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Dialkyl asymmetric

Esters are alkylated in the presence of strong bases in aprotic solvents. A common combination is LDA in tetrabydrofuran at low temperatures. Equimolar amounts of base are sufficient and only the mono-carbanion Js formed. After addition of one mole of alkyl halide the products form rapidly, and no dialkylation, which is a problem in the presence of excess base, is possible. Addition of one more mole of LDA and of another alkyl halide leads to asymmetric dialkylation of one or-carbon atom in high yield (R.J. Cregge, 1973). [Pg.22]

The first practical method for asymmetric epoxidation of primary and secondary allylic alcohols was developed by K.B. Sharpless in 1980 (T. Katsuki, 1980 K.B. Sharpless, 1983 A, B, 1986 see also D. Hoppe, 1982). Tartaric esters, e.g., DET and DIPT" ( = diethyl and diisopropyl ( + )- or (— )-tartrates), are applied as chiral auxiliaries, titanium tetrakis(2-pro-panolate) as a catalyst and tert-butyl hydroperoxide (= TBHP, Bu OOH) as the oxidant. If the reaction mixture is kept absolutely dry, catalytic amounts of the dialkyl tartrate-titanium(IV) complex are suflicient, which largely facilitates work-up procedures (Y. Gao, 1987). Depending on the tartrate enantiomer used, either one of the 2,3-epoxy alcohols may be obtained with high enantioselectivity. The titanium probably binds to the diol grouping of one tartrate molecule and to the hydroxy groups of the bulky hydroperoxide and of the allylic alcohol... [Pg.124]

The asymmetric epoxidation of an allylic alcohol 1 to yield a 2,3-epoxy alcohol 2 with high enantiomeric excess, has been developed by Sharpless and Katsuki. This enantioselective reaction is carried out in the presence of tetraisopropoxyti-tanium and an enantiomerically pure dialkyl tartrate—e.g. (-1-)- or (-)-diethyl tartrate (DET)—using tcrt-butyl hydroperoxide as the oxidizing agent. [Pg.254]

Numerous research activities have focused on the improvement of the protective films and the suppression of solvent cointercalation. Beside ethylene carbonate, significant improvements have been achieved with other film-forming electrolyte components such as C02 [156, 169-177], N20 [170, 177], S02 [155, 169, 177-179], S/ [170, 177, 180, 181], ethyl propyl carbonate [182], ethyl methyl carbonate [183, 184], and other asymmetric alkyl methyl carbonates [185], vinylpropylene carbonate [186], ethylene sulfite [187], S,S-dialkyl dithiocarbonates [188], vinylene carbonate [189], and chloroethylene carbonate [190-194] (which evolves C02 during reduction [195]). In many cases the suppression of solvent co-intercalation is due to the fact that the electrolyte components form effective SEI films already at potential which are positive relative to the potentials of solvent co-intercalation. An excess of DMC or DEC in the electrolyte inhibits PC co-intercalation into graphite, too [183]. [Pg.397]

Asymmetric epoxidation is another important area of activity, initially pioneered by Sharpless, using catalysts based on titanium tetraisoprop-oxide and either (+) or (—) dialkyl tartrate. The enantiomer formed depends on the tartrate used. Whilst this process has been widely used for the synthesis of complex carbohydrates it is limited to allylic alcohols, the hydroxyl group bonding the substrate to the catalyst. Jacobson catalysts (Formula 4.3) based on manganese complexes with chiral Shiff bases have been shown to be efficient in epoxidation of a wide range of alkenes. [Pg.117]

Asymmetric conjugate addition of dialkyl or diaryl zincs for the formation of all carbon quaternary chiral centres was demonstrated by the combination of the chiral 123 and Cu(OTf)2-C H (2.5 mol% each component). Yields of 94-98% and ee of up to 93% were observed in some cases. Interestingly, the reactions with dialkyl zincs proceed in the opposite enantioselective sense to the ones with diaryl zincs, which has been rationalised by coordination of the opposite enantiofaces of the prochiral enone in the alkyl- and aryl-cuprate intermediates, which precedes the C-C bond formation, and determines the configuration of the product. The copper enolate intermediates can also be trapped by TMS triflate or triflic anhydride giving directly the versatile chiral enolsilanes or enoltriflates that can be used in further transformations (Scheme 2.30) [110],... [Pg.55]

Mikolajczyk and coworkers have summarized other methods which lead to the desired sulfmate esters These are asymmetric oxidation of sulfenamides, kinetic resolution of racemic sulfmates in transesterification with chiral alcohols, kinetic resolution of racemic sulfinates upon treatment with chiral Grignard reagents, optical resolution via cyclodextrin complexes, and esterification of sulfinyl chlorides with chiral alcohols in the presence of optically active amines. None of these methods is very satisfactory since the esters produced are of low enantiomeric purity. However, the reaction of dialkyl sulfites (33) with t-butylmagnesium chloride in the presence of quinine gave the corresponding methyl, ethyl, n-propyl, isopropyl and n-butyl 2,2-dimethylpropane-l-yl sulfinates (34) of 43 to 73% enantiomeric purity in 50 to 84% yield. This made available sulfinate esters for the synthesis of t-butyl sulfoxides (35). [Pg.63]

Metal-catalyzed asymmetric addition of dialkyl phosphites to aldehydes (Pudovik reaction) has been extensively developed since the initial reports in 1993 by Shibuya. Scheme 5-25 illustrates the use of TiCh to promote diastereoselective addition of diethyl phosphite to an a-amino aldehyde. [Pg.158]

Shibasaki showed that an aluminum-lithium-BINOL complex (ALB) also catalyzes the asymmetric addition of dialkyl phosphites to aldehydes, with ees ranging from 55 to 90% for aryl or unsaturated aldehydes (Scheme 5-37). [Pg.162]

Scheme 1.22 Kitamura and Noyori s mechanism of the asymmetric addition of dialkyl zinc to aryl aldehydes. Scheme 1.22 Kitamura and Noyori s mechanism of the asymmetric addition of dialkyl zinc to aryl aldehydes.
Feringa s group has demonstrated that cyclopentene-3,5-dione monoacetals as 2-47 can also be successfully applied as substrates in an asymmetric three-component domino Michael/aldol reaction with dialkyl zinc reagents 2-48 and aromatic aldehydes 2-49 [17]. In the presence of 2 mol% of the in-sitw-generated enantiomeri-cally pure catalyst Cu(OTf)2/phosphoramidite 2-54, the cyclopentanone derivatives 2-51 were formed nearly exclusively in good yields and with high ee-values (Scheme 2.11). [Pg.54]

The scope of metal-mediated asymmetric epoxidation of allylic alcohols was remarkably enhanced by a new titanium system introduced by Katsuki and Sharpless epoxidation of allylic alcohols using a titanium(IV) isopropoxide, dialkyl tartrate (DAT), and TBHP (TBHP = tert-butyl-hydroperoxide) proceeds with high enantioselectivity and good chemical yield, regardless of... [Pg.208]

Field, L., Harle, H., Owen, T.C., and Ferretti, A. (1964) Preparation and oxidation of some asymmetrical dialkyl and alkyl pyridnium disulfides./. Org. Chem. 29, 1632-1635. [Pg.1063]

The asymmetric organosilane reduction of prochiral ketones has been studied as an alternative to the asymmetric hydrogenation approach. A wide variety of chiral ligand systems in combination with transition metals can be employed for this purpose. The majority of these result in good to excellent chemical yields of the corresponding alcohols along with a trend for better ee results with aryl alkyl ketones than with prochiral dialkyl ketones. [Pg.105]


See other pages where Dialkyl asymmetric is mentioned: [Pg.259]    [Pg.241]    [Pg.295]    [Pg.347]    [Pg.347]    [Pg.347]    [Pg.152]    [Pg.180]    [Pg.993]    [Pg.63]    [Pg.72]    [Pg.73]    [Pg.826]    [Pg.827]    [Pg.912]    [Pg.59]    [Pg.186]    [Pg.213]    [Pg.72]    [Pg.73]    [Pg.826]    [Pg.827]    [Pg.912]    [Pg.117]    [Pg.99]    [Pg.1082]    [Pg.197]    [Pg.19]    [Pg.102]    [Pg.212]    [Pg.106]    [Pg.107]   
See also in sourсe #XX -- [ Pg.45 ]




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