Sonogashira coupling

Summary

The Sonogashira reaction is a cross-coupling reaction used in organic synthesis to form carbon–carbon bonds. It employs a palladium catalyst as well as copper co-catalyst to form a carbon–carbon bond between a terminal alkyne and an aryl or vinyl halide. :* R1: aryl or vinyl :* R2: arbitrary :* X: I, Br, Cl or OTf The Sonogashira cross-coupling reaction has been employed in a wide variety of areas, due to its usefulness in the formation of carbon–carbon bonds. The reaction can be carried out under mild conditions, such as at room temperature, in aqueous media, and with a mild base, which has allowed for the use of the Sonogashira cross-coupling reaction in the synthesis of complex molecules. Its applications include pharmaceuticals, natural products, organic materials, and nanomaterials. Specific examples include its use in the synthesis of tazarotene, which is a treatment for psoriasis and acne, and in the preparation of SIB-1508Y, also known as Altinicli

Official source

https://en.wikipedia.org/wiki/Sonogashira_coupling

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Ni-catalyzed Sonogashira coupling of nonactivated, β-H- containing alkyl halides, including chlorides, is reported. The coupling is tolerant to a wide range of functional groups, including ether, ester, amide, nitrile, keto, heterocycle, acetal, and aryl halide, in both coupling partners. The coupling can be selective for a specific C−X bond (X = I, Br, Cl) and allows for orthogonal functionalization of alkyl halides with multiple reactive sites.

2009

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

This dissertation is devoted to the development of well-defined nickel complexes as catalysts for cross coupling processes of alkyl electrophiles. In chapter one, we summarize recent cross coupling methodologies of alkyl electrophiles using nickel based catalysts. The description of each study includes the coupling conditions, the substrate scope and the mechanistic considerations. In chapter two, we report the development of high diastereoselective alkyl-alkyl Kumada coupling method for 1,3- and 1,4-substituted cyclohexyl halides and tetrahydropyrans using an amido bis(amine) nickel complex "Nickamine" as catalyst. The stereochemical properties of the starting materials and of the coupling products were determined by NMR techniques. The mechanistic investigations of the coupling provided evidence of a reversible activation of the alkyl halide. In chapter three, we present the synthesis of new bidentate amido â amine ligands derived from 2,5-dimethylpyrrolidine or Î±-methylbenzylamine. The ligands were used to synthesize well-defined bidentate nickel complexes by transmetallation from the corresponding lithium complexes. A complex having an Î±-methylbenzylamine derived ligand and 2,4-lutidine as co-ligand was an effective catalyst for the coupling of non-activated secondary iodides with alkyl Grignard reagents. An enantiomerically pure version of this complex was synthesized and no racemization was observed during the synthesis. The chiral complex showed no asymmetric induction capacity as a cross coupling catalyst. In chapter four, the synthesis of new amido bis(amine) pincer ligands derived from Î±-methylbenzylamine or pyrrolidine are described. The metallation of a NNN ligand derived from Î±-methylbenzylamine was not possible by transmetallation from the corresponding lithium complex or by oxidative addition from the corresponding chloroamine. A well-defined pincer nickel complex was synthesized by Li â Ni transmetallation using a NNN ligand having dimethyl amino and pyrolidine donors. Crystal structure analysis shows that the pyrrolidine donor is slightly less hindered. This complex is an effective catalyst for alkyl-alkyl and alkyl-aryl Kumada coupling of non-activated primary and secondary alkyl halides. The coupling process shows good functional group tolerance. This is the first time that a well-defined nickel pincer complex shows high catalytic activity for Kumada coupling reactions of sterically hindered alkyl substrates. In chapter 5, a well-defined nickel pincer complex bearing an alkyl amine donor is synthesized. The complex is able to catalyzed direct coupling of non-activated primary halides with terminal alkynes at room temperature. The catalysis has a good substrate scope and high functional group tolerance. Kinetic data suggest that the new pincer ligand is hemilabile, and the dissociation of the alkyl amine donor is the turnover-determining step of the catalysis. An intermediate Ni-alkynyl species has been isolated and structurally characterized. The reactivity of this species gives insight into the nature of the active species for the activation of alkyl halide.

EPFL2015

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