Reversibility with carbonyl compounds

How does structure determine organic reactivity, 35, 67 Hydrated electrons, reactions of, with organic compounds, 7,115 Hydration, reversible, of carbonyl compounds, 4, 1 Hydride shifts and transfers, 24, 57... 

In this section, reactions of zinc dienolates with carbonyl compounds, imines and conjugated enones will be considered all of these reactions have been proved to be reversible, and, hence, conditions favouring either kinetic or thermodynamic control will drive the reaction towards the formation of different regioisomers. Generally, equilibrating conditions lead to attack at the position of 190, as a thermodynamically more stable conjugated carbonyl or carboxylic compound is formed on the other hand, kinetic control leads to attack at the electron richer a-position. 

Silyl enol ethers undergo reaction with carbonyl compounds promoted by Lewis acids, but especially titanium tetrachloride. The reaction is thought to proceed via a titanium chelate which inhibits the reverse aldol process and the regiochemical integrity of the starting silyl enol ether is retained (Scheme 102).373... 

A condition of equilibrium is reached (70-90 per cent of bisulphite compound with equivalent quantities of the reagents in 1 hour), but by using a large excess of bisulphite almost complete conversion into the addition compound results. Since the reaction is reversible, the carbonyl compound can be recovered by adding to an aqueous solution of the bisulphite compound sufficient sodium carbonate solution or hydrochloric acid to react with the free sodium metabisulphite present in the equilibrium mixture. Bisulphite compounds may therefore be employed for the purification of carbonyl compounds or for their separation from other organic substances. 

In chapter 10 we compared C-C disconnections with related two-group C-X disconnections, mainly at the alcohol oxidation level. In this chapter we deal more fully with carbonyl compounds, chiefly aldehydes and ketones, by two related disconnections. We start by comparing the acylation of heteroatoms by acid derivatives such as esters (a 1,1-diX disconnection 1 that can also be described as a one-group C-X disconnection) with the acylation of carbon nucleophiles and move on to compare the 1,2-diX disconnection 3 with the alkylation of enolates 6. Here we have reversed the polarity. We mention regioselectivity—a theme we shall develop in chapter 14. 

The reaction of 1,3-dibromopropene with carbonyl compounds mediated by indium in water gives 3,3-disubsti-tuted propene 63 (Scheme 55). In the formation of 63, 1,3-dibromopropene acts as a w-allyl dianion synthon. Aromatic aldehydes generally have a higher selectivity than aliphatic ones in the product formation. Unsubstituted and electron-withdrawing group-substituted benzaldehydes give mainly 3,3-disubstituted propene 63. For electron-rich benzaldehydes, the formation of both 3,3- 63 and 1,3-disubstituted propene 64 is dramatically decreased and the selectivity is reversed completely to give diene 65 and homoallylic alcohol 66.219... 

An interesting feature of isomiinchnones is their ability to undergo 1,3-dipo-lar cycloaddition with carbonyl compounds, a reaction which is unprecedented with miinchnones [56]. This is illustrated by the reaction of diazoimide 106 with Cu(acac)2 in the presence of several different aldehydes and ketones which resulted in the formation of cycloadducts of type 107 -109. When benzil was used as the dipolarophile, the regioselectivity was reversed giving rise to cycloadduct 110 as the only regioisomer. 

A possible explanation of these differences is that the reactions of the trivalent phosphorus compounds with carbonyl compounds may contain reversible and irreversible steps. The condensation of one mole of biacetyl with one of the phosphite probably contains several reversible steps leading eventually to the 1 1 oxyphosphorane. If this 1 1 adduct is of high energy as a result of ring strain and/or intramolecular crowding in the TBP, it might not be observable. The carbon-carbon condensation step in the formation of the 2 1 adducts is probably essentially irreversible under most conditions hence, once that step is achieved, there is an opportunity for isolation of the 2 1 phosphoranes. 

How does structure determine organic reactivity, 35, 67 Hydrated electrons, reactions of, with organic compounds, 7,1 15 Hydration, reversible, of carbonyl compounds, 4, 1 Hydride shifts and transfers, 24, 57 Hydrocarbons, small-ring, gas-phase pyrolysis of, 4, 147 Hydrogen atom abstraction from O—H bonds, 9, 127 Hydrogen bonding and chemical reactivity, 26, 255 Hydrogen isotope effects in aromatic substitution reactions. 2, 163... 

Reverse regioselectivity is observed when isopiene zirconocene is treated with carbonyl compounds under photochemical conditions, at -70 C where the thermally induced addition is totally suppressed. 

The reaction between sulfur ylides and carbonyl compounds entails attack of the ylide on the carbonyl to form a betaine, which then collapses with expulsion of the neutral sulfide or sulfoxide (Scheme 1 X = R2S ). - - a theoretical study of this mechrmism has appeared. Ylides belonging to the general classes of (1) and (2) differ in stability and in the relative rates of the two mechanistic steps. Specifically, the more stable (2) reacts reversibly with carbonyl groups, whereas (1) undergoes a kinetic addition to the substrate followed by a rapid collapse of the betaine to an epoxide. Differences in chemoselectivity and stereoselectivity between Ae ylides are attributed to this key difference. - - ... 

Anion (64) generally reacts with carbonyl compounds at the y-position, whereas it reacts with alkyl halides at the a-position. The triethylaluminum ate complex of (64) exhibits reversed regioselectivity propanal and 2-methylpropanal give exclusively the a-adducts. The anti isomers are produced predominantly. Organic halides and trimethylsilyl chloride do not react with the aluminum ate complex. 9,11-Dodecadien-l-yl acetate, a pheromone of Diparopsis castanea, is prepared by condensation of 9-oxonon-l-yl acetate via the ate complex (Scheme 43). 

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