Enolates and related species

Enolates and Related Species. Heteroatom-stabUized Species. ... 

The coordination of /3-diketonates and related species to alkali and alkaline earth cations has long been recognized. Combes first prepared Be(acac)2 in 1887,255 and the contribution of Sidgwick and Brewer concerning the nature of dihydrated alkali metal /3-diketonates plays a seminal role in the development of this area of coordination chemistry.19 A review concerning the structure and reactivity of alkali metal enolates has been written, 6 and sections on alkali and alkaline earth /3-diketonates can be found within more generalized accounts of /3-diketone complexes.257,258... 

The furoxanopyridine (584) has its azole ring expanded into a pyrazine when reacted with enamines. The reactive species is assumed to be the 2,3-dinitrosopyridine (585) (80M407). Recent review literature on benzofuroxanes suggests extension of the enamine reaction to enolate anions and related species (75S415,76H(4)767). 

Samarium has two common oxidation states +2 and -h3. Upon solution in toluene under nitrogen, an anionic Sm(II) species, [(—CH2—)5]4-calix-tetrapyrrole Sm(THF)[Li (THF)]2[Li(THF)2]Cl, forms, in part, the compound [(—CH2—)5]4-calix-tetrapyrrole Sm(THF)Li2[Li(THF)](/r -OCH=CH2) . However, this compound is a lithium enolate derived by elimination of THF. In that the metalloorganic reagent is rather similar to what will be discussed in Section XI as part of vanadium enolate chemistry, we fail to understand why in the former case with Sm a lithium enolate is formed but in the latter with V it is an ynolate that is produced. Almost nothing is known to allow comparing the energetics of metal enolates and related ynolates. We note from the enthalpies of... 

Jones and colleagues have prepared 1,4-dicarbonyl compounds by conjugate additions of enolate and related anions to a,P-unsaturated sulfoxides [80,81]. For example, the lithium enolate of acetone dimethylhydrazone (83), in the presence of dimethyl sulfide-copper(I) bromide complex, underwent conjugate addition to 2-phenylsulfinyloct-l-ene (82). Quenching the reaction mixture with dimethyl disulfide gave the doubly protected 1,4-diketone derivative (84), which, on sequential hydrolysis with copper(II) acetate and trifluoroacetic acid gave the dodecane-2,5-dione (85) as the product in 54% yield from (82) (Scheme 5.27). Other examples of the addition of enolate-type species to a,p-unsaturated sulfoxides have also been reported [82.83]. 

In general the reaction of an aldehyde with a ketone is synthetically useful. Even if both reactants can form an enol, the a-carbon of the ketone usually adds to the carbonyl group of the aldehyde. The opposite case—the addition of the a-carbon of an aldehyde to the carbonyl group of a ketone—can be achieved by the directed aldol reaction The general procedure is to convert one reactant into a preformed enol derivative or a related species, prior to the intended aldol reaction. For instance, an aldehyde may be converted into an aldimine 7, which can be deprotonated by lithium diisopropylamide (EDA) and then add to the carbonyl group of a ketone ... 

The reactivity of enolates is also affected by the metal counterion. For the most commonly used ions the order of reactivity is Mg2+ < Li+ < Na+ < K+. The factors that are responsible for this order are closely related to those described for solvents. The smaller, harder Mg2+ and Li+ cations are more tightly associated with the enolate than are the Na+ and K+ ions. The tighter coordination decreases the reactivity of the enolate and gives rise to more highly associated species. 

A quite consistent relationship is found in these and related data. Conditions of kinetic control usually favor the less substituted enolate. The principal reason for this result is that removal of the less hindered hydrogen is faster, for steric reasons, than removal of more hindered protons. Removal of the less hindered proton leads to the less substituted enolate. Steric factors in ketone deprotonation can be accentuated by using more highly hindered bases. The most widely used base is the hexamethyldisilylamide ion, as a lithium or sodium salt. Even more hindered disilylamides such as hexaethyldisilylamide7 and bis(dimethylphenylsilyl)amide8 may be useful for specific cases. On the other hand, at equilibrium the more substituted enolate is usually the dominant species. The stability of carbon-carbon double bonds increases with increasing substitution, and this effect leads to the greater stability of the more substituted enolate. 

Organometallic methods, with the possible exception of those involving the stoichiometric generation of enolates and other stabilized carbanionic species 140], have seldom been used in carbohydrate chemistry for the synthesis of cyclohexane and cyclopentane derivatives. The present discussion will not cover these areas. The earliest of the examples using a catalytic transition metal appears in the work of Trost and Runge [41], who reported the Pd-catalyzed transformation of the mannose-derived intermediate 22 to the functionalized cyclopentane 23 in 98% yield (Scheme 10). Under a different set of conditions, the same substrate gives a cycloheptenone 24. Other related reactions are the catalytic versions of the Ferrier protocol for the conversion of methylene sugars to cyclohexanones (see Chap. 26) [40,42,43]. 

The three major classes of nucleophilic carbon species are organometallic compounds, enolate derivatives and related carbanionic compounds, and neutral enol derivatives ... 

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