Carbonyl compounds tetrahedral intermediates from

Tetrahedral Intermediates Derived from Carbonyl Compounds, Pentacoordinate Intermediates Derived from Phosphoryl and Sulfonyl Compounds, and Concerted Paths Which Avoid Them... 

As we saw in A Preview of Carbonyl Compounds, the most general reaction of aldehydes and ketones is the nucleophilic addition reaction. A nucleophile, Nu-, approaches along the C=0 bond from an angle of about 75° to the plane of the carbonyl group and adds to the electrophilic C=0 carbon atom. At the same time, rehybridization of the carbonyl carbon from sp2 to sp3 occurs, an electron pair from the C=0 bond moves toward the electronegative oxygen atom, and a tetrahedral alkoxide ion intermediate is produced (Figure 19.1). 

Aldol reactions, Like all carbonyl condensations, occur by nucleophilic addition of the enolate ion of the donor molecule to the carbonyl group of the acceptor molecule. The resultant tetrahedral intermediate is then protonated to give an alcohol product (Figure 23.2). The reverse process occurs in exactty the opposite manner base abstracts the -OH hydrogen from the aldol to yield a /3-keto alkoxide ion, which cleaves to give one molecule of enolate ion and one molecule of neutral carbonyl compound. 

TETRAHEDRAL INTERMEDIATES DERIVED FROM CARBONYL COMPOUNDS... 

We showed in Figs. 3-2 and 3-3 that the tetrahedral intermediate which is initially formed from the reaction of a nucleophile with a carbonyl compound may further react in a number of different ways. In this section, we will consider some reactions which proceed along the pathway indicated in Fig. 3-3. The hydration of ketones is a reaction analogous to the hydrolysis of an ester, with the first step of the reaction involving nucleophilic attack of water on the carbonyl group. The tetrahedral intermediate is trapped by reaction with a proton to yield the hydrated form of the ketone, the geminal diol (Fig. 3-15). Similar reactions occur with alcohols as nucleophiles to yield, initially, hemiacetals. 

From Figure 6.40 you can see that these particular conditions are fulfilled if the rate-determining step of the acylation—i.e., the formation of the tetrahedral intermediate B—is considerably faster than the further reaction of the carbonyl compound C giving the alkoxide D. In more quantitative terms, it would hence be required that the rate of formation [Pg.307]

---