Acetyl decomposition mechanism

A situation similar to that in acetyl phosphate is also encountered in benzoyl phosphate76 . Electron-attracting substituents on the phenyl ring accelerate the hydrolysis of the dianion (a linear relationship exists between log khydrol and the Hammett a constants with q = 1.2 and the linear log ki,j,drol./pKa relationship is the same as for the phosphoric monoaryl ester dianions65 . On the other hand, hydrolysis of the monoanion is influenced only slightly by substituents in the phenyl ring. These observations can also be rationalized in terms of the decomposition mechanism to the POf ion formulated for 116 and 117. 

Scheme 17.4. Decomposition mechanism of competitive formation ofpiotonated imine and ortho acetyl aniline. (Adapted with permission from Ref. 46.)...

CR(Q(262)1017>. The nucleophilic reactivity of the oxygen atom has been observed in the acetylation by acetic anhydride of 2-aryl- and 2-heteryl-A2-thiazolin-4-ones (Scheme 136). 2-Alkoxy and 2-methyl derivatives of A2-thiazolin-4-one (196) react with OPCl3 to yield thiazolylphosphoric esters (197) which have insecticidal uses (Scheme 137). An example of the electrophilic reactivity of the C-4 atom is the easy formation of oxime and phenylhydrazone derivatives. 5-Aryl-A2-thiazolin-4-one (198) gives the 1,3-dipolar cycloaddition product (199) with methyl fumarate and methyl maleate (Scheme 138). Under similar conditions, treatment of (198) with dimethyl acetylenedicarboxylate (DMAD) yields a thiophene derivative (202) when R = Ph and a pyridone derivative (203) when R = H (Scheme 139). The proposed mechanism involves the formation of a mesoionic intermediate (200) which reacts in a cycloaddition with a second molecule of DMAD, yielding (201), the decomposition of which depends on the R substituent. 

The mechanism of reductive elimination of a hydrido alkyl complex is therefore often approached in an indirect manner. The hydrido-alkyl complex is made not by oxidative addition of the alkane but by some other route. The decomposition of the hydrido-alkyl complex to give alkane is then studied for mechanistic information. Reductive eliminations of an aldehyde from an acyl-hydrido complex, Reaction 2.7, and acetyl iodide from an iodo-acyl complex,... 

In non-aqueous solutions the Kolbe electrosynthesis takes place with high eflSciency at platinized platinum and gold, as well as at smooth platinum, anodes increase of temperature and the presence of catalysts for hydrogen peroxide decomposition, both of which have a harmful effect in aqueous solution, have relatively little influence. The mechanism of the reaction is apparently quite different in non-aqueous solutions and aqueous solutions in the former no hydroxyl ions are present, and so neither hydroxyl radicals nor hydrogen peroxide can be formed. It is probable, therefore, that direct discharge of acetate ions occurs at a potential which is almost independent of the nature of the electrode material in a given solvent. The resulting radicals probably combine in pairs, as in aqueous solution, to form acetyl peroxide, which subsequently decomposes as already described. ... 

The decompositions of the formyl and acetyl radicals are certain to be in the fall-off region at the pressures used in the investigations of the acetaldehyde pyrolysis. However, the complexity of the mechanism impedes any conclusion to be drawn from this system. 

Martin et that attempts to trap the acetoxy radical with iodine, galvinoxyl or diphenylhydrazyl were either unsuccessful or ambiguous. However, isotopic labeling experiments show that cage recombination does occur and the mechanism of acetyl peroxide decomposition may be formulated as... 

Secondary isotope studies are consistent with the suggested mechanism for acetyl peroxide decomposition. It was concluded from the data given in Table 90 that little or no methyl radical character was developed in the rate-determining step . This view has been contested with data from a study of and 0-iso-tope effects in the decomposition of acetyl peroxide. The carbon isotope effect in... 

The reaction of acylimidazoles with imidazole is subject to both imidazole and imidazolium ion catalysis (Fife, 1965). The latter reaction is no doubt due to the imidazole-catalyzed hydration of acetylimidazolium ion, as in 18, and fully analogous to the N-methylimidazole-catalyzed hydrolysis of N-acetyl,N -methylimidazolium ion. The mechanism of the former reaction is undefined at the present time, since no 0 exchange studies have been performed with acylimidazoles in more alkaline solution where imidazole catalysis occurs. The leaving group, the imidazole anion, is quite basic (piC = 14-5) therefore it is possible that general base-catalyzed decomposition of the neutral tetrahedral intermediate (24) or general acid-assisted decomposition of the anionic tetrahedral intermediate (25) may occur. The general base-catalyzed alkaline hydrolysis of amides most probably occurs by the... 

Besides condensation reactions to form heavy ends, polyester ketones are formed by the decomposition of acetyl iodide to polyester polyketones (eq. (22)) following a mechanism similar to the decomposition of acetyl chloride [64d,ej. 

Tetracarbonylalkyl derivatives of cobalt(I) have low stability. As early as 1964 it had been noted that ketones are formed in the thermal decomposition of CoR(CO)4 (R = Me, Et) presumably involving a binuclear intermediate or an intermolecular mechanism. The mechanism of acetone formation was studied for other cobalt systems that are more easily handled, namely, Co(>/ -C5H5)Me2(PMe3) and Co2(ti -CsH )2Me2(fi2-CO)2 . Upon carbonylation, in the former case, the transient carbonyl derivative Co()j -C5H5)Me2(CO) was observed spectroscopically, whereupon it underwent carbon monoxide insertion to give an acetyl-methyl complex, followed by reductive elimination of acetone ... 

The catalytic pathway is best described as a random binding kinetic mechanism involving the formation of the ternary complex E-acetyl-P-ADP, with direct phosphoryl group transfer between enzyme-bound substrates to form the product ternary complex E-acetate-ATP. The formation and decomposition of these ternary complexes involve only noncovalent binding interactions of the enzyme with the substrates and products. The stereochemistry is inconsistent with a mechanism in which the phosphoryl group is transferred to an enzymic nucleophile as a step in the interconversion of the ternary complexes. The case of acetate kinase is one in which the stereochemical course of phosphoryl group transfer essentially discredited a double-displacement mechanism that had been reasonably well supported by other evidence. 

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