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41	Acylation hétérogène de Friedel-Crafts en milieu CO2 supercritique / Friedel-Craft reaction in super critical CO2 media Aribert, Nicolas 26 November 2009 (has links) L’acylation de Friedel-Crafts est parmi les réactions les plus fondamentales et les plus utiles pour former des cétones aromatiques. Bien que la mise en oeuvre de ces réactions soit habituellement pénalisante en termes de sous produits formés, de rendement atomique et de quantité de catalyseur utilisée, cette voie est encore largement utilisée dans l’industrie de la chimie fine. Ces dernières années, la prise de conscience de l’impact des activités industrielles sur l’environnement a mené les chimistes à travailler sur de nouvelles voies, moins dangereuses et plus respectueuses de l’environnement.Nous avons considéré ici l’acylation d’un dérivé du benzofurane par un chlorure d’acyle, correspondant à une étape intermédiaire pour la fabrication d’un principe actif pharmaceutique. Dans cette étude, la première proposition a consisté à remplacer les catalyseurs classiques (FeCl3 ou AlCl3) par des catalyseurs solides réutilisables. Dans ce travail, plusieurs catalyseurs (zéolites, résines échangeuses d’ions...) ont d’abord été testés dans des conditions « conventionnelles » , c’est-à-dire en utilisant un solvant organique, afin de déterminer le plus performant, en termes de réactivité, de durée de vie et de réutilisabilité. Une zéolite Y s’est avéré la plus adaptée. Cependant, l’utilisation d’un solvant organique (ici le 1,2-dichlorobenzène) reste discutable et l’utilisation du CO2 supercritique comme solvant a donc été envisagée. Pour cela, nous avons imaginé et dimensionné un réacteur tubulaire à lit fixe de catalyseur fonctionnant sous pression et en continu. Les résultats présentés montrent la faisabilité d’un tel procédé et pose les jalons pour arriver à une ou des solutions pour une meilleure mise en oeuvre industrielle des réactions de Friedel-Crafts. / Friedel-Crafts acylation is among the most fundamental and useful reactions to yield aromatic ketones, but it is one of the less acceptable in terms of unwanted polluting by-products or atom economy because of overconsumption of catalyst which is used in stoichiometric quantities in the conventional process. This route is nevertheless still widely used in the fine chemicals industry. In recent years, awareness of the impact of industrial activities on the environment has lead chemists to work on new chemical routes, less dangerous and more environmentally friendly. We considered here the acylation of a benzofurane derivative by an acid chloride, as an intermediary step for a pharmaceutical product. In this study, one of the first alternative was to replace conventional catalysts (FeCl3 or AlCl3), by reusable solid catalysts. In this work, different catalysts (zeolites, ion-exchange resins...) were first tested in "conventional" conditions, i.e., using an organic solvent (1,2-dichlorobenzene in our case), to determine the best one, in terms of reactivity, lifetime and reusability. The zeolite Y was found the most appropriate. However, the use of an organic solvent still remains questionable and the use of supercritical carbon dioxide as the solvent was also considered. Its inherent properties include non-flammability, mild critical conditions, tuneable solubility near to the critical point and very low environmental impact. The reaction was operated using a specifically designed continuous high pressure fixed bed and results concerning yield and selectivity are presented. These results demonstrate the feasibility of such an approach, which would ultimately yield to better industrial operation of Friedel-Crafts reactions. CO2 supercritique Réacteur à lit fixe continu Oxyde d’indium Acylation de Friedel-Crafts Catalyse hétérogène Zéolite Supercritical CO2 Continuous fixed bed reactor Indium oxide Friedel-Crafts acylation Heterogeneous catalysis Zeolite
42	Estudos visando a síntese total da (+)-cis-triquentrina A / Studies on the synthesis of (+)-cis-trikentrin A Natália Lussari 31 July 2017 (has links) Triquentrinas A são produtos naturais marinhos com atividade biológica e alta complexidade estrutural. Estes fatores tornam estes alcaloides e compostos análogos, como os herbindóis, alvos para a síntese total e plataforma para o desenvolvimento de novas metodologias sintéticas. Nesta Dissertação de Mestrado, procurou-se completar a síntese estereosseletiva da (+)-cis-triquentrina A empregando-se intermediários sintéticos protegidos com o grupo benzila que poderão ser usados para a futura prospecção de novos compostos com atividade biológica. A rota proposta baseia-se na obtenção do ácido (S)-3-(1-benzil-4-etil-1H-indol-7-il)butanóico, um intermediário-chave já descrito por Silva e colaboradores no percurso da síntese total da (+)-trans-triquentrina A, e da finalização da síntese de acordo com a abordagem proposta pelo grupo de RajanBabu para conversão do análogo protegido com grupo tosila à (+)-cis-triquentrina A. A resolução enzimática do intermediário-chave com lipase de Pseudomonas cepacia imobilizada em terra diatomácea foi otimizada, resultando em rendimentos de 32% e 99% ee na metade do tempo descrito anteriormente. Na etapa-chave da síntese, o (S)-ácido foi submetido a uma acilação de Friedel-Crafts intramolecular na presença de anidrido trifluoroacético que produziu o produto de ciclização desejado com 40% de rendimento. Na etapa final da síntese, o intermediário sintético protegido com grupo benzila não pode ser convertido à (+)-cis-triquentrina A, empregando-se a metodologia desenvolvida para a redução do composto análogo tosilado, dada a diferença de reatividade imposta pela troca do grupo protetor. As etapas realizadas até o penúltimo intermediário sintético (S)-8, consta com 10 etapas e rendimento global de 1,3%. viii As diferenças eletrônicas e estruturais relacionadas a diferentes grupos protetores poderão ser refletidas em variações na atividade antiproliferativa de indóis relacionados a triquentrinas. Ainda no interesse de preparar moléculas para envio à análises de atividade antiproliferativa preparou-se um composto relacionado à síntese da trans-triquentrina A tendo como etapa-chave uma contração de anel mediada por I(III) em 21% de rendimento, cujo trabalho foi incluído nos anexos. / Trikentrins A are marine natural products with biological activity and high structural complexity. These factors make these alkaloids and analogous compounds, such as herbidoles, targets for total synthesis and platform for the development of new synthetic methodologies. In this Master\'s Dissertation, we attempted to complete the stereoselective synthesis of (+)-cis-trikentrin A using synthetic intermediates protected with the benzyl group that could be used for the future prospection of new compounds with biological activity. The proposed route is based on the preparation of (S)-3-(1-benzyl-4-ethyl-1H-indol-7-yl) butanoic acid, a key intermediate already described by Silva et al., in the course of total synthesis (+)-trans-triquentrin A, and the final part of the synthesis according to the approach proposed by the RajanBabus group for conversion of the protected analogue with tosyl group to (+)-cis-trikentrin A. The enzymatic resolution of the key intermediate with Pseudomonas cepacia lipase immobilized on diatomaceous earth was optimized, resulting in 32% yield and 99% ee in half the time described above. In the key step of the synthesis, the (S)-acid was subjected to an intramolecular Friedel-Crafts acylation in the presence of trifluoroacetic anhydride which yielded the desired cyclization product in 40% yield. In the final step of the synthesis, the synthetic intermediate protected with benzyl group couldnt be converted to (+)-cis-trikentrin A, employing the methodology developed for the reduction of the tosylated analogous compound, given the difference of reactivity imposed by exchange of the protective group. The steps carried out up to the synthetic intermediate (S)-8, consists of 10 steps and overall yield of 1.3%. Electronic and structural differences related to different protective groups may be reflected in variations in the antiproliferative activity of indoles related to trikentrins. A compound related to the synthesis of trans-triquentrin A having as its key step an I(III) mediated ring contraction in 21% yield was also prepared in the interest of preparing molecules for antiproliferative activity analysis, whose work was included in the appendix. (+)-cis-triquentrina A Alcalóide Indóis Resolução enzimática Síntese assimétrica (+)-cis-trikentrin A alkaloid asymmetric synthesis enzymatic resolution indoles intramolecular Friedel-Crafts acylation
43	Syntheses of Polycyclic Aromatic Compounds with Heteroatom Junctions via Tandem Hetero-Friedel－Crafts Reactions / タンデムヘテロフリーデルクラフツ反応を活用したヘテロ元素縮環部位を有する多環芳香族化合物群の合成 Hashimoto, Sigma 25 March 2013 (has links) Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第17584号 / 工博第3743号 / 新制\|\|工\|\|1570(附属図書館) / 30350 / 京都大学大学院工学研究科物質エネルギー化学専攻 / (主査)教授中村正治, 教授大江浩一, 教授村田靖次郎 / 学位規則第4条第1項該当 Polycyclic Aromatic Compound Hetero-Friedel-Crafts Reaction 多環芳香族化合物ヘテロFriedel-Crafts反応 500
44	Nouvelles applications de la réaction de Passerini dans des réactions de type Friedel-Crafts et Tsuji-Trost. / New applications of Passerini reaction in Friedel-Crafts and Tsuji-Trost reactions. Elmamouni, Elhachemia 02 March 2017 (has links) L’élaboration de synthèses rapides et efficaces de molécules complexes à partir de substrats de départ simples en utilisant un minimum d’étapes constitue un véritable enjeu de la chimie organique contemporaine. Dans ce contexte, les réactions multicomposant, grâce à leur capacité à créer plusieurs liaisons en une étape, offrent une grande efficacité pour synthétiser des structures d’une grande complexité moléculaire. Par ailleurs, la catalyse organométallique s’est considérablement développée ces dernières années, pour devenir un outil de choix pour la formation de liaisons carbone-carbone. La réaction de Tsuji-Trost est notamment un des plus connues dans ce domaineDans le cadre de cette thèse, la découverte de post-condensations originales à partir d’adduits obtenus par les réactions multicomposant impliquant un isonitrile est l’axe majeur de nos recherches. Ces réactions permettent un accès efficace à un large éventail de composés hétérocycliques.Tout d’abord, nous avons développé une nouvelle voie efficace de synthèse des indolylacétamides via une cascade Passerini/Friedel-Crafts à partir d’adduits de Passerini et d’indoles en présence d’un acide de Lewis. Une version monotope de cette cascade a été ainsi développée.Par ailleurs, nous avons exploité la réactivité des hydrazones N-monosubstitués en tant que bis-nucléophile 1,3 en vue de préparer divers dérivés de 2-pyrazolines via une cascade Tsuji-Trost/Cyclisation pallado-catalysée à partir des adduits de Passerini ou de phosphonates. Dans le but de préparer des 2-pyrazolines énantiosélectivement enrichis, une version énantiosélective de cette cascade a été également réalisée à partir d’adduits de Passerini.Enfin, la mise au point d’une nouvelle cascade Tsuji-Trost/Cyclisation exploitant l’allyle méthyle carbonate a permis l’accès rapide à des motifs hétérocycliques de type oxazolidine-2,4-diones en exploitant le dioxyde de carbone généré in situ. / The development of rapid and efficient syntheses of complex molecules from simple starting substrates using a minimum of steps is a real challenge of contemporary organic chemistry. In this context, multicomponent reactions, thanks to their ability to create several one-step bonds, offer a high efficiency in synthesizing structures of great molecular complexity. Moreover, organometallic catalysis has developed considerably in recent years, becoming a tool of choice for the formation of carbon-carbon bonds. The Tsuji-Trost reaction is specially well known in this field.In this thesis, the discovery of the original post-condensations from the adducts obtained by multicomponent reactions involving isonitrile is the major axis of our research. These reactions allow efficient access to a wide range of heterocyclic compounds.First, we have developed a new efficient pathway for the synthesis of indolylacetamides via the Passerini/Friedel-Crafts cascade from the Passerini adducts and indole in the presence of a Lewis acid. A one-pot version of this cascade has been also developed.Furthermore, we have exploited the reactivity of N-monosubstituted hydrazones as 1,3-bis-nucleophile in order to prepare various 2-pyrazoline derivatives via a pallado-catalyzed Tsuji-Trost/Cyclisation cascade from the Passerini adducts or Phosphonates. In order to prepare enantioselectively enriched 2-pyrazolines, the enantioselective version of this cascade was also realized from the Passerini adduct.Finally, the development of a new Tsuji-Trost/Cyclization cascade from the Passerini adducts and the allyl methyl carbonate provide straight fast and efficient access to oxazolidine-2,4-diones heterocyclic units by exploiting the carbon dioxide generated in situ. Réaction de Passerini Indole Friedel-Crafts Hydrazone Tsuji-Trost Oxazolidine-2.4-Diones Passerini reaction Indole Friedel-Crafts Hydrazone Tsuji-Trost Oxazolidine-2.4-Diones
45	Catalytic synthesis of benign bisphenols / Katalytisk syntes av ofarliga bisfenoler Chu, Victoria, Lundqvist, Emma, Hagelin, Hampus January 2022 (has links) This study analyzes the reactivity and selectivity of Friedel-Crafts alkylations using benzylic alcohols and phenols in the presence of a Lewis acid, to synthesize methoxylated bisphenols as a benign alternative to BPA. The degree of methoxylation on the electrophile appears to affect the yield of the reaction while the degree of methoxylation on the nucleophile appears to affect the selectivity. A more methoxylated electrophile results in a lower yield whereas a more methoxylated nucleophile results in a change in ratio between the bisphenol isomers and/or causes other isomers to form. Neither the yield nor the selectivity appears to be affected significantly by the temperature. Bisphenols Vanillyl alcohol Friedel-Crafts alkylation Lewis acid catalysis Sustainability Bisfenoler Vanillylalkohol Friedel-Crafts alkylering Lewissyra-katalys Hållbarhet Organic Chemistry Organisk kemi
46	PREPARATION, CHARACTERIZATION AND APPLICATIONS OF FUNCTIONALIZED CARBON NANO-ONIONS Sreeramoju, Mahendra K 01 January 2013 (has links) Carbon nano-onions (CNOs) discovered by Ugarte in 1992 are multi-layered fullerenes that are spherical analogs of multi-walled carbon nanotubes with diameters varying from 6 nm to 30 nm. Among the various methods of synthesis, CNOs prepared by graphitization of nanodiamonds (N-CNOs) and underwater electric arc of graphite rods (A-CNOs) are the subject of our research. N-CNOs are considered as more reactive than A-CNOs due to their smaller size, high curvature and surface defects. This dissertation focuses on structural analysis and surface functionalization of N- CNOs with diameters ranging from 6—10 nm. Synthetic approaches such as oleum- assisted oxidation, Freidel-Crafts acylation and Billups reductive alkylation were used to functionalize N-CNOs to improve their dispersion properties in aqueous and organic solvents. Functionalized N-CNOs were characterized using various techniques such as TGA, TG-MS, Raman spectroscopy and pH-titrimetry. We designed an experimental method to isolate polycyclic aromatic adsorbates formed on the surface of oleum oxidized N-CNOs (ON-CNOs) and characterized them. A-CNOs, on the other hand are bigger than N-CNOs with diameters ranging from 20—40 nm. In this dissertation, we discuss the preparation of graphene structures by unzipping of A-CNOs using KMnO4 as oxidizing agent. These graphene structures were characterized using powder X-ray diffraction, TGA, BET nitrogen adsorption/desorption studies and compressed powder conductivity. This dissertation also focuses on lithiation/delithiation studies of N-CNOs, A- CNOs and A-CNO-derived graphene structures to use them as negative electrode materials in lithium-ion batteries. The cycling performances of these materials at a charge/discharge rate of C/10 were discussed. The cycling performance of N-CNOs was tested at faster charge/discharge rate of C. Nano-onions oleum-assisted oxidation Friedel-Crafts acylation graphene lithium ion batteries Inorganic Chemistry Materials Chemistry
47	The Catalytic Intramolecular Friedel-Crafts Acylation of Meldrum's Acid Derivatives and The Total Synthesis of Taiwaniaquinol B Fishlock, Daniel January 2005 (has links) The intramolecular Friedel-Crafts acylation of aromatics with Meldrum?s acid derivatives catalyzed by metal trifluoromethanesulfonates and other Lewis acids is reported. Meldrum?s acids are easily prepared, functionalized, handled, and purified. The synthesis of polysubstituted 1-indanones from benzyl Meldrum's acids was investigated thoroughly, and it was shown that a variety of catalysts were effective, whilst accommodating a diversity of functional groups under mild conditions. The scope, limitations, and functional group tolerance (terminal alkene and alkyne, ketal, dialkyl ether, dialkyl thioether, aryl methyl ether, aryl TIPS and TBDPS ethers, nitrile- and nitro-substituted aryls, alkyl and aryl halides) for a variety of 5-benzyl (enolizable Meldrum?s acids) and 5-benzyl-5-substituted Meldrum?s acids (quaternarized Meldrum?s acids), forming 1-indanones and 2-substituted-1-indanones respectively, are delineated. <br ><br /> This method was further applied to the synthesis of 1-tetralones, 1-benzosuberones, and the potent acetylcholinesterase inhibitor donepezil. <br ><br /> Mechanistic investigations were undertaken to determine the rate-determining step in the acylation sequence using Meldrum?s acid, as well as to examine the role of the Lewis acid catalyst. Enolizable Meldrum?s acid derivatives can react via an acyl ketene intermediate under thermal conditions, while quaternarized Meldrum?s acid derivatives are thermally stable and only act as effective Friedel-Crafts acylating agents in the presence of a Lewis acid catalyst. <br ><br /> The total synthesis of (??)-Taiwaniaquinol B was completed. This natural product was the first ever isolated containing an unusual 6-5-6 fused ring system, and it also contains a hexasubstituted aromatic ring, and two all-carbon quaternary centers. This synthesis was accomplished via an intramolecular Friedel-Crafts acylation/carbonyl a-<em>tert</em>-alkylation reaction that exploits the unique chemistry of Meldrum?s acid. This novel methodology can be used to access a variety of highly substituted fused ring systems of various sizes. Chemistry Friedel-Crafts acylation Meldrum's acid Taiwaniaquinol B synthesis catalysis alkylation indanone tetralone arylketone
48	Synthesis of Novel Azetidines Thaxton, Amber 20 December 2013 (has links) Azetidine is a four-membered nitrogen-containing heterocyclic ring that has recently received a great deal of attention as a molecular scaffold for the design and preparation of biologically active compounds. Structure-activity studies employing functionalized azetidines have led to the development of variety of drug molecules and clinical candidates encompassing a broad spectrum of biological activities. Herein, the synthesis a novel series of 3-aryl-3-arylmethoxyazetidines is described. Selected 3-aryl-3-arylmethoxyazetidines were evaluated for their binding affinity to multiple monoaminergic transporters for the potential treatment of methamphetamine addiction. It was discovered that this scaffold exhibits high binding affinity (nM) for both the serotonin and dopamine transporters. In addition, a new method was developed for the synthesis of 3,3-diarylazetidines. This new approach provides a facile and efficient method to synthesize a variety of diaryl heterocycles including 3,3-diarylazetidines, 3,3-diarylpyrrolidines, and 4,4-diarylpiperidines in moderate to good yields. Medicinal and Pharmaceutical Chemistry Organic Chemistry
49	Enantioselective, Bronsted Acid-Catalyzed Additions of Nitrogen and Carbon Nucleophiles to Imines Rowland, Gerald B, Jr. 03 July 2008 (has links) The development of enantioselective reaction methodology has been at the forefront of research in both academic and industrial research laboratories due to the importance of chiral molecules in biological systems. An emerging area of research in the development of enantioselective reaction methodology has been the development of organocatalytic reactions. Organocatalysis, the use of small, chiral organic molecules as catalysts, has the advantage over traditional Lewis acid catalysis in that the reactions in general produce less toxic by-products. One recent breakthrough in the development of enantioselective methodology has been the development of chiral phosphoric acids as organocatalysts. Chiral phosphoric acids have been shown to be excellent catalysts for a wide variety of reactions. In this thesis chiral phosphoric acid-catalyzed enantioselective reaction methodologies have been developed for the addition of sulfonamides and indoles to imines. The development of Bronsted acid-catalyzed amidation of imines allows for an expedient route for the synthesis of N,N-aminals, which have been incorporated into a wide variety of biologically active compounds. Initial studies were undertaken to determine the practicality of a Bronsted acid-catalyzed method for the addition of amides to N-Boc protected imines. Over 20 achiral Bronsted acids were screened, and it was found that phenylphosphinic acid and trifluoromethanesulfinimide were both excellent catalysts for the addition of amides to a variety of imines giving the respective products in excellent yield. The methodology was extended to the development of an enantioselective method for the addition of sulfonamides to imines. It was found that a chiral phosphoric acid derived from the VAPOL ligand was suitable for this purpose. The developed methodology is capable of tolerating a wide variety of functional groups allowing for the preparation of the N, N-aminal products in excellent yield and enantioselectivities. An enantioselective phosphoric acid-catalyzed aza-Friedel-Crafts reaction between N-benzylindoles derivatives and N-benzoyl protected imines has been developed. A catalyst derived from the BINOL backbone was found to be the optimum catalyst for the enantioselective transformation. The developed methodology was capable of tolerating a wide variety of functional groups and provides an expedient route for the synthesis of chiral 3-indolylmethanamines. organocatalysis enantioselective catalysis aza-Friedel-Crafts aminal imines American Studies Arts and Humanities
50	Development of highly enantioselective organocatalyzed transformations Breistein, Palle January 2011 (has links) No description available. Asymetric catalysis aldehydes proline derivatives transition metals Friedel-Crafts conjugate addition boration α-alkylation

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