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Fluorous catalyst

Catalyst Fluorous solvent Reaction occurs Catalyst Fluorous solvent... [Pg.147]

For typical fluorous biphase catalysis the most important aspect is the simple recycling and re-use of the catalyst. Fluorous solvents have one special advantage over hydrocarbon solvents, however. Their very high oxygen dissolving capacity, combined with their extreme resistance to oxidative decomposition makes perfluorocarbons in combination with fluorous catalysts the optimum choice for oxidation reactions. Thus, the biomimetic oxidation of olefins with molecular oxygen and 2-methylpropanal as a co-reductand has been achieved with a fluorous cobalt porphyrin catalyst (22) [23], and also even without catalyst [24] (Scheme 3.7). [Pg.181]

In an attempt to improve the ability to recycle the catalyst, fluorous versions of the oxazaborolidine have been constructed.12 Pre-catalyst 29 could be prepared in five steps. This species was able to form the requisite chiral catalyst 30 in situ. Ketones 31 could be reduced to alcohols 32 in good to excellent chemical and optical yields. It was noted that aryl... [Pg.8]

Synthetic strategy Recyclable fluorous organocatalyst-promoted multi-component reaction Catalyst Fluorous imine-l,2-b/s(carbothioate) (I), an organocatalyst... [Pg.181]

Begue and coworkers recently achieved an improvement in this method by performing the epoxidation reaction in hexafluoro-2-propanol [120]. They found that the activity of hydrogen peroxide was significantly increased in this fluorous alcohol, in relation to trifluoroethanol, which allowed for the use of 30% aqueous H202. Interestingly, the nature of the substrate and the choice of additive turned out to have important consequences for the lifetime of the catalyst. Cyclic dis-ubstituted olefins were efficiently epoxidized with 0.1 mol% of MTO and 10 mol%... [Pg.217]

The most important biphasic liquid systems are probably those that combine a conventional organic phase with another type of solvent, such as water, a fluorous organic solvent, or an ionic liquid [3]. In those cases the solvent can be considered as the support for the catalyst phase and we have therefore limited the examples in this review to those where the recycled liquid catalyst phase is recovered as a whole. [Pg.151]

Compounds lb and 2b were the Urst fluorinated ligands tested in Mn-catalyzed alkene epoxidation [5,6]. The biphasic Uquid system perfluorooc-tane/dichloromethane led to excellent activity and enantioselectivity (90% ee) in the epoxidation of indene with oxygen and pivalaldehyde (Scheme 1, Table 1). In addition, the fluorous solution of the catalyst was reused once and showed the same activity and selectivity. This represents a considerable improvement over the behavior in the homogeneous phase, where the used catalyst was bleached and reuse was impossible. Unfortunately, indene was the only suitable substrate for this system, which failed to epoxidize other alkenes (such as styrene or 1,2-dihydronaphthalene) with high enantioselectivity. The system was also strongly dependent on the oxidant and only 71% ee was obtained in the epoxidation of indene with mCPBA at - 50 °C. [Pg.153]

The term fluorous biphase has been proposed to cover fully fluorinated hydrocarbon solvents (or other fluorinated inert materials, for example ethers) that are immiscible with organic solvents at ambient conditions. Like ionic liquids the ideal concept is that reactants and catalysts would be soluble in the (relatively high-boiling) fluorous phase under reaction conditions but that products would readily separate into a distinct phase at ambient conditions (Figure 5.5). [Pg.161]

The strategy of using two phases, one of which is an aqueous phase, has now been extended to fluorous . systems where perfluorinated solvents are used which are immiscible with many organic reactants nonaqueous ionic liquids have also been considered. Thus, toluene and fluorosolvents form two phases at room temperature but are soluble at 64 °C, and therefore,. solvent separation becomes easy (Klement et ai, 1997). For hydrogenation and oxo reactions, however, these systems are unlikely to compete with two-phase systems involving an aqueous pha.se. Recent work of Richier et al. (2000) refers to high rates of hydrogenation of alkenes with fluoro versions of Wilkinson s catalyst. De Wolf et al. (1999) have discussed the application and potential of fluorous phase separation techniques for soluble catalysts. [Pg.142]

The use of thermomorphic systems has recently been studied as a way of achieving catalyst separation in homogeneous catalysis. For example, a biphasic hydroformylation catalyst system was developed to take advantage of the unusual solvent characteristics of perfluorocarbons combined with typical organic solvents (4). Fluorous/organic mixtures such as perfiuoromethylcyclohexane... [Pg.244]

Further examples of microwave-assisted Suzuki cross-couplings involving supported substrates/catalysts or fluorous-phase reaction conditions are described in Chapter 7. [Pg.126]

Fluorous ligands introduce an ease of purification in that the tagged phosphine ligand, the palladium catalyst complexed ligand, and the oxidized ligand can be completely removed by direct fluorous solid-phase separation (F-SPE) prior to product isolation. Similarly, an example of a fluorous palladium-catalyzed microwave-induced synthesis of aryl sulfides has been reported, whereby the product purification was aided by fluorous solid-phase extraction [91]. [Pg.355]

These alternative processes can be divided into two main categories, those that involve insoluble (Chapter 3) or soluble (Chapter 4) supports coupled with continuous flow operation or filtration on the macro - nano scale, and those in which the catalyst is immobilised in a separate phase from the product. These chapters are introduced by a discussion of aqueous biphasic systems (Chapter 5), which have already been commercialised. Other chapters then discuss newer approaches involving fluorous solvents (Chapter 6), ionic liquids (Chapter 7) and supercritical fluids (Chapter 8). [Pg.8]

Keurentjes et al. performed a continuous hydrogenation of 1-butene in supercritical carbon dioxide.[9,10] A fluorous derivative of Wilkinson s catalyst was prepared in situ by mixing the ligand with [(COD)RhCl]2 under hydrogen / carbon dioxide pressure (Figure 4.37). [Pg.96]

Fluorous biphasic systems operate on the premise that the catalyst complex is preferentially soluble in the fluorous phase. This is achieved by synthesising fluorinated ligands that have a high weight-percentage of fluorine. It has been reported that for a complex to be preferentially soluble in fluorous solvents it must contain >60... [Pg.145]

Figure 6.3. Fluorous soluble ionic catalysts for the hydrogenation of 1-octene.[30]... Figure 6.3. Fluorous soluble ionic catalysts for the hydrogenation of 1-octene.[30]...
Better retention into the fluorous phase was observed when using a polar fluorous solvent and hexane (>99.82%, insoluble catalyst emulsified in homogeneous reaction mixture) than when using a PFMC and acetone (97.5%), as expected for the ionic... [Pg.149]


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See also in sourсe #XX -- [ Pg.385 , Pg.1377 , Pg.1380 , Pg.1383 , Pg.1386 ]




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Catalyst fluorous biphasic

Catalyst scavenger, fluorous

Catalysts fluorous biphasic catalysis concept

Catalysts separation, fluorous

Catalysts separation, fluorous biphasic

Designing fluorous catalysts

Esterification of alcohol with acetic anhydride using a fluorous scandium catalyst

Fluorous

Fluorous Catalysts and Reagents

Fluorous Grubbs’ catalysts

Fluorous Palladacycle Catalysts

Fluorous Wilkinson Catalyst

Fluorous acid and base catalysts

Fluorous biphasic catalysis catalysts

Fluorous compounds Catalysts

Fluorous metallic catalysis catalysts

Fluorous pony-tail, catalysts with

Fluorous solid catalyst

Light fluorous catalyst

Organocatalysts fluorous catalyst

Recycling fluorous catalysts

TEMPO catalyst, fluorous

Thiourea catalysts fluorous

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