Kinetics carbonyl anions

The scope and limitations of the metal anions of 2-halo-l,3-dithiane trans-1,3-dioxide as diastereoselective carbonyl anion equivalents has been explored with regard to reaction with aldehydes.79 Reactions of metallated trans-, 3-dithiolanc 1,3-dioxide (five-membered ring) with aldehydes under kinetic and thermodynamic control have also been studied and contrasted with those of the metallated monooxide, parent sulfide, and 1,3-dithiane 1,3-dioxide (six-membered ring).80... 

A rather different approach to carbonylation of aliphatic halides involves the carbonyl anion [Co(CO)4] which, being a kinetically stable 18-electron species, attacks the halide by nucleophilic displacement rather than by undergoing oxidative addition. A probable catalytic cycle for cobalt-catalyzed carbonylation of benzyl chloride is shown in Scheme 6. ... 

Directed aldol reaction (Section 19.5B) A crossed aldol reaction in which the desired enolate anion is generated first and rapidly using a strong base (e.g., LDA) after which the carbonyl reactant to be attacked by the enolate is added. If both a kinetic enolate anion and a thermodynamic enolate anion are possible, this process favors generation of the kinetic enolate anion. 

One possible reaction for 60 is an intramolecular condensation with the other carbonyl (see Chapter 22, Section 22.6, for reactions of this type), but that would lead to a four-membered ring product, 61. The activation barrier to form this strained ring is high, so this reaction is slow (see Chapter 8, Section 8.5.3). The reaction conditions favor thermodynamic control (protic solvent, hydroxide, heat see Chapter 22, Section 22.4.2), which means that enolate anion 60 is in equilibrium with the neutral diketone. Further reaction with hydroxide generates the kinetic enolate anion 62 as part of the equilibrium mixture. If 62 attacks the carbonyl in an intramolecular aldol reaction (Chapter 22, Section 22.6), a six-membered ring is formed (63) in a rapid and highly favorable process. 

Turning to carbonyls containing more than one metal atom, Johnson has proposed a new mechanism for the substitution reactions of metal-carbonyl dimers Corraine and Atwood have produced a number of papers dealing with carbonyl anions in reaction with carbonyl dimers. The thermodynamic and kinetic factors that control the reactions are also discussed 2. Heaton et al have discussed the electron-microscopy of transition-metal carbonyl clusters 25,26 Butler et al have published a comparison of photoacousdc, attenuated total reflection, and transmission infrared-spectra of crystalline organoiron(ll) carbonyl-complexes 27. 

M Ru or Os) is reacted with a metal carbonylate anion. The hydrido species [Ru30sH2(C0)i3] and [0s3RuH(C0)3] are formed on protonation of the products. Metallo-selective reactions of [Co3RuH(C0)i2] have been observed in which CO bonded to Ru is substituted by amines, whereas phosphine substitution occurs exclusively at Ligand substitution kinetics of the [Ru3H(C0)n]" anion... 

The block copolymer produced by Bamford s metal carbonyl/halide-terminated polymers photoinitiating systems are, therefore, more versatile than those based on anionic polymerization, since a wide range of monomers may be incorporated into the block. Although the mean block length is controllable through the parameters that normally determine the mean kinetic chain length in a free radical polymerization, the molecular weight distributions are, of course, much broader than with ionic polymerization and the polymers are, therefore, less well defined,... 

The obvious choice for a reagent is again a sulphur ylid, but how are we to control the regioselectivity of the addition The more reactive sulphur ylids, notably (26) and (27), add directly to the carbonyl group (kinetic control, cf p T 117 ) giving epoxides (29) while the more stable ylid (28), which combines the anion-stabilisations of (26) and (27), adds reversibly and gives the thermodynamic product (25). 

Stereoinversion Stereoinversion can be achieved either using a chemoenzymatic approach or a purely biocatalytic method. As an example of the former case, deracemization of secondary alcohols via enzymatic hydrolysis of their acetates may be mentioned. Thus, after the first step, kinetic resolution of a racemate, the enantiomeric alcohol resulting from hydrolysis of the fast reacting enantiomer of the substrate is chemically transformed into an activated ester, for example, by mesylation. The mixture of both esters is then subjected to basic hydrolysis. Each hydrolysis proceeds with different stereochemistry - the acetate is hydrolyzed with retention of configuration due to the attack of the hydroxy anion on the carbonyl carbon, and the mesylate - with inversion as a result of the attack of the hydroxy anion on the stereogenic carbon atom. As a result, a single enantiomer of the secondary alcohol is obtained (Scheme 5.12) [8, 50a]. 

The fundamental aspects of the structure and stability of carbanions were discussed in Chapter 6 of Part A. In the present chapter we relate the properties and reactivity of carbanions stabilized by carbonyl and other EWG substituents to their application as nucleophiles in synthesis. As discussed in Section 6.3 of Part A, there is a fundamental relationship between the stabilizing functional group and the acidity of the C-H groups, as illustrated by the pK data summarized in Table 6.7 in Part A. These pK data provide a basis for assessing the stability and reactivity of carbanions. The acidity of the reactant determines which bases can be used for generation of the anion. Another crucial factor is the distinction between kinetic or thermodynamic control of enolate formation by deprotonation (Part A, Section 6.3), which determines the enolate composition. Fundamental mechanisms of Sw2 alkylation reactions of carbanions are discussed in Section 6.5 of Part A. A review of this material may prove helpful. 

A comprehensive kinetic, spectroscopic, and analysis study into the Rh-catalyzed carbonylation of ROH (R = Me, Et, Pr) has been reported.4,5 In all cases, the reaction rate is first order in both [Rh] and added [HI] and independent of CO pressure. The only Rh species observed under catalytic conditions was (1). The rates of carbonylation decreased in the stated order of R, with relative rates of 21 1 0.47, respectively at 170 °C. All the data are consistent with rate-determining nucleophilic attack by the Rh complex anion on the corresponding alkyl iodide. 

Prior to our studies it was recognized that ion pairing with anionic metal carbonyls could promote CO insertion and related reactions (14-16). Both kinetic and non-kinetic evidence suggests the importance of ion pairs in these types of reactions (14,17). For example, a small cation was found to greatly accelerate the CO insertion reaction relative to the same reaction with a large cation, equation 6 (14). 

The use of an anionic reagent for addition at carbonyl carbon rather than a fully esterified form of a trivalent phosphorus acid obviates a troublesome aspect of the Abramov reaction. Specifically no dealkylation step is required. Mechanistic investigations257 258 indicate that the reaction proceeds much as a simple "aldol"-type reaction in which the anionic phosphorus site adds directly to the carbonyl center. While the initial efforts concerned with the "Pudovik reaction"259 were directed toward the use of sodium salts of the simple dialkyl phosphites, as shown in Equation 3.17,260 266 with a, 5-unsaturated carbonyl systems (vide infra) competition between sites for addition can occur. Addition at the carbonyl carbon site is the kinetically favored route.267-270... 

A recent example is provided by the kinetics of closure of l,l-bis(ethoxy-carbonyl) cycloalkanes [7] from the anions derived from diethyl o-bromoal-kylmalonates (49a), which have been investigated by Casadei et al. (1984) in... 

Nitrobenzoylamino)-2,2-dimethylpropanamide (143 R = Me) reacts in methanol-DMSO solution with sodium methoxide to yield 5,5-dimethyl-2-(4-nitrophenyl)imidazol-4(5//)-one (144 R = Me). The 4-methoxyphenyl derivative and the parent phenyl derivative react similarly, as do compounds in which variation of the 2-substitutent (R = Pr , Ph, 4-O2NC6H4) was made. The mechanism of the cyclization probably involves initial formation of the anion of the alkanamide (145), which adds to the carbonyl group of the benzamido moiety to yield the tetrahedral oxyanion (146) proton transfer and dehydration then yield the heterocycle (144). The kinetics of hydrolysis in water at 70 °C and pH 2-11 of A-glycidylmorpholine (147) have been reported. ... 

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