Hydrosilylation of Ketones and Imines

Literature on the hydrosilylation of ketones and imines is extensive. This chemistry provides a method for the reduction of these unsaturated substrates with reagents that are inexpensive and either liquids or solids, rather than gases (H ). As noted in the introduction, much of this literature focuses on the enantioselective hydrosilylation of ketones and imines to form non-racemic chiral alcohols and amines. In addition to the conveniaice of using a liquid reagent, the ability to vary the substituents on a silane allows for tuning of the stereoselectivity of the reductions. 

More recently, the asymmetric hydrosilylation of aryl ketones and aryl imines has been developed using copper catalysts. In this case, axially chiral biaryl bisphos-phine ligands boimd to copper generate remarkably active catalysts for tihe hydrosilylation of ketones. These reactions occur with high selectivity using the hydrosilane polymer 

The mechanism of hydrosilylation involves a sequence of elementary reactions described in the earlier chapters of the book. The most commonly cited mechanism for hydrosilylation was first described by Chalk and Harrod and involves oxidative addition of the silane, insertion of an olefin into the metal-hydride bond, and reductive elimination to form the silicon-carbon bond in the organosilane product. More recently, a related but distinct mechanism involving insertion of the olefin into the silyl group has been recognized, and this mechanism is often called the modified Chalk-Harrod mechanism. Before these steps are described, some of the mechanistic issues regarding the specific systems of Speier s catalyst and Karstedt s catalyst are described briefly. 

Induction Periods and Phase of the Reactions Catalyzed by Speier s and Karstedt s Catalysts 

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While it is beyond the scope of this chapter to cover the asymmetric hydrosilylation of ketones and imines in any detail, a number of the more catalytically active ML combinations will be mentioned here. A full review of the area has recently appeared.138 Asymmetric hydrosilylation of carbonyl groups is usually performed with rhodium or titanium catalysts bearing chelating N- or P-based ligands. Representative results for some of the most active Rh/L combinations (Scheme 32) for addition of Si H to acetophenone are given in Table 11. 

Hosomi et al. reported an unprecedented hydrosilylation of ketones and imines displaying remarkable chemoselectivity that enabled ketones to be differentiated from aldehydes. Although the active species were not dear, they accepted that monomeric gold complexes stabilized by excess of tributylphosphine played a crucial role in controlling the reaction [190] (Scheme 8.30). 

ASYMMETRIC HYDROSILYLATION OF KETONES AND IMINES WITH RH AND RU CATALYSTS... 

Recent advances in the asymmetric hydrosilylation of ketones and imines have been reviewed.276... 

Diselenides as Chiral Ligands for Asymmetric Hydrosilylation of Ketones and Imines... 

Much work has also been conducted on the hydrosilylation of ketones and imines (Equation 16.16). The products from these reactions are silyl ethers and sdylamines. These additions of silanes across C-X ir-bonds have been conducted predominantly for the purpose of generating optically active alcohols and amines after hydrolysis. Because the mechanism of these reactions is less defined than the mechanism of alkene hydrosilylation, and this chemistry lies outside the theme of this chapter, the hydrosilylation of ketones and imines is presented only briefly. Instead, this chapter provides an overview of the scope and motivation for the hydrosilylation of alkenes and alkynes and provides details on the mechanisms of these reactions catalyzed by complexes of various metals. Several comprehensive reviews of the scope of these reactions have been published. ... 

Recently, several organocatalysts that are catalytically active in hydrosilylation of ketones (and imines), have been developed (for review, see (309)). The reactions proceed via the formation of hypervalent silicon intermediates and permit synthesis of the corresponding alcohols with moderate to high enantioselectivity. 

In 1999 [22] and 2001 [23], Matsumura and co-workers reported the first examples of stereoselective hydrosilylation with HSiCla and (5)-proline derivatives as effective activators. These works can be considered as milestones for the asymmetric reduction of ketones and imines using HSiCla as reducing agent and paved the road to the synthesis of other related systems. Since then, considerable efforts have been devoted to the development of efficient catalysts for the reduction of carbon-nitrogen double bonds, and remarkable progress has been made. 

Asymmetric hydrosilylation of ketones and ketoimines has been demonstrated in the absence of transition metal catalysts. Using catalytic amounts of chiral-alkoxide Lewis bases such as binaphthol (BINOL), Kagan was able to facilitate the asymmetric reduction of ketones (eq 19). This process is believed to arise from activation of the triethoxysilane by mono-alkoxide addition to give an activated pentavalent intermediate, which can undergo coordination of an aldehyde. This highly ordered hexacoordinate transition state directs reduction in an asymmetric manner, with subsequent catalyst regeneration. Brook was able to facilitate a similar tactic for asymmetric reduction by employing histidine as a bi-dentate Lewis base activator of triethoxysilane. A similar chiral lithium-alkoxide-catalyzed asymmetric reduction of imines was demonstrated by Hosomi with the di-lithio salt of BINOL and trimethoxysilane. ... 

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)]. 

Michael-aldol reaction as an alternative to the Morita-Baylis-Hillman reaction 14 recent results in conjugate addition of nitroalkanes to electron-poor alkenes 15 asymmetric cyclopropanation of chiral (l-phosphoryl)vinyl sulfoxides 16 synthetic methodology using tertiary phosphines as nucleophilic catalysts in combination with allenoates or 2-alkynoates 17 recent advances in the transition metal-catalysed asymmetric hydrosilylation of ketones, imines, and electrophilic C=C bonds 18 Michael additions catalysed by transition metals and lanthanide species 19 recent progress in asymmetric organocatalysis, including the aldol reaction, Mannich reaction, Michael addition, cycloadditions, allylation, epoxidation, and phase-transfer catalysis 20 and nucleophilic phosphine organocatalysis.21... 

The nucleophilic activation of hydrosilanes as HSi(OR)3 offers an opportunity to transfer one hydride on the carbon of ketones or imines [22]. The enantioselective organocatalytic hydrosilylation of ketones was first reported in 1999 by Matsu-mura et al. [23], the catalyst employed being a proline derivative 19 (Scheme 11.7). Amide 20 was also able to catalyze the hydrosilylation of ketimines, as indicated in Scheme 11.7 [24]. Improved results were recently reported by Kocovsky and Maikov [25], who prepared from valine some acyclic analogues of prolina-... 

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... 

Optically active alcohols, amines, and alkanes can be prepared by the metal catalyzed asymmetric hydrosilylation of ketones, imines, and olefins [77,94,95]. Several catalytic systems have been successfully demonstrated, such as the asymmetric silylation of aryl ketones with rhodium and Pybox ligands however, there are no industrial processes that use asymmetric hydrosilylation. The asymmetric hydrosilyation of olefins to alkylsilanes (and the corresponding alcohol) can be accomplished with palladium catalysts that contain chiral monophosphines with high enantioselectivities (up to 96% ee) and reasonably good turnovers (S/C = 1000) [96]. Unfortunately, high enantioselectivities are only limited to the asymmetric hydrosilylation of styrene derivatives [97]. Hydrosilylation of simple terminal olefins with palladium catalysts that contain the monophosphine, MeO-MOP (67), can be obtained with enantioselectivities in the range of 94-97% ee and regioselectivities of the branched to normal of the products of 66/43 to 94/ 6 (Scheme 26) [98.99]. 

Enantioselective reduction of simple ketone carbonyls is possible, but catalysts that deliver consistently high selectivities in such reactions have been elusive [61-64]. More success has been recorded in the asymmetric reduction of functionalized ketones and imines (reviews [65,66]). Two types of stoichiometric reductants are used dihydrogen and dihydrosilanes (reviews ref. [67,68]), but as the mechanism of hydrosilylation is highly controversial [68], we will discuss only the former. 

Part two (section 3) deals with the hydrosilylation of unsaturated carbon-heteroatom bond, mostly 0=0 and 0=N (but also C N, and C=S), as a catalytic method for the reduction of C=0 and C=N bonds—one of the most fundamental transformations in organic chemistry. Catalytic hydrosilylation of prochiral ketones and imines with substituted silanes and siloxanes that can provide (if followed by hydrolysis) convenient access to chiral alcohols and amines, respectively, discussed from the catalytic and synthetic point of view completes this part. 

In 2011, Sortais and Darcel described the activity of the related nonlinked half-sandwich iron complex [CpFe(IMes)(CO)2]I [IMes = l,3-bis(2,4,6-trimethylphenyl)imidazol-2-ylidene] (Fig. 10.15c) in the hydrosilylation of aldehydes and ketones [73], and more recently, they extended these studies to the reduction of amides [74], nitriles [74], imines... 

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