Bifunctional Enamine‐Metal Lewis Acid Catalysis and α-Enaminones for Cyclization Reactions

Davis, Jacqkis

08 1900

The use of enamines continues to be an important tool in organic syntheses as both a catalyst and reactant. The addition of metal catalysts coupled with enamine catalysis has generated many reactions that normally would not occur separately. However, catalysts' incompatibility is an issue that we wish to solve allowing new chemistry to occur without hindrance. The use of enamines has continued to be a well-studied area of organic chemistry, but the field is ripe for different types of enamines to gain the spotlight. Enaminones are enamines with both nucleophilic and electrophilic properties. They allow reactions that are normally not possible with enamines to become obtainable. Chapter 1 is a brief introduction on enamines and the reason they gained so much attention. Then ends with enaminones and what makes them interesting reactants. Chapter 2 described a new synthesis for the tricyclic synthesis of chromanes using a novel bifunctional catalyst system of enamine-metal Lewis acid giving great yields (up to 87 %yield) and excellent stereoselectivity (up to 99 % ee). Chapter 3 covered new reactions for ring-open cyclopropane (up to 94% yield), tetrahydroquinolinones (up to 84% yield) and enantiospecific tetrahydroquinolinones (up to 84% yield and 97% ee) using α-enaminone and donor-acceptor cyclopropanes. Finally, Chapter 4 focused a new method for synthesizing benzobicyclo[3.2.1]octanes with an added sterically bulky quaternary center and imine functionalization giving yields between 36-73% yield using α-enaminone with alkylidene malonates.

Bifunctional Catalysis

Enamine Catalysis

Metal Catalysis

α-Enaminone

Cyclization

Chemistry, Organic

Design of New Monodentate Ligands for Regioselectivity and Enantioselectivity Tuning in Late Transition Metal Catalysis

Ruch, Aaron A.

05 1900

The ability of gold(I) to activate many types of unsaturated bonds toward nucleophilic attack was not widely recognized until the early 2000s. One major challenge in gold catalysis is the control over regioselectivity when there are two or more possible products as a result of complicated mechanistic pathways. It is well know that the choice of ligand can have dramatic effects on which pathway is being followed but very rarely are the reasons for this selectivity understood. The synthesis of new acyclic diaminocarbenes was developed and a study of the ligand effects on the regioselectivity of a gold-catalyzed domino enyne cyclization hydroarylation reaction and a Nazarov cyclization was undertaken. New chiral acyclic diaminocarbenes were also developed and tested along side new C3-symmetric phosphite ligands in an asymmetric intramolecular hydroamination of allenes. Structure activity correlations were developed for the potential use in further rational ligand design. The synthesis of 6a,7-dihydro-5-amino-dibenzo[c,g]chromene derivatives via a gold-catalyzed domino reaction of alkynylbenzaldehydes in the presence of secondary amines was developed. These were sent to be screened for biological activity.

gold catalysis

carbene

Nazarov

catalysis

enantioselective

hydroamination

phosphite

acyclic

diaminocarbene

Catalysis.

Ligands.

Gold.

Transition metals.

Selectivity Control in 3d Transition Metal-Catalyzed C–H Activation

Loup, Joachim

16 August 2019

No description available.

540

C–H Activation

Catalysis

Transition metal catalysis

Asymmetric catalysis

iron catalysis

nickel catalysis

cobalt catalysis

mechanistic studies

Hydroarylation

chiral ligand

3d transition metals

Mössbauer spectroscopy

Amidation

Chemie  (PPN62138352X)

Palladium- and copper-catalysed heterocycle synthesis

Ball, Catherine Jane

January 2014

A number of privileged starting materials based on aryl halide frameworks have emerged that allow access to a variety of different heterocyclic scaffolds through judicious choice of reaction conditions. This work describes efforts to develop and extend the utility of two of these general heterocycle precursors - ortho-(haloalkenyl)aryl halides A and α-(ortho-haloaryl) ketones B - in conjunction with cascade reactions involving the construction of key carbon-heteroatom bonds via palladium or copper catalysis. Chapter 1 entails an overview of the development of palladium- and copper-catalysed carbon-heteroatom bond forming processes. The application of these processes in heterocycle synthesis using ortho-(haloalkenyl)aryl halide and ortho-haloacetanilides/ α-(ortho-haloaryl) ketone precursors is also described. Chapter 2 focuses on the development of a two-step synthesis of cinnolines using ortho-(haloalkenyl)aryl halides via intermediate protected dihydrocinnoline derivatives C. Chapter 3 demonstrates how the inherent reactivity of protected dihydrocinnoline derivatives C can be harnessed to provide access to functionalised products. A brief target synthesis of a pharmaceutically-relevent cinnoline is also described. Chapter 4 details attempts to develop a novel synthesis of benzothiophenes D from both ortho-(haloalkenyl)aryl halide and α-(ortho-haloaryl) ketone precursors.

547

Catalytic asymmetric carbon-carbon bond formation using alkenes as alkylmetal equivalents

Maksymowicz, Rebecca Marie

January 2014

The development of new methods for carbon-carbon bond formation is a challenging topic at the heart of organic chemistry. Over the past ten years a number of methods for the catalytic asymmetric 1,4-addition of organometallic reagents such as Grignard, organozinc and organoaluminium reagents have been reported. However these reagents suffer from many limitations, including the need for cryogenic temperatures, which prevent their widespread use. Here we have developed a new asymmetric method: the copper-catalysed enantioselective 1,4-addition of alkylzirconium compounds, generated in situM/em>, from alkenes. A general introduction into the formation of carbon-carbon bonds and catalytic asymmetric 1,4-addition reactions is first given. We then focus our attention on hydrometallation reactions and their current use in the addition of alkenyl and alkyl groups in asymmetric 1,4-addition reactions. In Chapter two, we introduce the development of our methodology. We found that by using copper complex <b>(S,S,S)-A</b>, high enantioselectivities can be achieved (up to 96% ee), in the presence of a broad range of functional groups which are often not compatible with comparable methods using pre-made organometallic reagents. The method gives good enantioselectivity at room temperature, in a wide range of solvents, using readily available alkenes. Chapter three discusses the expansion of our method to the 1,4- and 1,6-addition to complex steroids. Modified conditions were then found to enable the addition to &beta;-substituted enones, to form quaternary centres. This is followed by the successful addition to &alpha;,&beta;-unsaturated lactones, another difficult substrate class. All these results gave excellent selectivity. In summary, we have developed a new reaction which offers an alternative to current methods reported in the literature. This robust reaction can tolerate a variety of functional groups and we hope that this will aid in the synthesis of important molecules.

547

Gold(I)-Catalyzed Synthesis of Polycyclic Frameworks Related to Terpenes: Selective Divergent Synthesis of Fused Carbocycles

Barabe, Francis

07 November 2013

Gold catalysis has become an important tool to achieve highly chemoselective p-acid activation. Exceptional reactivity and selectivity are often encountered under mild reaction conditions. These properties have made gold(I) complexes suitable catalysts for tremendous applications in the total synthesis of natural products. The first chapter will highlight a number of total syntheses using gold catalysis as a key step. The second chapter will cover our application of the gold(I)-catalyzed 6-endo-dig carbocyclization for the synthesis of bridgehead-substituted scaffolds and its use toward the synthesis of PPAP natural products. This research has opened our eyes to the utility of biphenylphosphine ligands, particularly JohnPhos, in gold(I)-catalysis. The reactivity and selectivity exhibited by gold(I) complexes is modulated by the nature of the ancillary ligand. Recent research rationalizes the impact of these ligands on the divergent reactivity observed between cationic and carbenoid intermediates. Our desire to favor the 6-endo-dig pathway has led us toward the discovery of another example of the diagonal reactivity that NHC carbene and biphenylphosphine ligands can bring to gold(I)-catalysis. Chapter three will explain the development of a selective gold-catalyzed synthesis of fused carbocycles . Our selective divergent synthesis of fused carbocycles, combined with the Diels–Alder reaction, has brought new synthetic opportunities. Chapter four will describe our approach toward the synthesis of various polycyclic diterpene-related frameworks. Starting with a unique linear precursor, we have developed a new “one-pot” process for the synthesis of three different polycyclic compounds related to the terpenoid family. The facile modulation of the linear precursor and the use of different dienophiles during the Diels–Alder reaction could enable the synthesis of diverse polycyclic analogues based on three principal frameworks. The gold(I)-catalyzed synthesis of fused carbocycles reached some limitations during our study. Regioselective control was found to be substantially more challenging, with terminal alkynes or alkynes bearing a sterically and electronically neutral methyl substituent. In chapter five, we will discuss how the complementarity of silver(I) catalysis to gold(I) catalysis enabled the selective divergent synthesis of three different fused carbocycles from a unique precursor. Moreover, copper(I) catalysis has given access to the 6-endo-dig pathway on terminal alkynes without the formation of a vinylidene intermediate.

gold(I)-catalysis

carbocyclization

fused carbocycles

bridged carbocycles

PPAP natural product

silver(I)-catalysis

copper(I)-catalysis

tandem reaction

Distinguishing between surface and solution catalysis for palladium catalyzed C-C coupling reactions: use of selective poisons

Richardson, John Michael

15 January 2008

This work focuses on understanding the heterogeneous/homogeneous nature of the catalytic species for a variety of immobilized metal precatalysts used for C-C coupling reactions. These precatalysts include: (i) tethered organometallic palladium pincer complexes, (ii) an encapsulated small molecule palladium complex in a polymer matrix, (iii) mercapto-modified mesoporous silica metalated with palladium acetate, and (iv) amino-functionalized mesoporous silicas metalated with Ni(II). As part of this investigation, the use of metal scavengers as selective poisons of homogeneous catalysis is introduced and investigated as a test for distinguishing heterogeneous from homogeneous catalysis. The premise of this test is that insoluble materials functionalized with metal binding sites can be used to selectively remove soluble metal, but will not interfere with catalysis from immobilized metal. In this way the test can definitely distinguish between surface and solution catalysis of immobilized metal precatalysts. This work investigates three different C-C coupling reactions catalyzed by the immobilized metal precatalysts mentioned above. These reactions include the Heck, Suzuki, and Kumada reactions. In all cases it is found that catalysis is solely from leached metal. Three different metal scavenging materials are presented as selective poisons that can be used to determine solution vs. surface catalysis. These selective poisons include poly(vinylpyridine), QuadrapureTM TU, and thiol-functionalized mesoporous silica. The results are contrasted against the current understanding of this field of research and subtleties of tests for distinguishing homogeneous from heterogeneous catalysis are presented and discussed.

Palladium catalysis

Cross coupling reaction

Heterogeneous vs. homogeneous

Selective poisoning

Palladium catalysts

Heterogeneous catalysis

Catalysis

Catalyst poisoning

Gold(I)-Catalyzed Synthesis of Polycyclic Frameworks Related to Terpenes: Selective Divergent Synthesis of Fused Carbocycles

Barabe, Francis

January 2013

Gold catalysis has become an important tool to achieve highly chemoselective p-acid activation. Exceptional reactivity and selectivity are often encountered under mild reaction conditions. These properties have made gold(I) complexes suitable catalysts for tremendous applications in the total synthesis of natural products. The first chapter will highlight a number of total syntheses using gold catalysis as a key step. The second chapter will cover our application of the gold(I)-catalyzed 6-endo-dig carbocyclization for the synthesis of bridgehead-substituted scaffolds and its use toward the synthesis of PPAP natural products. This research has opened our eyes to the utility of biphenylphosphine ligands, particularly JohnPhos, in gold(I)-catalysis. The reactivity and selectivity exhibited by gold(I) complexes is modulated by the nature of the ancillary ligand. Recent research rationalizes the impact of these ligands on the divergent reactivity observed between cationic and carbenoid intermediates. Our desire to favor the 6-endo-dig pathway has led us toward the discovery of another example of the diagonal reactivity that NHC carbene and biphenylphosphine ligands can bring to gold(I)-catalysis. Chapter three will explain the development of a selective gold-catalyzed synthesis of fused carbocycles . Our selective divergent synthesis of fused carbocycles, combined with the Diels–Alder reaction, has brought new synthetic opportunities. Chapter four will describe our approach toward the synthesis of various polycyclic diterpene-related frameworks. Starting with a unique linear precursor, we have developed a new “one-pot” process for the synthesis of three different polycyclic compounds related to the terpenoid family. The facile modulation of the linear precursor and the use of different dienophiles during the Diels–Alder reaction could enable the synthesis of diverse polycyclic analogues based on three principal frameworks. The gold(I)-catalyzed synthesis of fused carbocycles reached some limitations during our study. Regioselective control was found to be substantially more challenging, with terminal alkynes or alkynes bearing a sterically and electronically neutral methyl substituent. In chapter five, we will discuss how the complementarity of silver(I) catalysis to gold(I) catalysis enabled the selective divergent synthesis of three different fused carbocycles from a unique precursor. Moreover, copper(I) catalysis has given access to the 6-endo-dig pathway on terminal alkynes without the formation of a vinylidene intermediate.

gold(I)-catalysis

carbocyclization

fused carbocycles

bridged carbocycles

PPAP natural product

silver(I)-catalysis

copper(I)-catalysis

tandem reaction

ASYMMETRIC TRANSITION METAL CATALYZED CYCLOPROPANATIONS

Kristen E Berger (16023602)

08 June 2023

<p>Cyclopropanes are found in an array of synthetic and natural products. The Simmons–Smith reaction has been one of the most common methods used to synthesize cyclopropanes since it was first discovered in the 1950s. The Simmons–Smith reaction entails the transfer of a carbene (:CH2) from a zinc carbenoid to an alkene, forming a cyclopropane. However, there are still many limitations to the Simmons–Smith method, including poor functional group tolerance and poor regioselectivity in polyalkene substrates. </p> <p>To address the weaknesses in the Simmons–Smith reactions, we have pursued a transition metal-catalyzed method. Our group has reported a cobalt pyridinediimine (PDI) catalyst system to carry out cyclopropanation reactions using gem-dichloroalkanes and gem-dibromoalkanes in order to access nonstabilized carbenes. This method also offers an advantage over diazo transfer chemistry since diazo chemistry requires a stabilizing group to be present in most cases.  This established work has demonstrated a complimentary reactivity to the Simmons–Smith reaction.</p> <p>In this work, we demonstrate that we could expand upon the existing methods of dimethylcyclopropanation to access spirocyclopropanated products by changing the identity of the dichloroalkane. In addition to this reactivity, an enantiopure catalyst that is able to catalyze an enantioselective cyclopropanation was found. We were able to show a broad scope of this new reaction, and mechanistic experiments are carried out in order to probe the mechanism of this reaction. Overall, this thesis offers a new way to access enantiopure dimethylcyclopropane and spirocyclopropanated products.</p>

Organometallic chemistry

Catalysis and mechanisms of reactions

Catalysis and Mechanisms of Reactions

Organometallic Chemistry

Organic Chemistry

Catalysis

Asymmetric

Cyclopropanation

Development of highly active internal steam methane reforming catalysts for intermediate temperature solid oxide fuel cells

Di, Jiexun

January 2013

Fuel processing is one of the essential parts for development of intermediate solid oxide fuel cells (IT-SOFC). Natural gas (methane) is considered as the most abundant and cost effective fuel for the production of hydrogen for IT-SOFC. The primary aim of this thesis is to use a novel precursor material—layered double hydroxide (LDH) – for developing a new type of cost effective, highly active and long lasting catalyst which can reform natural gas in IT-SOFC anode environment. Small amount of noble metals Pd, Rh and Pt are used as promoters to enhance the catalyst’s performance as while maintaining the cost relatively low. The research objectives are achieved by a series of studies including catalysts synthesis, characterisation and the catalytic activities. The thesis initially gives a comprehensive review on fuel cell and SOFC technology, steam methane reforming and reforming catalyst to provide better understanding of the research. Experimental studies include the effects of the synthetic conditions of the LDH precursors and thermal treatments on the physical, chemical behaviours and catalytic activities of the catalysts and promotional effects by noble metals. The LDH derived catalysts compositions, promoter quantities and operating conditions are optimised for the best performance in the IT-SOFC anode environment. A new method for the development of precursor sol for easy coating of the anode is developed and studied. The sol preparation is achieved by acid attack. The sol developed is found to produce better coating and has very high catalytic properties after activation. The catalysts developed were tested for their stability and self-activation ability to ensure its use in the commercial cells. The findings of the present study indicate that the catalysts developed show excellent catalytic performance and these catalysts have very high potential for further commercialisation in IT-SOFC.

621.312429