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21	Les complexes cationiques du gallium(III) et de l’indium(III) : de nouveaux outils pour la synthèse organique / Cationic complexes of gallium(III) and indium(III) : new tools for organic synthesis Michelet, Bastien 06 October 2015 (has links) Des complexes NHC du gallium(III) et de l’indium(III) ont été préparés. Ces composés, simples à synthétiser, se sont révélés être beaucoup plus stables que les sels commerciaux de type MX₃ (M = Ga, In ; X = Cl, Br, I). Ces complexes, une fois activés par AgSbF₆, présentent un fort caractère acide de Lewis. [IPr-GaCl₂][SbF₆] s’est ainsi montré très actif en tant qu’acide de Lewis π et a été utilisé comme catalyseur dans différentes réactions impliquant l’activation de fonctions carbonées insaturées. Il a ainsi permis d’effectuer des hydroarylations inter- et intramoléculaires d’alcynes, d’alcènes et d’allènes. La généralité de cette transformation a pu être démontrée dans une réaction tandem de cycloisomérisation/Friedel-Crafts entre un arényne et un nucléophile aromatique. La capacité des complexes cationiques de gallium et d’indium à activer des alcènes a également pu être mise à profit pour la réduction de dérivés styréniques en présence de cyclohexa-1,4-diène comme source d’hydrogène. Et parce que ces complexes permettent la génération de dérivés du styrène par hydroarylation d’alcynes, une cyclisation réductrice d’arénynes sans précédent a pu être développée. Enfin le complexe [IPr-GaCl₂][SbF₆] a été utilisé dans des réaction impliquant l’eau en tant que réactif. Quelques alcynes ont ainsi pu être hydratés et des esters γ,δ-insaturés ont été transformés en lactones. En résumé, nos complexes cationiques de gallium et d’indium peuvent être utilisés dans des réactions généralement considérées comme relevant du domaine des métaux de transition nobles (Au, Pt, Ru…). / NHC complexes of gallium(III) and indium(III) have been prepared. These compounds, easy to synthesize, proved to be much more stable than the commercially-available salts MX₃ (M = Ga, In ; X = Cl, Br, I). These complexes, once activated by AgSbF₆, show a strong Lewis acid character. For instance, [IPr-GaCl₂][SbF₆] showed a high activity as π-Lewis acid and was used as catalyst in several reactions triggered by the activation of unsaturated C-C bonds such as inter- and intramolecular hydroarylations of alkynes, alkenes and allenes. The versatility of this transformation was demonstrated in a cycloisomerization/Friedel-Crafts tandem reaction between an arenyne and an aromatic nucleophile. The ability of cationic complexes of gallium and indium to activate alkenes was also used for the reduction of styrene derivatives with 1,4-cyclohexadiene as hydrogen source. Also, because these complexes are able to generate styrene derivatives by hydroarylation of alkynes, an unprecedented reductive cyclization of arenynes could be developped. Moreover, [IPr-GaCl₂][SbF₆] was used in reactions involving water as reagent. Several alkynes were hydrated and γ,δ-unsaturated esters were transformed into lactones. In summary, our cationic complexes of gallium and indium can be used in reactions generally catalyzed by noble metals (Au, Pt, Ru…). Gallium Indium Acide de Lewis Catalyse Friedel-Crafts Hydrogénation Gallium Indium Lewis acid Catalysis Friedel-Crafts Hydrogenation
22	ORGANOMETALLIC HETEROCYCLES AND ACENE-QUINONE COMPLEXES OF RUTHENIUM, IRON AND MANGANESE Pokharel, Uttam Raj 01 January 2012 (has links) A variety of organometallic-fused heterocycles and acene quinones were prepared and characterized. This work was divided into three parts: first, the synthesis of 5,5-fused heterocyclic complexes of tricarbonylmanganese and (1’,2’,3’,4’,5’-pentamethylcyclopentadienyl)ruthenium; second, the synthesis of 1,2-diacylcyclopentadienyl p-cymene complexes of ruthenium(II); and third, synthesis of cyclopentadienyl-fused polyacenequinone complexes of ruthenium, iron and manganese. The first examples of the convenient, versatile and symmetric cyclopentadienyl-fused heterocycle complexes of (1’,2’,3’,4’,5’-pentamethylcyclopentadienyl)ruthenium(II) and tricarbonylmanganese(I) were synthesized starting from (1,2-dicarbophenoxycyclopentadienyl)sodium. The sodium salt was transmetalated using [MnBr(CO)5] and 1/4 [Ru(μ3-Cl)(Cp)]4 to give [Mn(CO)3{η5-C5H3(CO2Ph)2-1,2}] and [Ru{η5-C5H3(CO2Ph)2-1,2}(Cp)]. The diester complexes were saponified under basic conditions to obtain the corresponding dicarboxylic acids. The dicarboxylic acids were used to synthesize unique cyclopentadienylmetal complexes including diacyl chlorides, anhydrides, thioanhydrides and p-tolyl imides of ruthenium and manganese. Similarly, a series of 1,2-diacylcyclopentadienyl-p-cymene cationic complexes of ruthenium were synthesized using thallium salt of 2-acyl-6-hydroxyfulvene and [Ru(η6-p-cymene)(μ-Cl)Cl]2 in a 2:1 ratio with an intension of converting them into heterocycle-fused cationic sandwich complexes. However, our attempts of ring closing on 1,4-diketons with sulfur or selenium were unsuccessful. A methodology involving the synthesis of metallocene-fused quinone complexes was employed starting from pentamethylruthenocene-1,2-dicarboxylic acids. The diacyl chloride was prepared in situ from the dicarboxylic acids and used for Friedel-Crafts acylation. We observed single-step room-temperature diacylation of aromatics, including benzene, o-xylene, toluene, 1,4-dimethoxybenzene and ferrocene with pentamethylruthenocene-1,2-diacyl chloride to obtain the corresponding quinone complexes. Similarly, we synthesized mononuclear and binuclear γ-quinones by aldol condensation of 1,2-diformylcyclopentadienylmetal complexes with cyclohexane-1,4-dione or 1,4-dihydroxyarenes. The third methodology involves the Friedel-Crafts acylation of ferrocene with 2-carbomethoxyaroyl chlorides followed by saponification, carbonyl reduction, and ring closing by second Friedel-Crafts acylation to give Ferrocene-capped anthrone-like tricyclic and tetracyclic ketones. The oxidation of the ketones gave [3,4-c]-fused α-quinone complexes of iron. The oxidative and reductive coupling, enolization and C-alkylation of the anthrone complex were studied. Solvolysis of α-carbinol gave α-ferrocenylcarbenium salt, which underwent dimerization on treatment with non-nucleophilic base. We were successful to trap the in situ generated trimethylsilylenol ether of ferrocene-anthrone using dienophiles like N-phenylmaleimide or dimethylacetylenedicarboxylate under Diels-Alder conditions. Pentamethylruthenocene cymantrene ferrocene Aldol condensation Friedel-Crafts acylation Chemistry
23	Contribución teórica a la interpretación de la catálisis de Friedel-Crafts Mora Canales, Francisco 16 June 1981 (has links) No description available. Catálisis de Friedel-Crafts Alquilación de compuestos aromáticos Haluros de alquilo Química Física
24	Development of New Domino Reactions of Alkylidene Meldrum’s Acids Involving Friedel-Crafts Chemistry and Catalytic Conjugate Allylation of Alkylidene Meldrum’s Acids Dumas, Aaron January 2009 (has links) Alkylidene Meldrum’s acids are very reactive acceptors in conjugate additions, and are known to be significantly more electrophilic than other α,β-unsaturated carbonyl electrophiles. They also offer advantages in terms of ease of preparation, purification and storage. Despite this, they are relatively underused in organic synthesis, and have been treated as something of a curiousity in the literature. The goal of my research was to demonstrate the utility of these molecules in new reactions that are not readily available to other electrophiles. To facilitate this work, new conditions for the Knoevenagel condensation of aldehydes with Meldrum’s acid were developed. This allowed access to a broader range of monosubstituted alkylidenes than was previously possible from any single method. In a reaction that exploits the acylating ability of Meldrum’s acid, a domino addition of phenols to alkylidene Meldrum’s acids was developed. Here, Yb(OTf)3 catalyzed the addition of a phenol to the alkylidene as well as acylation through activation of the electrophile. The unique properties of these acceptors permitted synthesis of 3,4-dihydrocoumarins and coumarins through C-alkylation/O-acylation, and also 4-chromanones and chromones through O-alkylation/C-acylation. The predictable and general reversal of chemoselectivity is dependent on the number of substituents on the alkylidene. The same properties that make alkylidene Meldrum’s acids strong electrophiles also make them excellent dienophiles. A one-pot Diels-Alder/Friedel-Crafts process was used as an entry into the 6-5-6-tricyclic skeleton of a family of natural products that have been of interest in our group. The modular nature of the reaction allowed structural variation at nearly every position around both 6-membered rings. An attempted extension of this work into the synthesis of ergot alkaloids provided insight into the factors affecting Friedel-Crafts acylation of 4-substituted indoles. These results provided a highly regioselective entry into 4,5-fused indole ring systems. The electrophilicity of alkylidene Meldrum’s acids was combined with Lewis acid activation for development of a mild conjugate allylation reaction. The use of allyltriphenyltin as nucleophile for addition to monosubstituted alkylidenes avoided many of the practical disadvantages of working with trialkylstannanes. By employing such a relatively weak allylating agent, functional group compatibility was maximized to include groups susceptible to nucleophilic allylation. Additions to chiral, non-racemic alkylidenes were highly diastereoselective. It was also shown that functionalized all-carbon quaternary stereocentres can be formed by this process. alkylidene Meldrum's acid domino conjugate allylation Friedel-Crafts Chemistry
25	Development of New Domino Reactions of Alkylidene Meldrum’s Acids Involving Friedel-Crafts Chemistry and Catalytic Conjugate Allylation of Alkylidene Meldrum’s Acids Dumas, Aaron January 2009 (has links) Alkylidene Meldrum’s acids are very reactive acceptors in conjugate additions, and are known to be significantly more electrophilic than other α,β-unsaturated carbonyl electrophiles. They also offer advantages in terms of ease of preparation, purification and storage. Despite this, they are relatively underused in organic synthesis, and have been treated as something of a curiousity in the literature. The goal of my research was to demonstrate the utility of these molecules in new reactions that are not readily available to other electrophiles. To facilitate this work, new conditions for the Knoevenagel condensation of aldehydes with Meldrum’s acid were developed. This allowed access to a broader range of monosubstituted alkylidenes than was previously possible from any single method. In a reaction that exploits the acylating ability of Meldrum’s acid, a domino addition of phenols to alkylidene Meldrum’s acids was developed. Here, Yb(OTf)3 catalyzed the addition of a phenol to the alkylidene as well as acylation through activation of the electrophile. The unique properties of these acceptors permitted synthesis of 3,4-dihydrocoumarins and coumarins through C-alkylation/O-acylation, and also 4-chromanones and chromones through O-alkylation/C-acylation. The predictable and general reversal of chemoselectivity is dependent on the number of substituents on the alkylidene. The same properties that make alkylidene Meldrum’s acids strong electrophiles also make them excellent dienophiles. A one-pot Diels-Alder/Friedel-Crafts process was used as an entry into the 6-5-6-tricyclic skeleton of a family of natural products that have been of interest in our group. The modular nature of the reaction allowed structural variation at nearly every position around both 6-membered rings. An attempted extension of this work into the synthesis of ergot alkaloids provided insight into the factors affecting Friedel-Crafts acylation of 4-substituted indoles. These results provided a highly regioselective entry into 4,5-fused indole ring systems. The electrophilicity of alkylidene Meldrum’s acids was combined with Lewis acid activation for development of a mild conjugate allylation reaction. The use of allyltriphenyltin as nucleophile for addition to monosubstituted alkylidenes avoided many of the practical disadvantages of working with trialkylstannanes. By employing such a relatively weak allylating agent, functional group compatibility was maximized to include groups susceptible to nucleophilic allylation. Additions to chiral, non-racemic alkylidenes were highly diastereoselective. It was also shown that functionalized all-carbon quaternary stereocentres can be formed by this process. alkylidene Meldrum's acid domino conjugate allylation Friedel-Crafts Chemistry
26	Die Entwicklung neuer Lewis- und Brønsted-Säure-katalysierter Friedel-Crafts-Alkylierungen Nachtsheim, Boris Johannes Unknown Date (has links) (PDF) Frankfurt (Main), Univ., Diss., 2009
27	Heterogeneous Superacidic Catalyst for Friedel-Crafts Alkylation Cutright, Josh T., Jauregui, Robert L., Edwards, Savana D., Mohseni, Ray M., Vasiliev, Aleksey 07 April 2022 (has links) Long-chain alkylbenzenes are industrially synthesized precursors to commercial surfactants such as laundry detergent. The process of benzene alkylation currently utilizes homogeneous acidic catalysts (HF, AlCl3, etc.), which cause a multitude of problems such as production of toxic waste, hazards to workers, and corrosion of expensive industrial equipment. These problems can be avoided by the use of heterogeneous highly acidic catalysts. Solid catalysts do not corrode equipment and are relatively simple to remove from the post-reaction mixture. Phosphotungstic acid (PTA) supported on silica gel could be a possible catalyst due to its high acidity with an estimated pKa ≈ -13. However, it is soluble in many solvents and can be leached from silica gel during the process. The objective of this research is to obtain a superacidic stable heterogeneous catalyst containing covalently immobilized PTA, and evaluate its activity and stability in the alkylation of benzene by long-chain alkenes. The catalyst PTA/SiO2 was prepared via the sol-gel method by co-condensation of PTA with tetraethoxysilane in acidic media. Surfactant Pluronic P123 was used as a template to form porous structure. Then the catalyst was granulated to prevent caking of the powder during reaction. For granulation, the powder PTA/SiO2 was mixed with aluminum oxide (an inert adhesive agent) and pressured at 7 t to make tablets. The tablets were converted to granules of 1-2 mm diameter and calcined at 400 °C to remove moisture. FT-IR spectra confirmed the presence of PTA in the obtained material. Analysis by atomic absorption spectroscopy showed PTA contents of 0.027 mmol/g. The catalyst was mesoporous with BET surface area of 168 m2/g and mean particle size of 856 nm. The reaction of alkylation of benzene by octene-1 and decene-1 was carried out in a fixed bed flow reactor at 200-250 °C where mixtures of benzene and an alkene flowed through the catalyst with constant rate. Products were collected and analyzed on a GC chromatograph. The catalyst demonstrated good catalytic activity at temperatures above 200 °C. In all experiments mixtures of isomeric alkylbenzenes were obtained with 2-phenylalkanes as main products. Decreasing of flow rate and ratio alkene:benzene favored conversion of alkenes. Characterization of the catalyst after the reaction showed little changes in porosity and particle size. No leaching of PTA was observed. However, carbon deposits were found on the catalyst that requires regeneration before next use in catalysis. Friedel-Crafts alkylation heterogeneous superacidic catalyst Chemical Sciences
28	Bismuth Triflate Catalyzed Friedel-Crafts Acylations of Sydnones Fisher, Jennifer Ann 05 December 2005 (has links) No description available. Chemistry, Organic Friedel-Crafts metal triflates bismuth triflate sydnone
29	Routes to Acylated Sydnone Esters Balaguer, Amanda Marie 23 September 2011 (has links) No description available. Chemistry sydnone Friedel Craft acylation metal triflate microwave reaction
30	Funcionalização de grafite em condições de Friedel-Crafts / Graphite Functionalization in Friedel-Crafts conditions. Sawazaki, David Tatsuo Atique 30 September 2013 (has links) Neste trabalho foi realizada a funcionalização de grafite sem prévio tratamento em condições de Fridel-Crafts. Considerando que a grafite não possui hidrogênio em sua estrutura, não se observa uma reação de substituição eletrofílica. Por outro lado, o trabalho mostra o papel da umidade presente no grafite na reação de funcionalização. Dessa forma, foi proposto um mecanismo para a reação com a participação da água adsorvida na grafite estabilizando o carbocátion formado. O grafite funcionalizado obtido na reação foi utilizado como material eletródico. Para a reação de funcionalização, quatro moléculas foram utilizadas: ácido ferrocenomonocarboxílico, cloreto de 4-nitrobenzoíla, cloreto de 3,5-dinitrobenzoíla e ácido 3,4-dinitrobenzóico. Para o estudo das condições ótimas da reação, utilizou-se diferentes potências de radiação no reator de micro-ondas, sendo que a extensão da funcionalização mostrou-se sensível à variação deste parâmetro. Para a caracterização dos materiais, utilizou-se voltametria cíclica e análise térmica (TG e DTA). Resultados de infravermelho e Ramam são apresentados no Apêndice A. Os resultados eletroquímicos mostraram que os materiais funcionalizados em maiores potências apresentaram maior corrente Faradaica, mas ao mesmo tempo, o material obtido foi mais resistivo. A diferença de potencial relacionada ao processo redox do ferroceno aumentou conforme a extensão da funcionalização, uma vez que um sobrepotencial é necessário devido ao fluxo iônico (para a manutenção da eletroneutralidade) relativo ao número de espécies envolvidas. Os resultados eletroquímicos também indicaram que a funcionalização do grafite com os nitro compostos foi baixa. A análise térmica evidenciou que a reação de funcionalização do grafite com o ferroceno resultou em materiais com 15% a 20% (m/m) de material ligado ao grafite. Os materiais funcionalizados a maiores potências apresentaram maior massa ligada ao grafite. A funcionalização com os nitro compostos resultou em materiais com menos de 3% (m/m) de composto ligado ao grafite. Os resultados das duas técnicas mostraram coerência na análise da extensão da funcionalização. O material funcionalizado com o ácido ferrocenomonocarboxilico foi o que apresentou os melhores resultados e propõe-se uma explicação para tal baseado no mecanismo de reação sugerido. Com o objetivo de melhor elucidar o mecanismo da reação, foram realizadas algumas reações na ausência de alguns reagentes. Por exemplo, quando tenta-se funcionalizar o material sem a presença de cloreto de alumínio ou sem a umidade natural do grafite, a reação não ocorre. / In this work natural graphite functionalization in Fridel-Crafts conditions is performed using a one-step microwave assisted reaction. Since there is no hydrogen in graphite structure, it is not possible to observe electrophilic substitution. On the other hand this work shows the role of the moisture present on graphite in the functionalization reaction under this condition. Therefore, a reaction mechanism with the participation of the water naturally adsorbed on graphite stabilizing the formed carbocation has been suggested. After the reaction, the functionalized graphite was used as electrode material. Four molecules were used to functionalize graphite: Ferrocene monocarboxylic acid, 4-nitrobenzoyl chloride, 3,5-dinitrobenzoyl chloride and 3,4-dinitrobenzoic acid. To study the optimal conditions of the reaction, the microwave radiation power was varied and the extent of the functionalization on graphite was sensitive to this parameter. Two techniques were used to characterize the materials, cyclic voltammetry and thermal analysis (TG and DTA). IR and Raman data are shown in appendix A. Electrochemical results have shown that the materials functionalized at higher microwave radiation power have higher Faradaic current, but are more resistive. The potential difference between the peaks of the redox process of ferrocene increased with the extent of functionalization. This occurs because an overpotencial is needed to compensate the ionic flux (in order to maintain the electroneutrality) related to the number of species involved. The electrochemical results also indicated that the extent of functionalization of graphite with the nitro compounds was low. The thermal analysis have shown that the functionalization of graphite with ferrocene lead to values between 15% to 20% (m/m) of compound in the material. The materials functionalized at higher microwave radiation power presented higher relative mass in the material. The reaction with the nitro compounds lead to less than 3% (m/m) of compound in the final material. The results of both techniques were coherent about the extent of functionalization. The material functionalized with ferrocene monocarboxylic acid showed the best results, and an explanation for that based on the reaction mechanism is suggested. In order to elucidate the reaction mechanism, some experiments were realized in absent of some reagents. When the reaction were carried out without aluminum chloride or with dried graphite, the reaction has not occurred. Acilação de Friedel-Crafts Carbon Paste Electrode Cyclic Voltammetry Eletrodo de Pasta de Carbono Friedel-Crafts acylation Functionalized Graphite Grafite Funcionalizado Voltametria Cíclica

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