New Vinylation and Alkynylation Strategies with Hypervalent Iodine Reagents and Diazo Compounds

The development of a sequential copper-catalyzed oxy-alkynylation/intramolecular [4+2] cycloaddition of allenes and arenes was investigated at first. This one-pot protocol allowed the construction of complex polycylic architectures with high efficiency from aryldiazo esters and ethynylbenziodoxolone reagents (EBX). The mild reaction conditions (23 to 90 Â°C) for the dearomatization step was unusual compared to previous literature reports and DFT computations showed that substituents on the aryl ring resulted in favorable dispersive interactions, decreasing the activation energy barrier of the cycloaddition. The bicyclo[2.2.2]octadiene products were successfully applied as ligands for rhodium. The prepared diene-rhodium complexes were extensively characterized by NMR spectroscopy and X-ray crystallography. Finally, an enantiopure ligand having a pseudo C2-symmetry was used in the conjugate addition of phenylboronic acid to cyclohexenone and furnished the Î²-functionalized ketone in good yield and with high enantioselectivity.The vinylation reactions of diazo compounds are scarce. A successful copper-catalyzed vinylation of diazo compounds with vinylbenziodoxolone reagents (VBX) as partners was reported. The transformation allowed an unprecedented gem-oxy-vinylation at the carbene center, providing functionalized Î±-vinyl-hydroxyacid derivatives in high atom and step economy. The products were obtained in excellent yields and contained synthetically versatile functional groups for post-modifications. The development of an enantioselective version of this reaction was limited and further investigations will be required to obtain high enantioselectivities. In addition, a practical synthesis of alkyl-substituted VBX reagents has been established; VBX reagents being limited to aryl substituents until then. Multicomponent reactions provide efficient means to rapidly access molecular diversity. A copper(I)-catalyzed threeâcomponent reaction utilizing diazo compounds, alcohols as nucleophiles and vinyl- or ethynylbenziodoxole reagents, was successfully developed. The transformation allowed the synthesis of highly functionalized allyl and propargyl ethers. The scope is broad, and extensive variations of the three partners of the reaction is possible, leading to maximal structural diversity. Extension of this work to N-nucleophiles was not as straightforward as anticipated, but good results could be obtained with anilines, trifluorodiazoethane and EBX reagents as components.Questions about the reaction mechanisms of the copper-catalyzed difunctionalizations of diazo compounds with VBX and EBX reagents have been frequent all-along this research work. Preliminary results of in-depth mechanistic investigations have been obtained. The initial assumption of an internal alkyne transfer step was first invalidated by DFT computations and was latter refuted experimentally. A complexation between the carboxylate of ethynylbenziodoxolone reagents and the copper catalyst was characterized by NMR spectroscopy and contrasted to a alkyne-copper interaction observed with ethynylbenziodoxole reagents. These two possible complexes were supported by DFT calculations. Finally, non-classical sigmoidal kinetic profiles of the oxy-alkynylation reaction were obtained by in situ 19F NMR monitoring and the Cu-EBX complex is presumably involved in the observed induction periods.

Copper-Catalyzed 1,2-Methoxy Methoxycarbonylation of Alkenes with Methyl Formate and Synthetic Studies Towards the Total Synthesis of Koumine, Voacafricine A and Voacafricine B

Balázs Budai

The development of an unusual oxidative alkene difunctionalization using methyl formate and syn-thetic studies towards alkaloid natural products provide the basis of the thesis. The first chapter details the development of a method that forges methoxycarbonyl radical direct-ly from its most accessible precursor: methyl formate. Although the aforementioned transfor-mation was documented in the literature, no synthetically useful method was developed at the time. We were able to identify conditions that transform methyl formate and simple styrene de-rivatives to value added ï¢-methoxy alkanoates and cinnamic acid derivatives under copper cataly-sis. We also demonstrated that by tethering nucleophilic moieties to the styrene substrates, we could access medicinally important heterocycles such as pyrrolidines, tetrahydrofurans and ï§-lactones. Our method proved to be scalable on each classes of substrates. Mechanistic studies re-vealed that methyl formate has an unprecedented double role in the transformation. It acts as a precursor for methoxycarbonyl radical; furthermore, it is the direct source of the ï¢-methoxy func-tion in the synthesis of ï¢-methoxy alkanoates. A ternary ï¢-diketiminato-Cu(I)-styrene complex, fully characterized by NMR spectroscopy and X-ray crystallographic analysis is capable of catalyz-ing the same transformation. We hypothesize that pre-coordination of electron-rich double bond to copper might play an important role in the polarity-mismatched addition between nucleophilic methoxycarbonyl radical and electron rich olefins. Synthetic studies toward the total synthesis of koumine is discussed in the second chapter. Our synthetic strategy features an oxidative ring closing, Fukuyama indole synthesis and an enantiose-lective Diels-Alder cycloaddition for the construction of the core of koumine skeleton. We designed a rapid route to access 1,2-dihydropyridine derivatives and these compounds were examined as dienes in the Diels-Alder cycloaddition reaction. Despite our efforts, we were unable to effect the [4+2] cycloaddition, which eventually lead us to decide to discontinue our campaign. In chapter three, our synthetic efforts toward voacafricine A and voacafricine B is presented. In our pursuit towards the natural products, we devised and followed a divergent and potentially en-antioselective strategy. We successfully developed a synthetic route to reach the key intermediate in five steps. Despite our efforts, we were not able to construct the remaining F ring of the natural product. Our conformational analysis of advanced intermediates suggest that epimerization of the C14 stereocenter potentially unlocks the desired reactivity and enables us to reach the target mol-ecules. Work towards the total synthesis of voacafricine A and voacafricine B is underway and may focus on the conformational manipulation of advanced intermediates to allow the elaboration of the F ring and complete the synthesis.

EPFL2020

A Well-Defined Ni Pincer Catalyst for Cross Coupling of Non-Activated Alkyl Halides and Direct C-H Alkylation

Oleg Vechorkin

Carbon-carbon bond forming reactions are among the most important and useful methods for organic synthesis. During the last years, significant progress has been made in this field. Whereas many catalysts were developed for the coupling of aryl, alkenyl, and alkynyl halides, non-activated alkyl halides remain challenging substrates, mainly due to unproductive β-hydride elimination and difficulty in oxidative addition of alkyl halides. This dissertation is devoted to the development of a well-defined nickel catalyst for cross coupling of non-activated alkyl halides and direct alkylation of C–H bonds. Chapter 2 describes the synthesis of a new pincer MeN2N ligand and its Ni complexes. This ligand can be obtained by Pd-catalyzed C–N coupling of 2-amino-N,N-dimethylaniline and 2-bromo-N,N-dimethylaniline. Reaction of its Li salt with Ni(dme)Cl2 gives [(MeN2N)Ni-Cl] (1). Complex 1 can be akylated with Grignard reagents to give [(MeN2N)Ni-Alkyl] species. Stability of the alkyl complexes against β-hydride elimination inspired us to use the [(MeN2N)Ni-Cl] complex as a catalyst for cross coupling of carbon nucleophiles with alkyl halides. After investigating different experimental conditions, we found that complex 1 is an active catalyst for cross coupling of non-activated alkyl polyhalides (Chapter 3) and alkyl monohalides (Chapter 4) with alkyl Grignard reagents. The reaction with alkyl monohalides can be done at -35 °C in DMA and only 30min is required to accomplish the formation of the desired products. The high activity of the catalyst resulted in a high group tolerance. Ester, ketone, amide, nitrile, heterocyclic, and acetal groups didn't pose problems. In Chapter 5, the catalysis was extended to include aryl and heteroaryl Grignard reagents as nucleophiles. The best results were obtained with primary alkyl bromides and iodides and cyclic secondary alkyl iodides in THF and at room temperature. Addition of an additive such as TMEDA or bis[2-(N,N-dimethylaminoethyl)]ether (O-TMEDA) was necessary to prevent the formation of undesired homocoupling products. Functionalized Grignard reagents could be readily coupled. The [(MeN2N)Ni-Cl] catalyst was then used for the Sonogashira coupling of alkyl halides with alkynes (Chapter 6). A wide range of functionalized alkyl halides could be used for this reaction. Not only alkyl iodides and bromides but also alkyl chlorides can be used. Moreover, by changing reaction conditions (additive and temperature), selective coupling of C–Br bond in the presence of C–Cl bond, and of C–I bond in the presence of both C–Br and C–Cl bonds can be achieved. This feature allowed us to carry out multiple and selective Sonogashira coupling of the substrates containing different alkyl halide bonds. We could combine Sonogashira coupling with Kumada-Corriu-Tamao coupling. Utilization of these two methods leads to a simple and rapid synthesis of organic molecules. Similar conditions were then applied for the direct alkylation of aromatic heterocycles in Chapter 7. Aromatic heterocyclic compounds are widely used as bio-active molecules, pharmaceuticals, and organic materials. Direct C–H functionalization represents the most straightforward way for the derivatization of these compounds. Despite of the developments during the last years, direct alkylation of C–H bond with alkyl halides is still challenging. Utilization of our [(MeN2N)Ni-Cl] catalyst gives the desired products in high yields and a wide range of aromatic heterocyclic compounds can be used for the reaction. The well-defined nature and a high stability of [(MeN2N)Ni-Cl] complex and its derivatives enabled us to perform detailed mechanistic investigations of the catalytic transformations. Presumed intermediates of catalytic cycles were determined and some of them were synthesized or separated from the reaction mixture. The resting states of the catalysts were also defined in most of the cases, giving important information for the mechanistic elucidation. In the last part (Chapter 8) we developed a direct C–H carboxylation chemistry for aromatic heterocycles. The carboxylation can be done under catalyst-free conditions and with a mild base Cs2CO3. The unstable carboxylic acids were converted to the more stable esters by a one-pot reaction with MeI. A wide substrate scope was achieved.

EPFL2011

Catalytic Enantioselective Transformations with Chiral Cyclopentadienyl Ruthenium(II) Complexes

Sung Hwan Park

The chemistry of cyclopentadienyl ruthenium(II) complexes plays an important role in ruthenium catalysis because of its high potential for various transformations. However, asymmetric catalysis with chiral cyclopentadienyl ruthenium(II) complexes is still at an infant stage, but rapidly developing because of its expected impact on multiple enantioselective applications. This thesis discusses the synthesis of a novel class of chiral cyclopentadienyl ligands, which can be readily accessed by a two-step process from alpha, beta-unsaturated aldehydes and cyclopentadiene. The novel C2-symmetric chiral cyclopentadienyl ligands were complexed with ruthenium(II) and successfully applied in asymmetric catalysis. The cyclopentane-fused CpxRu complex enables the enantioselective synthesis of benzonorcaradienes by coupling of oxa-benzonorbornadienes with internal alkynes in high enantioselectivity (up to 97.5:2.5 er). The reaction mechanism was investigated by computational studies and control experiments. The chiral cyclopentadienyl ruthenium(II) complexes show promising results for other transformations. An alkylative cycloetherification of allenols and aryl vinyl ketones was investigated using binaphthyl-derived chiral cyclopentadienyl ruthenium(II) complex. After an initial optimization study, allenol and phenyl vinyl ketone gave the desired enantio-enriched cyclic ether with a promising enantioselective ratio of 90:10. Furthermore, preliminary studies were undertaken for the [2+1] cycloaddition of enynes via ruthenium vinyl carbenes. Model substrate, 1,6-enyne, delivered the desired enantio-enriched bicyclo[3.1.0]hexane in a good yield of 72% (E:Z = 1.6:1), with enantiomeric ratios of 72.5:27.5 and 63.5:36.5 for the E- and Z-isomer, respectively.

EPFL2020

A Well-Defined Ni Pincer Catalyst for Cross Coupling of Non-Activated Alkyl Halides and Direct C-H Alkylation

Oleg Vechorkin

EPFL2011

Copper-Catalyzed 1,2-Methoxy Methoxycarbonylation of Alkenes with Methyl Formate and Synthetic Studies Towards the Total Synthesis of Koumine, Voacafricine A and Voacafricine B

Balázs Budai

EPFL2020