Alcohols from ketone hydrosilylation

Preparation of enantiomerically pare secondary amines by catalytic asymmetric hydrogenation or hydrosilylation of imines is as important as the preparation of alcohols from ketones. However, asymmetric hydrogenation of prochiral ON double bonds has received relatively less attention despite the obvious preparative potential of this process.98... 

The hydrosi(ly)lations of alkenes and alkynes are very important catalytic processes for the synthesis of alkyl- and alkenyl-silanes, respectively, which can be further transformed into aldehydes, ketones or alcohols by estabhshed stoichiometric organic transformations, or used as nucleophiles in cross-coupling reactions. Hydrosilylation is also used for the derivatisation of Si containing polymers. The drawbacks of the most widespread hydrosilylation catalysts [the Speier s system, H PtCl/PrOH, and Karstedt s complex [Pt2(divinyl-disiloxane)3] include the formation of side-products, in addition to the desired anh-Markovnikov Si-H addition product. In the hydrosilylation of alkynes, formation of di-silanes (by competing further reaction of the product alkenyl-silane) and of geometrical isomers (a-isomer from the Markovnikov addition and Z-p and -P from the anh-Markovnikov addition. Scheme 2.6) are also possible. 

The hydrosilylation of carbonyl compounds by EtjSiH catalysed by the copper NHC complexes 65 and 66-67 constitutes a convenient method for the direct synthesis of silyl-protected alcohols (silyl ethers). The catalysts can be generated in situ from the corresponding imidazolium salts, base and CuCl or [Cu(MeCN) ]X", respectively. The catalytic reactions usually occur at room tanperature in THE with very good conversions and exhibit good functional group tolerance. Complex 66, which is more active than 65, allows the reactions to be run under lower silane loadings and is preferred for the hydrosilylation of hindered ketones. The wide scope of application of the copper catalyst [dialkyl-, arylalkyl-ketones, aldehydes (even enoUsable) and esters] is evident from some examples compiled in Table 2.3 [51-53],... 

Supported cationic rhodium(I) phosphine complexes, chiral at a men-thyl moiety, effected hydrogenation of ketones, but the 2-butanol produced from methylethylketone was optically inactive (348). Polystyrene-or silica gel-supported DIOP systems, however, are particularly effective for production of optically active alcohols (up to 60% ee) via asymmetric hydrosilylation of ketones (10, 284, 296, 366, 368 see also Section III, A,4). 

It has been reported that (TMS)3SiCl can be used for the protection of primary and secondary alcohols [55]. Tris(trimethylsilyl)silyl ethers are stable to the usual conditions employed in organic synthesis for the deprotection of other silyl groups and can be deprotected using photolysis at 254 nm, in yields ranging from 62 to 95%. Combining this fact with the hydrosilylation of ketones and aldehydes, a radical pathway can be drawn, which is formally equivalent to the ionic reduction of carbonyl moieties to the corresponding alcohols. 

A complex prepared in situ from CuCl, (R)-3,5-Xyl-MeO-BIPHEP, and t-C4H9ONa promoted the hydrosilylation of several alkyl aryl ketones (substrate Cu ligand base=33 l l l) with PMHS in toluene at -50 or -78 °C to afford the corresponding R products with high optical purity (Scheme 18) [35]. The reduction of propiophenone gave 97% ee. 4 -Trifluoromethylacetophenone and 2 -ac-etonaphthone were converted to the corresponding R alcohols in 95% ee. 1-Te-... 

Enantioselective hydrosilylation of ketones.1 The complex formed from RhCl3 and la when activated by a silver salt, AgBF4 or AgOTf, is an effective catalyst for enantioselective hydrosilylation of ketones with diphenylsilane to provide, after acidic hydrolysis, (S)-secondary alcohols. In all cases, addition of free ligand (4-6 mole %) improves the enantioselectivity markedly. The highest enantioselectivity... 

Encouraged by these successful results, Saigo and co-workers tested ligand 78 in the rhodium-catalyzed hydrosilylation of ketones.56 Indeed, asymmetric hydrosilylation of acetophenone and tetralone using 78 as a chiral source led to considerably improved enantioselectivities (94% and 89% ee, respectively) compared to reactions performed with valinol-derived phosphorous-containing oxazoline 66 (82% and 59%, respectively).59,60 The equal accessibility of the two enantiomers of the m-2-amino-3,3-dimethyl-l-indanol backbone in 78 represented an additional advantage over oxazoline 66, which is derived from an amino alcohol of the chiral pool because (5)-tetralol could easily be obtained using (-)-78 in 97% yield and 92% ee (Scheme 17.30).56... 

Reductive TVansformations. The utility of 1 was first demonstrated in the enantioselective hydrosilylation of ketones. Uniformly high enantioselectivity, yield, and turnover were observed for aromatic (and some aliphatic) ketones when using the complex derived from RhCls (eq 1). Lower enantioselection is observed with t-Bu-pybox or i-Pr-pybox cobalt(I). The derived l Sn(OTf)2 complex gives alcohol products with up to 58% ee using methano-lic polymethylhydrosiloxane. A cationic ruthenium(III) catalyst diverts the usual reduction pathway to enolsilane formation, particularly when the nature of the silane is modified (eq 2). ... 

Although hydrosilanes reduce ketones, in trifluoroacetic acid, to the corresponding methylene compounds or dimeric ethers via ionic hydrogenation, the reduction of a-amino and a-oxy ketones and p-keto acid derivatives with hydrosilanes, particularly PhMe2SiH, under these conditions proceeded with high anti selectivity to the alcohols. No racemization was observed at the carbon a to the carbonyl group. Intramolecular hydrosilylation catalyzed by Lewis acids provided a highly stereoselective route to anti-1,3-diols from p-hydroxy ketones (Section 1.1.3. ). ... 

The catalytic hydrosilylation of acetophenone or t-butyl methyl ketone with diethyl-, methylphenyl- or diphenylsilane in the presence of rhodium(I) catalysts containing (R,i )-(-l-)- or (S,S)-(—)-170, followed by acid cleavage of the intermediate silyl ethers, affords the respective alcohols with optical yields of 10—42% . The synthesis of (ff)-(-l-)-l-phenylethanol from acetophenone and diethylsilane in conjunction with the catalyst derived from (S,S)-( —)-170 was the most effective reaction (equation 28). In... 

Hydrosilylation of unsaturated organic molecules is an attractive organic reaction. Asymmetric hydrosilylation of prochiral ketones or imines provides effective routes to optically active secondary alcohols or chiral amines (Scheme 756). These asymmetric processes can be catalyzed by titanium derivatives. The ( A ebthi difluoro titanium complex has been synthesized from the corresponding chloro compound.1659 This compound results in a very active system for the highly enantioselective hydrosilylation of acyclic and cyclic imines and asymmetric hydrosilylation reactions of ketones including aromatic ketones.1661,1666,1926-1929 An analogous l,l -binaphth-2,2 -diolato complex catalyzes the enantioselective hydrosilylation of ketones.1... 

Stereoselective hydrosilylation of terpene ketones such as camphor and menthone catalyzed by RhCI(PPh3)3 followed by hydrolysis exhibits significant differences in stereochemistry from other reductions using metal hydrides123,115. The bulkiness of hydrosilanes exerts a remarkable influence on the stereochemical course of the reaction, i.e., a bulky hydrosilane favors the production of the more stable alcohols (equation 61). 

Hydrosilylations by complexed CuH have been applied to several substrate types (Scheme 1-17). As illustrated by the following examples, the stereochemical outcomes from both 1,2-additions (to aryl ketones and aryl imines ) and 1,4-conjugate additions (cyclic ketones, P-aryl and/or P-silyl enoates, and unsaturated lactones) can be controlled by these ligand-accelerated reactions. One of the key tricks to this chemistry is to take advantage of the tolerance of CuH complexes to alcohols and water.In fact, several methods rely on the presence of a bulky alcohol (e.g., t-BuOH) to significantly enhance reaction rates. It takes relatively little added alcohol (volume-wise) to accelerate the hydrosilylation, usually on the order of 1-3 equivalents. The role of this additive is usually ascribed to the more rapid quenching of an intermediate copper alkoxide or enolate, which necessarily generates a copper alkoxide, an ideal precursor to rapid reformation of CuH in the presence of excess silane. Thus, the rate increase is presumably due to... 

The sense of chirality in these hydrosilylations is such that (7 j-(-)-DTBM-SEGPHOS predictably delivers hydride to aryl alkyl ketones fi om the si face to give alcohols of R absolute stereochemistry, which is also true for imines. Stereocontrol at a p-site due to asymmetric 1,4-additions is controlled by either the nature of the geometrical isomer (i.e., or Z) or the axial chirality of the ligand. Thus, by switching from the (/ )- to the (5)-enantiomer of the ligand, or from the E- to the Z-activated olefin isomer, the observed central chirality can be inverted. 

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