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Acetic acid Activation Energy

The acid cleavage of the aryl— silicon bond (desilylation), which provides a measure of the reactivity of the aromatic carbon of the bond, has been applied to 2- and 3-thienyl trimethylsilane, It was found that the 2-isomer reacted only 43.5 times faster than the 3-isomer and 5000 times faster than the phenyl compound at 50,2°C in acetic acid containing aqueous sulfuric acid. The results so far are consistent with the relative reactivities of thiophene upon detritia-tion if a linear free-energy relationship between the substituent effect in detritiation and desilylation is assumed, as the p-methyl group activates about 240 (200-300) times in detritiation with aqueous sulfuric acid and about 18 times in desilylation. A direct experimental comparison of the difference between benzene and thiophene in detritiation has not been carried out, but it may be mentioned that even in 80.7% sulfuric acid, benzene is detritiated about 600 times slower than 2-tritiothiophene. The aforementioned consideration makes it probable that under similar conditions the ratio of the rates of detritiation of thiophene and benzene is larger than in the desilylation. A still larger difference in reactivity between the 2-position of thiophene and benzene has been found for acetoxymercuration which... [Pg.44]

Kinetic studies have been carried out using the 1 1-complex iodobenzene dichloride as a source of molecular chlorine. In acetic acid solutions, the dissociation of this complex is slower than the rate of halogenation of reactive aromatics such as mesitylene or pentamethylbenzene, consequently the rate of chlorination of these is independent of the aromatic concentration. Thus at 25.2 °C first-order chlorination rate coefficients were obtained, being approximately 0.2 x 10-3 whilst the first-order dissociation rate coefficient was 0.16 xlO-3 from measurements at 25.2 and 45.6 °C the corresponding activation energies... [Pg.106]

With trifluoroacetic acid as solvent, toluene and o-xylene gave second-order kinetics and for the activation energy for toluene was 12.7 (from data at 1.6 and 25.2 °C), i.e. considerably less than for the zinc chloride-catalysed reaction in acetic acid330. [Pg.138]

Thomas and Long488 also measured the rate coefficients for detritiation of [l-3H]-cycl[3,2,2]azine in acetic acid and in water and since the rates relative to detritiation of azulene were similar in each case, a Bronsted correlation must similarly hold. The activation energy for the reaction with hydronium ion (dilute aqueous hydrochloric acid, = 0.1) was determined as 16.5 with AS = —11.3 (from second-order rate coefficients (102At2) of 0.66, 1.81, 4.80, and 11.8 at 5.02, 14.98, 24.97, and 34.76 °C, respectively). This is very close to the values of 16.0 and —10.1 obtained for detritiation of azulene under the same condition499 (below) and suggests the same reaction mechanism, general acid catalysis, for each. [Pg.215]

Dissimilatory sulfate reducers such as Desul-fovibrio derive their energy from the anaerobic oxidation of organic compounds such as lactic acid and acetic acid. Sulfate is reduced and large amounts of hydrogen sulfide are generated in this process. The black sediments of aquatic habitats that smell of sulfide are due to the activities of these bacteria. The black coloration is caused by the formation of metal sulfides, primarily iron sulfide. These bacteria are especially important in marine habitats because of the high concentrations of sulfate that exists there. [Pg.51]

A slow oxidation of acetic acid by Mn(III) acetate occurs at 100 °C to give mainly acetoxyacetic acid and CO2 with an activation energy of 28 kcal.mole F In the presence of excess Mn(Il) a first-order disappearance of oxidant is found . The low yield of methane is incompatible with an initial homolysis of the type... [Pg.386]

The selectivity to citraconic anhydride decreases and that to acetic acid increases as the temperature is raised. The results indicate that the activation energy for the formation of citraconic anhydride is much lower than that for the formation of acetic acid. The selectivity to acetic acid decreases steadily with a lowering of the temperature. However, the highest selectivity to citraconic anhydride is obtained at 200°C. Possibly vaporization of pyruvic acid may become difficult at temperatures below 200°C. The yield of citraconic anhydride reached 71 mol% and that of acetic acid was 7 mol% at the pyruvic acid conversion of 98% the loss was about 20 mol%. [Pg.206]

Catabolism The breakdown of complex molecules to simpler ones to yield energy (e.g., triacylglycerols to fatty acids) and the inactivation of physiologically active molecules (e.g., acetylcholine to choline and acetic acid). [Pg.239]


See other pages where Acetic acid Activation Energy is mentioned: [Pg.795]    [Pg.795]    [Pg.802]    [Pg.740]    [Pg.740]    [Pg.126]    [Pg.75]    [Pg.260]    [Pg.464]    [Pg.63]    [Pg.432]    [Pg.87]    [Pg.99]    [Pg.101]    [Pg.102]    [Pg.117]    [Pg.119]    [Pg.129]    [Pg.130]    [Pg.132]    [Pg.132]    [Pg.264]    [Pg.279]    [Pg.316]    [Pg.355]    [Pg.344]    [Pg.298]    [Pg.99]    [Pg.440]    [Pg.112]    [Pg.253]    [Pg.148]    [Pg.257]    [Pg.117]    [Pg.322]    [Pg.122]   
See also in sourсe #XX -- [ Pg.232 , Pg.233 ]




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