Zirconium, electrophilic addition with

Treatment of alkylidene-bridged zirconium—aluminum species with HMPA activates the C—A1 bond of the alkylidene unit, making it susceptible to electrophilic attack [146]. Ligand-based activation of the C—A1 bond can also be used to convert alkylidene-bridged zirconium-aluminum reagents to other bimetallic species. Thus, treatment of 3 with HMPA followed by addition of a weakly electrophilic metal salt can give rise to a new heterome-tallic species. Slow addition of a solution of R3SnCl in toluene to a solution of 3 and 1... 

Before adding aldehyde 14 a transmetalation from zirconium to zinc is necessary because of low reactivity of the sterically hindered organozirconocene compounds like 18 toward most organic electrophiles.9 Resulting alkenylethylzinc 19 reacts in a 1,2-addition with the cr,y3-unsaturated aldehyde 14 transferring exclusively the alkenyl moiety. The formation of Z -allylic alcohol 20 reveals stereochemical retention of the double bond configuration in the transmetalation and addition steps. 

Aluminum hydrides add across carbon-carbon multiple bonds to form organo-alanes381-385 (hydroalanation or hydroalumination), which are usually further reacted with suitable electrophiles. The addition is thermal or may be catalyzed by metals, mainly titanium and zirconium compounds.386,387... 

Further versatility of this approach has been realized with contrasting Lewis acid promoted additions of silyl ketene acetals, (191) to (194), to ethyl propynoate (Scheme 42). In fact, the tandem 1,4-conjugate addition-electrophile trapping protocol is feasible when titanium(IV) tetrachloride is employed. In situ functionalization of the intermediate titanate enoate (259), with select electrophiles, affords a-substituted enoates (260) to (262). On the other hand, the zinc iodide and zirconium(IV) tetrachloride protocols afford directly -y-alkoxycarbonyl-a-trimethylsilylenoates (263) and [2 + 2] adducts (264), respectively.100... 

In fact, cleavage of the carbon-zirconium bond occurs classically with various electrophiles (see Electrophile), generally under mild conditions. In addition, the other carbon-metal bond in gem metaUozirconocenes undergoes a broad range of transformations. The different reactivities of the carbon-metal and carbon-zirconium bonds are the results of the difference of electronegativity of the two metal centers and the two different bond polarities. 

Aldol Reactions. Pseudoephedrine amide enolates have been shown to undergo highly diastereoselective aldol addition reactions, providing enantiomerically enriched p-hydroxy acids, esters, ketones, and their derivatives (Table 11). The optimized procedure for the reaction requires enolization of the pseudoephedrine amide substrate with LDA followed by transmeta-lation with 2 equiv of ZrCp2Cl2 at —78°C and addition of the aldehyde electrophile at — 105°C. It is noteworthy that the reaction did not require the addition of lithium chloride to favor product formation as is necessary in many other pseudoephedrine amide enolate alkylation reactions. The stereochemistry of the alkylation is the same as that observed with alkyl halides and the formation of the 2, i-syn aldol adduct is favored. The tendency of zirconium enolates to form syn aldol products has been previously reported. The p-hydroxy amide products obtained can be readily transformed into the corresponding acids, esters, and ketones as reported with other alkylated pseudoephedrine amides. An asymmetric aldol reaction between an (S,S)-(+)-pseudoephe-drine-based arylacetamide and paraformaldehyde has been used to prepare enantiomerically pure isoflavanones. ... 

A clean cleavage of the exocyclic zirconium-carbon bond in 63 and 65 takes place when they are reacted with chlorophosphines as electrophiles. As an example, addition of (1Pr2N)2PCl to 63 or 65 resulted in transfer of the diazo C(N2)R moiety to the phosphorus atom to give the a-diazophosphines 80 or 81, respectively (Eq. 5) [49] ... 

Lewis acid promoted reactions of silicon enolates, /.e., silyl enol ethers and ketene silyl acetals with various electrophiles have yielded a wealth of novel and selective synthetic methods. This combination of reagents has been used in the past to perform such reactions as aldol-condensations with aldehydes and acetals, imine-condensations, conjugate additions to a,P-enones, alkylations, electrophilic aminations, and Diels-Alder/cyclocondensations. Our own interest in this field has involved the use of titanium tetrachloride to promote the reaction of ketene silyl acetals with non-activated imines as an efficient route to P-lactams. This reaction has been applied to the asymmetric synthesis of P-lactams via a chiral imine-titanium tetrachloride template. We have also found that both ketene silyl acetals and vinylketene silyl acetals oxidativelly dimerize or cross-couple, in the presence of titanium tetrachloride to conveniently yield various diesters . Our present study concerns reactions of vinylketene silyl acetals with non-activated imines and vinylimines promoted by titanium and zirconium tetrachlorides. 

Another approach to using zirconium is to remember that it has only sixteen electrons and can, therefore, be attacked by electrophiles (Scheme 5.69). Addition of the anion prepared by deprotonation of allyl chloride results in addition to zirconium, followed by an alkyl migration with loss of chloride, resulting in the formation... 

The stereochemically controlled addition of organometallic species of copper, tin, silicon, palladium, zirconium, and boron to acetylenes has been investigated as a route to di-, tri-, and tetra-substituted olefins. The carbon-metal bond thus formed is cleaved in a stereoselective manner either directly, or indirectly, via the corresponding vinyl-lithium reagents with a wide variety of electrophiles. In three... 

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