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1,4‐Addition of TMSCCl3 to nitroalkenes: efficient reaction conditions and mechanistic understandingWu, Na, Wahl, B., Woodward, S., Lewis, W. 02 June 2020 (has links)
Yes / Improved synthetic conditions allow preparation of TMSCCl3 in good yield (70 %) and excellent purity. Compounds of the type NBu4X [X=Ph3SiF2 (TBAT), F (tetrabutylammonium fluoride, TBAF), OAc, Cl and Br] act as catalytic promoters for 1,4‐additions to a range of cyclic and acyclic nitroalkenes, in THF at 0–25 °C, typically in moderate to excellent yields (37–95 %). TBAT is the most effective promoter and bromide the least effective. Multinuclear NMR studies (1H, 19F, 13C and 29Si) under anaerobic conditions indicate that addition of TMSCCl3 to TBAT (both 0.13 M ) at −20 °C, in the absence of nitroalkene, leads immediately to mixtures of Me3SiF, Ph3SiF and NBu4CCl3. The latter is stable to at least 0 °C and does not add nitroalkene from −20 to 0 °C, even after extended periods. Nitroalkene, in the presence of TMSCCl3 (both 0.13 M at −20 °C), when treated with TBAT, leads to immediate formation of the 1,4‐addition product, suggesting the reaction proceeds via a transient [Me3Si(alkene)CCl3] species, in which (alkene) indicates an Si⋅⋅⋅O coordinated nitroalkene. The anaerobic catalytic chain is propagated through the kinetic nitronate anion resulting from 1,4 CCl3− addition to the nitroalkene. This is demonstrated by the fact that isolated NBu4[CH2=NO2] is an efficient promoter. Use of H2C=CH(CH2)2CH=CHNO2 in air affords radical‐derived bicyclic products arising from aerobic oxidation. / Engineering and Physical Sciences Research Council (EPSRC) Grant EP/K000578/1.
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Design, synthèse et activité organocatalytique de spiropyrazolidinones pour l'activation iminium et réactions d'échanges H/D organocatalytiques / Design, synthesis and organocatalytic activity of spiropyrazolidinones for iminium activation and organocatalytic H/D exchange reactionsPerez, Fabien 16 December 2016 (has links)
Depuis les années 2000, le domaine de l’organocatalyse est en plein essor. Une vue d’ensemble des différents modes d’activation organocatalytique fera l’objet du premier chapitre. Malgré les avancées considérables faites dans l’activation par liaison covalente, particulièrement dans l’aminocatalyse par activation iminium, des progrès sont encore possibles au niveau de l’activité catalytique des organocatalyseurs. Une large partie du travail détaillé dans le deuxième chapitre concerne le design puis le développement de deux voies de synthèse permettant de préparer une nouvelle classe d’organocatalyseurs pour l’activation iminium ainsi que leurs tests d’activité catalytique. Enfin, le troisième chapitre est consacré à l’étude de réactions d’échange H/D organocatalysées par les carbènes N-hétérocycliques. / Since the begining of 2000, the field of organocatalysis has performed a lot of improvements. An overview of the different modes of activation of this field will constitute the first chapter. Despite the improvements in the domain of activation by covalent bond, specially for the iminium activation, some enhancements of the catalytic activity of organocatalysts are still possible. A major part of the work developped in the second chapter will be focused on the design then the synthesis of a new class of organocatalysts for iminium activation and their catalytic activity tests. Then the third chapter will be dedicated to the H/D exchange reactions organocatalyzed by N-heterocyclic carbenes.
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O uso de azalactonas em síntese orgânica: preparação, aplicação em reações de formação de ligação C-C e em síntese totalPinheiro, Danielle Lobo Justo 09 September 2018 (has links)
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Previous issue date: 2018-09-09 / CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Azalactonas são heterociclos derivados de aminoácidos protegidos e ciclizados. Por conter em sua estrutura um sítio eletrofílico, um sítio pro-nucleofílico, além de um sítio nucleofílico ou eletrofílico (que será determinado pelas condições reacionais), esses compostos são extremamente versáteis. Nesse trabalho é demonstrado a reação das azalactonas com o reagente de Schwartz, que através de uma de redução quimiosseletiva gera derivados de aminoaldeídos com excelentes rendimentos em apenas 2 minutos de reação. Outra reação de redução quimiosseletiva demonstrada no trabalho envolve o uso de azalactonas de Erlenmeyer, hidrogênio e Pd/C como catalisador. Dessa forma, azalactonas saturadas funcionalizadas, foram possíveis de ser obtidas em uma metodologia simples, com excelentes rendimentos. O processo foi ainda adaptado para reações em um sistema one-pot, produzindo assim, adutos de Michael, Mannich e produtos de abertura de maneira simples e eficiente. O sítio nucleofílico das azalactonas também é explorado em reações de dimerização diastereosseletivas, utilizando uma base de Brønsted formada in situ pela reação entre acetonitrila e sal tricloroacetato de potássio ou sódio. O mecanismo da reação e estudos cinéticos são demonstrados a partir de uma análise obtida por experimentos online no RMN de ¹H. Além disso, um análogo de um produto natural é obtido através de uma redução estereosseletiva dos dímeros. O sítio nucleofílico das azalactonas também é explorado em reações de carbonilação α-arilativa catalisadas por Pd, utilizando o sistema de duas câmaras, seguido de sua abertura, obtendo, dessa forma, aminoácidos α,α-dissubstituídos protegidos. O mecanismo da reação é proposto após reações controle terem sido realizadas. Os mesmos aminoácidos também puderam ser sintetizados e marcados com o ¹³C. Esses compostos marcados foram aplicados em reações quimiosseletivas, como a reação de descarboxilação de Krapcho, reduções quimiosseletivas, e síntese de heterociclos como as oxazolonas e pirazolonas. / Azlactones are heterocycles derived from amino acids. There are an electrophilic site, a pro-nucleophilic site, and a nucleophilic or electrophilic site (determined by the reaction conditions). These compounds are extremely versatile. In this work the reaction of the azlactones with Schwartz reagent is demonstrated. A chemosselective reduction of these compounds is possible to generate aminoaldehydes in excellent yields in only 2 minutes reaction. Chemosselective reduction of Erlenmeyer azlactones is also demonstrated by using hydrogen gas and Pd / C as a catalyst. In this way, functionalized saturated azlactones are possible to obtain in excellent yields. The process was further adapted to reactions in a one-pot system, producing Michael, Mannich and opening products in a simple and efficient manner. The nucleophilic site of azlactones is also explored in the diastereoselective dimerization reactions promoted by a Brønsted base, affording by the reaction in situ between acetonitrile and potassium or sodium trichloroacetate salt. The mechanism of the reaction and kinetic studies are demonstrated from an analysis obtained by ¹H NMR online experiments. In addition, a stereoselective reduction of a dimer analogue gave a natural product in high both yield and diastereoselectivity. The nucleophilic site of the azalactones is exploited in Pd catalyzed α- arylation carbonylation reactions, using the two-chamber system, followed by their opening, thereby obtaining protected α,α -disubstituted amino acids. The mechanism of the reaction is proposed based on control reactions. The same amino acids could also be synthesized with ¹³C-labeled CO. These coumpounds were applied in chemosselective reactions, such as krapcho decarboxylation reaction, chemosselective reduction, and synthesis of heterocycles such as oxazolones and pyrazolones.
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