Scandium enolate

Scandium enolate chemistry is quite limited. The complex (nacnac)Sc(NHAr)(HBEt3) where nacnac = 21 and Ar = 2,6-(/-Pr2)2C6H3) reacts with THF to form the enolate (nacnac)Sc(NHAr)OCH=CH2 while diethyl ether forms the related alkoxide (nac-nac)Sc(NHAr)OEt. This suggests considerable stabilization due to the Sc—O bond. After all, ring opening of THE is energetically unfavorable (THE EtOVi A// > 40 kJ mor ). 

The authors proposed an intermediate complex 150 in which the chiral induction occurs by reaction of the scandium ketone enolate with the a, S-unsaturated ketone 148 (equation 42). The absolute configuration of the Michael adduct 150a can be explained by coordination of the hydroxy groups of 149 to Sc + in a tetradentate manner and shielding of the si-facc of the scandium enolate by an adjacent f-butyl group. Therefore, the enolate attacks the Michael acceptor preferably at the re-face. ... 

Scheme 3.7 O-metal bound dimeric yttrium enolate 17 and monomeric scandium enolate 18, both derived from acetaldehyde.

With these results in hand, we have next introduced new types of Lewis acids, e.g scandium tris(-dodecyl sulfate) (4a) and scandium trisdodecanesul-fonate (5a) (Chart 1).[1S1 These Lewis acid-surfactant-combined catalysts (LASCs) were found to form stable colloidal dispersions with organic substrates in water and to catalyze efficiently aldol reactions of aldehydes with very water-labile silyl enol ethers. 

CO2-PEG system is also effective for the scandium-catalyzed aldol reactions, and poly(ethylene glycol) dimethyl ether (PEG(OMe)2, MW = 500) is more effective than PEG (Scheme 3.12) [57]. Emulsions in C02-PEG(0Me)2 medium are observed when the concentration of the additive is 1 g/L. Not only benzal-dehyde but also substituted aromatics, aliphatic, and a, /]-unsaturated aldehydes react smoothly, and various silicon enolates derived from a ketones, esters, and thioesters also react well to afford the corresponding aldol adducts in high yields. 

An intramolecular [2+2] photocycloaddition of allyl ethers with dioxinones followed by a base-induced fragmentation leads to substituted tetrahydropyran-4-ones <1997TL5579>. A one-pot scandium triflate catalyzed diastereoselec-tive cyclization between aldehydes and (3-hydroxy dioxinones 1046 followed by alkoxide addition to the resulting bicycles 1047 leads to 3-carboxy-substituted tetrahydropyran-4-ones 1048 with high levels of diastereoselectivity as a mixture of keto/enol tautomers (Scheme 268, Table 49) <20050L1113>. 

Oxasilacyclopentenes were shown to be competent substrates for a scandium triflate-catalyzed Mukaiyama aldol process (Scheme 7.35).104 Exposure of silacy-clopentene 121 and benzaldehyde to substoichiometric amounts of scandium triflate produced ketone 122 diastereoselectively.105 This ketone was proposed to form by addition of enolate 123, resulting from desilylation of 121,106 to benzaldehyde. A 1,3-Brook rearrangement then afforded 122 from 124.107 This ketone could be further functionalized through lithium aluminum hydride reduction followed by deprotection to afford triol 125 containing four contiguous stereocenters. Thus, the molecular complexity of silyloxyalkynes can be increased dramatically in just three operations. 

Taking into account the competitive hydrolysis of the silyl enol ether, this reaction is remarkable. The method was shown to be general and was extended to a variety of aldehydes and several a,j9-unsaturated carbonyl compounds giving uniformly 1,4-addition with aldehydes and a mixture of 1,4- and 1,2-adducts in the case of ketones [187]. Later, this aqueous version of the Mukaiya-ma reaction was shown to give near quantitative yields in the presence of a water-tolerant Lewis acid such as ytterbium triflate [188]. Keeping with the same concept,copper(II) triflate [189],indium(III) trichloride [190],tris(pentafluoro-phenyl)boron [191] and scandium(III) triflate in the presence of a surfactant [192] have proved to be active catalysts. 

Quite recently, it has been found that scandium triflate (Sc(OTf)rcatalyzed aldol reactions of silyl enol ethers with aldehydes can be successfully carried out in micellar systems [24], While the reactions proceeded sluggishly in pure water (without organic solvents), remarkable enhancement of the reactivity was observed in the presence of a small amount of a surfactant (cf. Section 4.5). 

Scandium triflate-catalyzed aldol reactions of silyl enol ethers with aldehyde were successfully carried out in micellar systems and encapsulating systems. While the reactions proceeded sluggishly in water alone, strong enhancement of the reactivity was observed in the presence of a small amount of a surfactant. The effect of surfactant was attributed to the stabiMzation of enol silyl ether by it. Versatile carbon-carbon bondforming reactions proceeded in water without using any organic solvents. Cross-linked Sc-containing dendrimers were also found to be effective and the catalyst can be readily recycled without any appreciable loss of catalytic activity.Aldol reaction of 1-phenyl-l-(trimethylsilyloxy) ethylene and benzaldehyde was also conducted in a gel medium of fluoroalkyl end-capped 2-acrylamido-2-methylpropanesulfonic acid polymer. A nanostmctured, polymer-supported Sc(III) catalyst (NP-Sc) functions in water at ambient temperature and can be efficiently recycled. It also affords stereoselectivities different from isotropic solution and solid-state scandium catalysts in Mukaiyama aldol and Mannich-type reactions. 

The catalytic asymmetric Michael reaction using silyl enol esters (Mukaiyama-Michael reaction) as the pronucleophiles has been reported using a titanium/BINOL catalyst (in up to 90% ee). Considering furan (11.36) as a silyl enol ether, this has been shown to undergo nucleophilic addition to the Michael acceptor (11.37). The product (11.38) canbe obtained with excellent diastereocon-trol with the scandium complex of hgand (11.39), or with excellent enantiocontrol... 

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