Shlomy Arava scite author profile

Enolonium species/iodo(III)enolates of carbonyl compounds have been suggested to be intermediates in a wide variety of hypervalent iodine induced chemical transformations of ketones, including α-C-O, α-C-N, α-C-C, and α-carbon-halide bond formation, but they have never been characterized. We report that these elusive umpoled enolates may be made as discrete species that are stable for several minutes at -78 °C, and report the first spectroscopic identification of such species. It is shown that enolonium species are direct intermediates in C-O, C-N, C-Cl, and C-C bond forming reactions. Our results open up chemical space for designing a variety of new transformations. We showcase the ability of enolonium species to react with prenyl, crotyl, cinnamyl, and allyl silanes with absolute regioselectivity in up to 92 % yield.

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Enolonium Species—Umpoled Enolates

Arava

Kumar

Maksymenko

et al. 2017

Angewandte Chemie

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Enolonium species/iodo(III)enolates of carbonyl compounds have been suggested to be intermediates in a wide variety of hypervalent iodine induced chemical transformations of ketones, including α‐C−O, α‐C−N, α‐C−C, and α‐carbon–halide bond formation, but they have never been characterized. We report that these elusive umpoled enolates may be made as discrete species that are stable for several minutes at −78 °C, and report the first spectroscopic identification of such species. It is shown that enolonium species are direct intermediates in C−O, C−N, C−Cl, and C−C bond forming reactions. Our results open up chemical space for designing a variety of new transformations. We showcase the ability of enolonium species to react with prenyl, crotyl, cinnamyl, and allyl silanes with absolute regioselectivity in up to 92 % yield.

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Direct Umpolung Morita–Baylis–Hillman like α‐Functionalization of Enones via Enolonium Species

et al. 2020

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Herein we report on the umpolung of Morita–Baylis–Hillman type intermediates and application to the α‐functionalization of enone C−H bonds. This reaction gives direct access to α‐chloro‐enones, 1,2‐diketones and α‐tosyloxy‐enones. The latter are important intermediates for cross‐coupling reaction and, to the best of our knowledge, cannot be made in a single step from enones in any other way. The proposed mechanism is supported by spectroscopic studies. The key initial step involves conjugate attack of an amine (DABCO or pyridine), likely assisted by hypervalent iodine acting as a Lewis acid leading to formation of an electrophilic β‐ammonium‐enolonium species. Nucleophilic attack by acetate, tosylate, or chloride anion is followed by base induced elimination of the ammonium species to give the noted products. Hydrolysis of α‐acetoxy‐enones lead to formation of 1,2‐diketones. The α‐tosyl‐enones participate in Negishi coupling reactions under standard conditions.

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Strategies for the Synthesis of N-Arylammonium Salts

Arava

Diesendruck

2017

Synthesis

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The N-arylation of tertiary amines to provide sp3 quaternary ammonium salts is a challenge in organic chemistry. To date, no general method for such arylations has been established. Here, we summarize a variety of strategies that have been tested, starting with harsh nucleophilic aromatic substitutions, through to the use of copper catalysis and the application of strong electrophiles, such as phenyl cations and benzynes. The achievements and limitations of each method are summarized, and the challenges yet to be met in the synthesis of charged ammonium compounds are described.1 Introduction2 Alkylation of Anilines: The Menshutkin Reaction3 Arylations3.1 Nucleophilic Aromatic Substitutions by Tertiary Amines3.2 Preparation of N-Arylpyridinum Salts from Zincke and Pyrylium Salts3.3 Arylations Using Phenyl Cations3.4 Copper-Catalyzed Arylation of N-Heteroarenes3.5 Benzynes as Aryl Electrophiles4 Conclusions and Perspective

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Direct Umpolung Morita–Baylis–Hillman like α‐Functionalization of Enones via Enolonium Species

et al. 2020

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show abstract

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Shlomy Arava

Enolonium Species—Umpoled Enolates

Enolonium Species—Umpoled Enolates

Direct Umpolung Morita–Baylis–Hillman like α‐Functionalization of Enones via Enolonium Species

Strategies for the Synthesis of N-Arylammonium Salts

Direct Umpolung Morita–Baylis–Hillman like α‐Functionalization of Enones via Enolonium Species

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