Hydrosilylation ketone substrates

Tanaka and co-workers have investigated the dehydrogenative double silylation of carbonyl-containing compounds with o-bis(dimethylsilyl)ben-zene [Eqs. (66) and (67)].173 High-yield 1,2-double silylation occurs in reactions of heptanal, benzaldehyde, and diphenylketene catalyzed by Pt(CH2 = CH2)(PPh3)2 or Pt(dba)2. In contrast, the 1,4-double silylation product is formed for a,/3-unsaturated aldehyde or a,/3-Unsaturated ketone substrates, such as prop-2-enal and but-3-en-2-one. The system may also be affected by sterics reaction of ( )-3-phenyl-2-propenal gives 1,2-adduct as the major product and only minor amounts of 1,4-adduct. Hydrosilylation products were not formed in any of the carbonyl systems studied. 

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-... 

An iron complex-catalyzed asymmetric hydrosilylation of ketones was achieved by using chiral phosphoms ligands [68]. Among various ligands, the best enantios-electivities (up to 99% ee) were obtained using a combination of Fe(OAc)2/(5,5)-Me-Duphos in THF. This hydrosilylation works smoothly in other solvents (diethylether, n-hexane, dichloromethane, and toluene), but other iron sources are not effective. Surprisingly, this Fe catalyst (45% ee) was more efficient in the asymmetric hydrosilylation of cyclohexylmethylketone, a substrate that proved to be problematic in hydrosilylations using Ru [69] or Ti [70] catalysts (43 and 23% ee, respectively). 

As outlined in Section II,E, ketone and imine groups are readily hydrogenated via a hydrosilylation-hydrolysis procedure. Use of chiral catalysts with prochiral substrates, for example, R,R2C=0 or R,R2C=N— leads to asymmetric hydrosilylation (284, 285 Chapter 9 in this volume) and hence optically active alcohols [cf. Eq. (41)]. 

However, on a lightly cross-linked hydroxyethylmethacrylate/styrene polymer that swells in polar solvents (22, 365), or on a silica-gel support (366), catalyst performance matches that of the soluble one for the precursor amino acid substrates. A rhodium-DIOP analog has also been supported on a polymer containing pendent optically active alcohol sites [incidentally, formed via hydrosilylation and hydrolysis of a ketonic polymer component using an in situ rhodium(I)-DIOP catalyst]. The supported catalyst in alcohol again matched that of the soluble catalyst for... 

Displacement of the bound ketone by H2 was directly observed by NMR (Eq. (37)), and an approximate equilibrium constant was determined. The cationic tungsten complex can also be used for catalytic hydrosilylation of ketones. In the case of catalytic hydrosilylation of abphatic substrates using HSiEt3, the catalyst precipitates at the end of the reaction, facilitating recycle and reuse [66],... 

By far, the most W-Si bonds reported in the period that this review covers involve W(CO)n or (t]S-CsRs)W-containing compounds. A significant development has been that of a recyclable catalyst for the hydrosilylation of ketones the system begins with a polar liquid substrate (ketone or ester) and finishes with a non-polar liquid product (alkoxysilane). The rest state of the catalyst is a mixture of the [BlCgFsTH salts of 36 and 37 the tungsten complex is far more active than its molybdenum analog. 

Benzamido-cinnamic acid, 20, 38, 353 Benzofuran polymerization, 181 Benzoin condensation, 326 Benzomorphans, 37 Benzycinchoninium bromide, 334 Benzycinchoninium chloride, 334, 338 Bifiinctional catalysts, 328 Bifiinctional ketones, enantioselectivity, 66 BINAP allylation, 194 allylic alcohols, 46 axial chirality, 18 complex catalysts, 47 cyclic substrates, 115, 117 double hydrogenation, 72 Heck reaction, 191 hydrogen incorporation, 51 hydrogen shift, 100 hydrogenation, 18, 28, 57, 309 hydrosilylation, 126 inclusion complexes, oxides, 97 ligands, 19, 105 molecular structure, 50, 115 mono- and bis-complexes, 106 NMR spectra, 105 olefin isomerization, 96... 

Ojima and co-workers first reported the RhCl(PPh2)3-catalyzed hydrosilylation of carbonyl-containing compounds to silyl ethers in 1972.164 Since that time, a number of transition metal complexes have been investigated for activity in the system, and transition metal catalysis is now a well-established route for the reduction of ketones and aldehydes.9 Some of the advances in this area include the development of manganese,165 molybdenum,166 and ruthenium167 complex catalysts, and work by the Buchwald and Cutler groups toward extension of the system to hydrosilylations of ester substrates.168... 

Alkyl aryl ketimines were reduced with up to 99% ee (Scheme 8) [24]. The high enantioselectivity was not affected by the E Z ratio of the imines. For example, a 1.8 1 E Z mixture of the N-propylimine of 4 -methoxy-3-methyIbuty-rophenone was converted to the desired product in 97% optical yield. Hydrosilylation of the N-propylimine of cyclohexyl methyl ketone with a substrate to Ti molar ratio of 2,000 1 was completed to give the product in 98% ee [24]. N-Benzylimine of 2-octanone, a simple aliphatic ketimine, was reduced with 69% optical yield. The reduction of W-benzyl-l-indanimine gave the corresponding amine in 92% ee (Scheme 9) [24]. 

Racemic N-methylimines derived from 4-substituted 1-tetralones were ki-netically resolved by asymmetric hydrosilylation with phenylsilane (1 equivalent) as a reducing agent using the titanocene catalyst (R)-ll (substrate Ti= 100 1) at 13 °C, followed by a workup procedure to afford the corresponding chiral ketones and chiral cis amines with very high enantio- and diastere-oselectivity (Scheme 12) [28], The extent of the enantiomeric differentiation, kfast/kslow was calculated to be up to 114. The ris-selectivity of this reaction was... 

Figure 4.3 Substrate range in the Fe-catalyzed hydrosilylation of ketones in the presence oftmeda.

Hydrosilylation of carbon-oxygen bonds is a mild method for selective reduction of carbonyl functions. Parks and Piers have found that aromatic aldehydes, ketones, and esters are hydrosilylated at room temperature in the presence of 1-4 mol % B(CgF5)3 and 1 equiv. PhsSiFl [154]. On the basis of kinetic experiments the authors suggested that the reduction takes place by an unusual nucleophilic/electrophilic mechanism— the substrate itself serves to nucleophilically activate the Si-H bond, and hydride transfer is facilitated by the borane Lewis aeid (Eq. 99). 

The asymmetric catalytic reduction of ketones (R2C=0) and imines (R2C=NR) with certain organohydrosilanes and transition-metal catalysts is named hydrosilylation and has been recognized as a versatile method providing optically active secondary alcohols and primary or secondary amines (Scheme 1) [1]. In this decade, high enantioselectivity over 90% has been realized by several catalytic systems [2,3]. Therefore the hydrosilylation can achieve a sufficient level to be a preparative method for the asymmetric reduction of double bond substrates. In addition, the manipulative feasibility of the catalytic hydrosilylation has played a major role as a probe reaction of asymmetric catalysis, so that the potential of newly designed chiral ligands and catalysts can be continuously scrutinized. 

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