complexes have been synthesised, and their catalytic activity for the hydroacylation reaction has been investigated. In particular, emphasis has been placed on understanding how subtle changes in diphosphine steric properties affect, and can be used to control, selectivity of this catalysis. Chapter 2 presents investigations into rhodium complexes incorporating the potentially hemilabile P-O-P ligands: POP’, XANTphos and Xphos. The resulting complexes have been fully characterised and their activity for the catalytic intermolecular hydroacylation of aldehyde I (HCOC₂H₄SMe) and alkene II (H₂C=CHCO₂Me) established and compared to the DPEphos system. Further reactivity of Xphos for aromatic aldehyde V (HCOC₆H₄SMe) and alkene II, and aldehyde V and alkyne XI [HC≡CC₆H₃(CF₃)₂] has also been explored, and compared with the catalytic activity of {Rh(PPh₃)₂}⁺. Focus moved from potentially hemilabile ligands to chelating diphosphine ligands of the type PPh₂(CH₂)nPPh₂ (where n = 2-5), and then on to ortho-substituted bulky analogues of the type P(₀-C₆H₅R)₂(CH₂)₂P(₀-C₆H₅R)₂ (where R = Me and ⁱPr) complexed to rhodium. Chapter 3 outlines the complexes synthesised, and their activity for the catalytic intermolecular hydroacylation of aldehyde I and alkene II, aromatic aldehyde V and alkene II or aldehyde V and alkyne XI. Possible explanations for the observed switch in selectivity from alkene to aldehyde hydroacylation, and linear alkyne to branched alkyne hydroacylation, have been explored and are detailed. The final chapter concerns the structure of an interesting catalytic intermediate: the branched alkenyl species for the {Rh(DPEphos)}+ catalysed hydroacylation of aldehyde V and alkyne XI. Investigations into the kinetic and catalytic behaviour of this system were carried out, and a reaction scheme has been proposed which correlates well with kinetic modelling undertaken by Prof. Guy Lloyd-Jones of the University of Bristol.

541.395

Development of Ru-Catalyzed Tandem Sequences Involving Ring-Closing Metathesis

Nam, Youn Hee

January 2013

Thesis advisor: Marc L. Snapper / Tandem processes can have several advantages over multiple single step processes. Non-metathesis transformations of ruthenium alkylidenes were studied and applied to tandem processes. Ruthenium catalyzed tandem RCM/hydroacylation that allows access to tricyclic ring systems from readily available substrates was developed. Mechanistic investigations indicated that this reaction may proceed through a mechanism involving [Ru]-H species. A Ru-catalyzed tandem RCM/olefin isomerization/C-H activation sequence that provides significant advantages in terms of rapid elaboration of simple reaction partners to more complex entities was developed. / Thesis (PhD) — Boston College, 2013. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

C-H Activation

Hydroacylation

Olefin Isomerization

Ring-Closing Metathesis

Ru-Catalyzed

Tandem Sequence

Real-time Investigation of Catalytic Reaction Mechanisms by Mass Spectrometry and Infrared Spectroscopy

Theron, Robin

08 July 2015

Electrospray ionization mass spectrometry (ESI-MS) has been applied to the realtime study of homogeneous organometallic reactions. ESI-MS as a soft ionization technique is amenable to fragile organometallic complexes, and as a fast and sensitive technique is ideal for detecting low concentration intermediates within reactions. Pressurized sample infusion (PSI) was used for continuous sample infusion into the mass spectrometer, granting the air-free conditions necessary for these reactions to be successful, and resulting in reaction profile data that contains information about the dynamics of speciation of the catalyst. Collision induced dissociation (CID) was used to probe the binding affinities of various bisphosphine ligands as well as in characterizing intermediates in reactions. PSI ESI-MS was applied to the hydroboration reaction of the alkene tert-butylethene using the amine-borane H3B⋅NMe3 catalyzed by [Rh(xantphos)]+ fragments to show how the reaction progresses from substrates to products. PSI ESI-MS was also applied to the hydrogenation of a charge-tagged alkyne [Ph3P(CH2)4C2H]+[PF6]-, catalyzed by a cationic rhodium complex [Rh(PcPr3)2(η6-FPh)]+[B{3,5-(CF3)2C6H3}4]– (PcPr3 = triscyclopropylphosphine, FPh = fluorobenzene). This work demonstrated the use of ESI-MS in conjunction with NMR, kinetic isotope effects and numerical modeling for determining a mechanism of reaction. The hydroacylation reaction of a β–S substituted aldehyde and an alkyne catalyzed by [Rh(PiPr2NMePiPr2)(η6-FPh)]+[B{3,5-(CF3)2C6H3}4]– (PiPr2 = diisopropylphosphine) was studied by PSI ESI-MS while employing charged tags, allowing for observation of reaction progress and some key intermediates. A new concept for mechanistic analysis has been developed: coupling of an orthogonal spectroscopic technique with PSI ESI-MS. This new method was applied to the same hydroacylation reaction studied with charged tags. The use of IR in conjunction with ESI-MS led to rate information about the overall reaction along with dynamic information about catalytic speciation. Coupling of these techniques allows for detection over many magnitudes of concentration. / Graduate

Mass spectormetry

Infrared spectroscopy

Catalysis

Chemistry

operando spectroscopy

hydroacylation

hydrogenation

hydroboration

Ketone synthesis via rhodium-catalyzed traceless chelation-controlled hydroacylation reactions

Gao, Ming

January 2018

This thesis documents the development of rhodium-catalyzed traceless chelation-controlled hydroacylation reactions for the synthesis of a variety of ketone products. <strong>Chapter 1</strong> provides an overview of rhodium-catalyzed hydroacylation chemistry, focusing on the origin of chelation-controlled strategies and the benefits thereof. <strong>Chapter 2</strong> describes a sequential reaction involving alkene hydroacylation, sulfide elimination and boronic acid conjugate addition, which affords products with the initial sulfide coordinating group replaced by a stereochemically defined aryl group. <strong>Chapter 3</strong> demonstrates a sequential process involving alkyne hydroacylation, boronic acid conjugate addition and sulfide elimination, which provides enantioenriched β'-arylα,β-unsaturated ketones in a highly efficient and selective manner. <strong>Chapter 4</strong> illustrates a versatile chelating group, triazene, for hydroacylation reactions. Subsequent functionalization of aromatic C-H bonds, promoted by the same chelating unit, offers highly substituted phenyl ketone products. <strong>Chapter 5</strong> documents experimental procedures and data.

Exploring and exploiting selectivity in rhodium-catalysed hydroacylation reactions

Poingdestre, Sarah-Jane

January 2012

Chapter 1 is an overview of the key developments in rhodium-catalysed hydroacylation. The main focus of this chapter is the use of various chelation strategies for the stabilisation of key rhodium-acyl intermediates. In addition, the more recent emergence of regioselective hydroacylation processes has been highlighted. Chapter 2 discloses the branched-selective intermolecular hydroacylation of 1,3-dienes and S-chelating aldehydes to afford synthetically useful 1,5-dione products. The evaluation of a number of different phosphine ligands for this process identifies a correlation between ligand bite angle and reaction regioselectivity. Chapter 3 discusses the development of a linear-selective hydroacylation process for previously challenging alkyne substrates. This, in combination with a complementary branched-selective process, provides a ligand-controlled regioselectivity switch between the branched and linear pathways. Finally, Chapter 4 details efforts towards the development of multicomponent, tandem processes through exploitation of our synthetically useful branched hydroacylation adducts.

546.634

Rhodium catalysed hydroacylation reactions in the synthesis of heterocycles

Ylioja, Paul M.

January 2011

Rhodium-catalysed hydroacylation provides a highly atom economic synthesis of ketone products from the combination of aldehydes and multiple bond systems by C-H bond activation. This work evaluates the combination of intermolecular hydroacylation for the synthesis of classical heterocycle precursors and their dehydrative cyclisation to give rise to a range of substituted heterocyclic compounds. Chapter 1 outlines recent developments in the chemistry of hydroacylation. Particular attention is paid to the various chelation strategies employed in intermolecular hydroacylation. Chapter 2 discusses some relevant and recent developments in the field of pyridine and pyrrole synthesis. Having established that β-sulphur chelation controlled hydroacylation can be used to synthesise pyridines in Chapter 3; attention was turned to hydroacylation of propargyl amines in Chapter 4. The methodology was expanded to provide a synthesis of γ-amino enones. The hydroacylation reaction and cyclisation is combined in a procedure that utilises thermal Boc-deprotection and cyclisation to give a range of highly-substituted pyrroles. The regioselectivity of the hydroacylation of propargyl amines is investigated in Chapter 5 by application of statistical Design of Experiments methodology. Optimised conditions were identified with minor improvements in the selectivity of the reaction.

547.59

Hydroacylation and C-N Coupling Reactions. Mechanistic Studies and Application in the Nucleoside Synthesis

Marcé Villa, Patricia

23 May 2008

The PhD work "Hydroacylation and C-N coupling Reactions. Mechanistic Studies and Application in the Nucleoside Synthesis" tackle two different objectives, a) developing new methods of synthesis of nucleosides (introduction, and chapters 1 and 2) and b) to carry out a mechanistic study of the intermolecular hydroacylation and hydroiminoacylation reaction with and cationic rhodium complexes (chapter 3). Concerning the synthesis nucleosides, in chapter 1 we have explored new methods of synthesis of 2',3'-dideoxynucleosides and isonucleosides using a palladium or copper catalyzed C-N coupling reaction, aiming to overcome the stereoselectivity problems of the glycosylation reaction. The synthesis of the iodo-vinyl derivatives required as starting materials has been tried by different procedures, all of them unsuccessful. Finally, the coupling reaction has been explored in 1-iodo-glucal derivatives. Palladium catalysts were unsuccessful in coupling with benzimidazol used as model of purinic bases. Copper catalysts provided very low conversions. However, the oxidative addition of 1-iodo-glucal to palladium was proved and it was also observed that the reaction with aniline proceeds. That, suggest that the problem is in the steps involving the benzimidazol.In chapter 2, it has been developed a new method of synthesis of carbocyclic nucleosides using and enantioselective intramolecular hydroacylation reaction as a key step. This reaction leaded to the 3-hydroxymethyl-cyclopentanones in good yields and excellent enantioselectivities. When (S,S)-Me-Duphos was used the 3S-cyclopentanone was obtained, in contrast whether the (R,R)-Me-Duphos was employed the reaction proceed giving the opposite enantiomer. In both cases. The reduction of the ketone can be carried out in a stereoselective way using a hydroxyl-assited reduction with NaBH(OAc)3. Alternatively, the diastereomeric mixture obtained by a direct reduction can be resolved by using a DKR process using a combined enzyme/Ru complex catalytic system. A Mitsunobu reaction has allowed finally to link adenine to the cyclopentane moiety. In the third chapter, the mechanism of both cationic and neutral rhodium catalyst precursors in the hydroiminoacylation of alkenes was studied. The oxidative addition step was studied using both NMR and DFT techniques. Using the neutral complex, this step is a thermodynamically favoured process, as demonstrated by the isolation of the stable complex. Furthermore, DFT calculations showed the existence of an agostic intermediate on the route to the C-H activation product. In the cationic system, the oxidative addition reaction was shown by DFT calculations to be an endothermic process, hence un-favoured. This was in agreement with the NMR experiments, in which an oxidative addition product was only detected in the presence of a chloride source. Furthermore, the transition states involved in both systems were identified using DFT calculations, which proved that the presence of chloride not only stabilize the oxidative addition product but also lower the energy barrier of the overall process.Using the neutral system, it was identified the coupling product still coordinated to rhodium, which is in an enamine tautomeric form. After removal of the coupling product the stable complex [Rh(&#956;-Cl)(PPh3)2]2 was formed. This species was reported as a precursor for the oxidative addition step, from which the catalytic cycle can start again. However in the cationic system, the system did not yield any stable rhodium species and quickly evolved towards decomposition. / Durante la última década la terapia del SIDA ha experimentado una evolución notable. El conocimiento del modo de actuación y proliferación del virus ha permitido incrementar el número de dianas biológicas para su neutralización. Así, hoy en día se conocen compuestos que inhiben la entrada del virus en la célula, la transcripción del RNA en DNA, la integración del DNA vírico en DNA celular, la producción del envolvente proteico del virus, entre otros. Todo ello, ha permitido la realización de tratamientos dirigidos a diferentes dianas, que han neutralizado la evolución del virus mejorando la calidad de vida de los pacientes.Existen numerosas metodologías diseñadas para obtener los retrovirales mencionados anteriormente, pero en la mayoría de ellas se requieren numerosos pasos de síntesis y además en muchas de ellas se obtienen mezclas de los isómeros &#945;/&#946;. De este modo se pretende diseñar una alternativa sintética general para la preparación de la familia de nucleósidos arriba indicadas y al mismo tiempo que sea una alternativa práctica y eficaz a los métodos descritos hasta el momento.En el capítulo uno la obtención de isonucleosidos y 2',3'-dideoxinucleosidos se abordó utilizando como etapa clave de reacción el acoplamiento C-N entre los derivados de 4-halo-2,3-dihidrofurano y 5-halo-2,3-dihidrofurano con bases púricas y pirimidínicas, la posterior hidrogenación enantioselectiva del doble enlace nos permitiría obtener los mencionados compuestos de una forma sencilla. En el estudio realizado bajas conversiones de los productos de acoplamiento cruzado fueron detectados aunque actualmente se están intentado mejorar los resultados.Referente a la obtención de carbociclonucleosidos abordada en el capítulo 2, se ha llevado cabo una nueva metodología sintética en la que se ha aplicado la reacción de hidroacilación intramolecular enantioselectiva catalizada por rodio. Así pentenales substituidos en posición cuatro han sido convertidos en las ciclopentanonas correspondientes. En función de la quiralidad de la fosfina empleada se han obtenido tanto los enantiomeros R como S con excelentes conversiones y enantioselectividades.Con el fin de incorporar la base nitrogenada en la ciclopentanona la reducción diastereoselectiva se ha llevado a cabo dos procedimientos: a) reducción racémica de la ciclopentanona y posterior resolución cinética dinámica, b) reducción diastereoselectiva utilizando como agente reductor el triacetoxiborohidruro de sodio. En ambos casos se obtuvieron diastereoselectividades excelentes pudiendo así obtener un distereoisomero u otro en función del procedimiento y el enantiomero utilizado como material de partida. La posterior reacción de Mitsunobu sobre el alcohol y la desprotección del grupo protector nos ha permitido obtener el carbociclonucleosido con buenos rendimientos y excelentes esteroselectividades.En el capitulo tres se ha realizado un estudio sobre la reacción de hidroacilación intramolecular de alquenos cataliza por rodio, donde se ha estudiado la diferencia de comportamiento de los sistemas catiónicos y neutros de rodio en la etapa de adición oxidante. Estos estudios se han realizado utilizando técnicas espectroscópicas de resonancia magnética nuclear y cálculos teóricos mediante técnicas DFT. El estudio computacional ha mostrado que en el caso de los sistemas neutros la etapa de adición oxidante es una etapa termodinámicamente favorable hecho que se gratifica con el hecho de que el producto de adición oxidante es estable y aislable. Además se ha encontrado la existencia de un intermedio agóstico en el proceso de activación del enlace C-H. Sin embargo, en los sistemas catiónicos la etapa de adición oxidante resultó ser un proceso endotérmico. Los estados de transición encontrados no solo han demostrado que la presencia de cloruro estabiliza el producto de adición oxidante sino que también disminuye la barrera energética del proceso global. La etapa de inserción del alqueno también fue estudiada para ambos sistemas utilizando estireno como sustrato. En el sistema neutro se detectó una nueva especie de rodio la cual no había sido descrita anteriormente y fue completamente caracterizada mediante RMN multinuclear.En el sistema catiónico se consiguió detectar el hidruro correspondiente al producto de adición oxidante el cual también fue completamente caracterizado por técnicas de RMN. Sin embargo, en el estudio de la inserción del alqueno no se observó la ningún producto que indicase que el mencionado proceso se llevará acabo indicado que la inserción de alqueno es además la etapa lenta del proceso.

Mechanistic Studies by DFT and NMR

Synthesis of Carbocyclic Nucleoside

C-N couplings

544

546

547

ラジカル超原子価ヨウ素(III)試薬を用いた直接的C-H活性化反応の開発

臼井, 明日香

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18808号 / 理博第4066号 / 新制||理||1585(附属図書館) / 31759 / 京都大学大学院理学研究科化学専攻 / (主査)教授 丸岡 啓二, 教授 時任 宣博, 教授 大須賀 篤弘 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

hypervalent iodine(III) reagents

radical reactions

C-H activation

site-selective oxidation

photo-catalyzed reaction

hydroacylation

400

Tandem catalytic processes involving Rhodium-catalysed intermolecular hydroacylation

Lenden, Philip

January 2011

This work describes the extension of rhodium-catalysed intermolecular hydroacylation to encompass some tandem catalytic processes, wherein a further catalytic process is enacted on the product of an intermolecular hydroacylation reaction in “one pot”. Chapter 1 entails an overview of the development of hydroacylation chemistry, with a focus on the different types of catalytic systems which have been used to facilitate this transformation. A brief description of some precedented examples of tandem catalytic processes which include a hydroacylation reaction is also included. Chapter 2 describes the intermolecular hydroacylation of chelating aldehydes and propargylic alkynes to form γ-hydroxy-α,β-enones, and their subsequent acid-catalysed cyclisation to form substituted furans in a "one-pot" procedure. Additionally, a tandem intermolecular hydroacylation/double-bond isomerisation protocol for the synthesis of 1,4-dicarbonyl compounds is detailed, and the subsequent transformation of this class of compounds to heterocycles is included. Chapter 3 focuses on the development of tandem catalytic hydroacylation/reductive processes, wherein a hydroacylation product undergoes a reduction which is catalysed by the hydroacylation catalyst. Chapter 4 describes an attempt to utilise the rhodium-catalysed conjugate addition of arylmetal species to enomes to create a tandem alkyne hydroacylation/conjugate addition process. Chapter 5 encompasses the use of a small range of different solvents in rhodium-catalysed hydroacylation, in an attempt to find higher-boiling alternatives to acetone and a "green" alternative to the commonly used DCE.

547.215