Enolate compounds silicon enolates

Rhodium(i) complexes are excellent catalysts for the 1,4-addition of aryl- or 1-alkenylboron, -silicon, and -tin compounds to a,/3-unsaturated carbonyl compounds. In contrast, there are few reports on the palladium(n) complex-catalyzed 1,4-addition to enones126,126a for the easy formation of C-bound enolate, which will result in /3-hydride elimination product of Heck reaction. Previously, Cacchi et al. described the palladium(n)-catalyzed Michael addition of ArHgCl or SnAr4 to enones in acidic water.127 Recently, Miyaura and co-workers reported the 1,4-addition of arylboronic acids and boroxines to a,/3-unsaturated carbonyl compounds. A cationic palladium(n) complex [Pd(dppe)(PhCN)2](SbF6)2 was found to be an excellent catalyst for this reaction (dppe = l,2-bis(diphenyl-phosphine)ethane Scheme 42).128... 

Silicon-based Lewis acids have been known for some time, and the related chemistry in catalysis has recently been reviewed [24]. Most examples in the literature are mainly based on achiral species and will be discussed only briefly in this section. In general, a broad variety of reactions can be catalyzed with compounds like MejSiOTf, MejSiNTf or MOjSiClO. One advantage over some metal Lewis acids is that they are compatible with many carbon nucleophiles like silyl enol ethers, allyl organometallic reagents and cuprates. 

Addition of silyl enol ethers to nitroarenes2 In the presence of 1 equiv. of TASF, silyl enol ethers add to nitroalkenes to form unstable ortho and/or para nitronates, which are oxidized in situ by Br2 or DDQ to nitroaryl carbonyl compounds. The position of substitution depends on the substitution pattern of the arene and the size of the silicon reagent. With less hindered silyl derivatives ortho addition is strongly favored. 

Silenolates 26, i.e. silicon analogues of enolates, are formed, as shown by Ishikawa and coworkers, when sterically congested tris(trimethylsilyl)acylsilanes 25 are treated with silyllithium compounds (Scheme 10)87a b c The silyllithium reagent does not add to the C=0 bond but exclusively cleaves a Si—Si bond, yielding the corresponding silenolate 26. 

The enhanced reactivity of SCB-derived enol ethers is attributed to the combination of ring strain and the potential for silicon to expand its coordination number form penta- to hexacoordinate compounds. Specifically, for SCBs, the reaction with nucleophiles allows for relief of the strain energy via rehybridization of the geometry at silicon from tetrahedral to trigonal bipyramidal (tbp) upon formation of a pentacoordinate species. 

One silicon tethered example that is unique in its selectivity is the cinnamyl tethered silyl enol ether shown in Sch. 17. Unlike all of the other silyl tethered examples, this compound gives a photoadduct that is the result of a cross 2+2. However, it is the product expected if the cycloaddition is a stepwise process involving radical intermediates. It is also the product expected if the reaction pathway is controlled by 7i-stacking. 

In contrast, the related silyl enol ethers are available by mild selective transformations from carbonyl compounds or other precursors 55). Their stability and that of products derived from these alkenes can easily be regulated by choosing suitable substituents at silicon. Selective cleavage of a Si—O-bond is possible with fluoride reagents under very mild conditions, and this is why cyclopropane ring opening can now be performed with high chemoselectivity. 

Silyl enol ethers and ketene silyl acetals react with tetraphenylbismuth fluoride under neutral conditions to give the corresponding a-monophenylated carbonyl compounds in good yields together with triphenylbismuthane and fluorotrimethylsilane (Equation (111)).181 The reaction is likely to be initiated by the nucleophilic attack of the fluoride ion on the silicon atom, and the regiochemistry of arylation is governed by the structure of silyl enolates. 

You have now seen how enols and enolates react with electrophiles based on hydrogen (deuterium), carbon, halogens, silicon, sulfur, and nitrogen. What remains to be seen is how new carbon-carbon bonds can be formed with alkyl halides and carbonyl compounds in their normal electrophilic mode. These reactions are the subject of Chapters 26-29. We must first look at the ways aromatic compounds react with electrophiles. You will see similarities with the behaviour of enols. 

If the 1,5-diearbonyl compound is required, then an aqueous work-up with either acid or base cleaves the silicon-oxygen bond in the product but the value of silyl enol ethers is that they can undergo synthetically useful reactions other than just hydrolysis. Addition of the silyl enol ether derived from aeetophenone (PhCOMe) to a disubstituted enone promoted by titanium tetrachloride is very rapid and gives the diketone product in good yield even though a quaternary carbon atom is created in the conjugate addition, This is a typical example of this very powerful class of conjugate addition reactions. 

The other side of the coin is that the S 2 reaction at carbon is not much affected by partial positive [ charge (5+) on the carbon a tom. The Sn2 reaction at silicon is affected by the charge on silicon. The r most electrophilic silicon compounds are the silyl triflates and it is estimated that they react some 108-109 times faster with oxygen nucleophiles than do silyl chlorides. Trimethylsilyl triflate is, in fact, an excellent Lewis acid and can be used to form acetals or silyl enol ethers from carbonyl compounds, and to react these two together in aldol-style reactions. In all three reactions the triflate attacks an oxygen atom. 

The second major class of non-umpolung nucleophilic carbene catalysis comprises reactions by initial NHC-activation of various silicon compounds. Their proposed common pathway is thought to lead to a hypervalent silicon complex4 and thus provide carbene-catalyzed activation of the corresponding nucleophiles such as TMSCN, TMSCF3 etc. (Kano et al. 2006 Song et al. 2005 2006). It is not only certain carbon-silicon bonds that can be effectively activated, but a comparable activation of Si-O bonds, e.g. of trimethylsily enol ethers etc., allows for mild, NHC-promoted Mukaiyama aldol reactions (Scheme 6 Song et al. 2007). 

Although the reaction system stated above has extended the substrate applicability in Mannich reactions in water, there is still a drawback that the silicon enolates, which are prepared from the corresponding carbonyl compounds usually under anhydrous conditions, have to be used. From atom-economical and practical points of view, it is desirable to develop an efficient system for Mannich-type reactions in which the parent carbonyl compounds are directly used. Along this line, we next investigated three-component Mannich-type reactions in water using ketones, instead of silicon enolates, as nucleophilic components, and found that DBSA was also an effective catalyst [36]. An example is shown in Equation (7), where only 1 mol% DBSA was sufficient to give the desired product. 

An example of fortuitous vanadium enolate chemistry is the CO addition reaction to a silylamido vanadium species in which the dimeric metallocycle 32 is transformed into the corresponding cyclic enolate 33, as shown in equation 12. Given silicon s profound oxophilicity, the absence of the Si-O moieties in 33 is surprising. For example, the liquid phase reaction shown in equation 13 is exothermic by ca 420 kJmol , as determined from the enthalpies of formation of tetramethoxymethane and the silicon compounds . 

---