Reactivity isomer effects

M amines competed effectively with 55.5 M H O and 0.1 M OH for the nitrosating agent and suggested that possibly more reactive isomers of N O and N 0. are generated by the gaseous NO and NO components Here, -nltrosamines result from reaction of the unsymmetrical tautomer (ON-NO ), whereas the symmetrical tautomer (O N-NO ) produces an N-nitramine possibly via a four-center transition state. The results for N O may be xplalned similarly in terms of the corresponding ON-nO.ON-ONO tautomers. This conclusion has a prece-... 

The high mineralization activity of the PVDF-W10 membrane in comparison to the homogeneous catalyst can be ascribed to the selective absorption of the organic substrate from water on the hydrophobic PVDF polymer membrane that increases the effective phenol concentration around the catalytic sites. Moreover, the polymeric hydrophobic environment protects the decatungstate from the conversion over longer time to a less-reactive isomer that has a maximum absorption at a wavelength of 280 nm. 

The values of k1P, klQ, and kls for conversion of the highly reactive isomer A, still await regression to account for a possible drain effect, which in this case turns out to be rather severe The corrected coefficients are almost three times as large as the estimates above. Otherwise the fit is fairly reasonable, with the following exception. 

Electronic Size Effects. Understanding the size-dependent electronic structure of the Au /MgO(Fsc) model catalysts, which is fundamental for elucidation of their atom-by-atom controlled reactivity, is facilitated by analysis of the spectra of the LDOS projected on the oxygen molecule and on the metal cluster (see also Electronic Size Effects ). Figure 1.78a shows the LDOS projected on the O2 molecule which is adsorbed at the peripheral site (Fig. 1.77f) of the more reactive isomer of the Aug/MgO(F5c) model catalyst. As shown above, bonding and activation of O2 on the octamer is enabled by resonances formed between the cluster s electronic states and the 2jt molecular states... 

Attempts to effect the reaction involving the previously isolated isomeric mixture of 310 and 311 and BuLi in THF at —105 "C resulted in only a 10% yield of the bycyclic compound 309- The products of this reaction are presented in Table 62. The major products obtained were the ethylene derivatives 312, 313 and 314. It was also established that the cis compound 310 was at all times the more reactive isomer. 

Resonance effects are the primary influence on orientation and reactivity in electrophilic substitution. The common activating groups in electrophilic aromatic substitution, in approximate order of decreasing effectiveness, are —NR2, —NHR, —NH2, —OH, —OR, —NO, —NHCOR, —OCOR, alkyls, —F, —Cl, —Br, —1, aryls, —CH2COOH, and —CH=CH—COOH. Activating groups are ortho- and para-directing. Mixtures of ortho- and para-isomers are frequently produced the exact proportions are usually a function of steric effects and reaction conditions. 

Differences in reactivity of the double bond among the four isomers are controlled by substitution pattern and geometry. Inductive effects imply that the carbons labeled B in Table 3 should have less electron density than the A carbons. nmr shift data, a measure of electron density, confirm this. 

Only trace amounts of side-chain chlorinated products are formed with suitably active catalysts. It is usually desirable to remove reactive chlorides prior to fractionation in order to niinimi2e the risk of equipment corrosion. The separation of o- and -chlorotoluenes by fractionation requires a high efficiency, isomer-separation column. The small amount of y -chlorotoluene formed in the chlorination cannot be separated by fractionation and remains in the -isomer fraction. The toluene feed should be essentially free of paraffinic impurities that may produce high boiling residues that foul heat-transfer surfaces. Trace water contamination has no effect on product composition. Steel can be used as constmction material for catalyst systems containing iron. However, glass-lined equipment is usually preferred and must be used with other catalyst systems. 

The effect of conformation on reactivity is intimately associated with the details of the mechanism of a reaction. The examples of Scheme 3.2 illustrate some of the w s in which substituent orientation can affect reactivity. It has been shown that oxidation of cis-A-t-butylcyclohexanol is faster than oxidation of the trans isomer, but the rates of acetylation are in the opposite order. Let us consider the acetylation first. The rate of the reaction will depend on the fiee energy of activation for the rate-determining step. For acetylation, this step involves nucleophilic attack by the hydroxyl group on the acetic anhydride carbonyl... 

Although the limited examples of AE reactions on 2,3Z-substituted allyl alcohols appear to give product epoxides in good enantioselectivity, the highly substituted nature of these olefins can have a deleterious effect on the reactivity. For example, Aiai has shown that the 2,3E-substituted allyl alcohol 30 can be epoxidized with either (-)-DET or (+)-DET in good yields and enantioselectivity. However, the configurational isomer 32 is completely unreactive using (-)-DET, even after a 34 h reaction time. 

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... 

Indirect deactivation by an alkoxy group is apparent in the sluggish reaction of 4-butoxy-2-chloroquinoline with w-butylamine (EtOH, 5 hr, 180°, but not at 80°). The chloro group in 2-chloro-4-ethoxy-quinoline is more reactive than that in the 4-chloro-2-ethoxy isomer toward alkoxides or amines in spite of the usually more effective para indirect deactivation in the former. For kinetic data on quinolines see Tables X and XI, pp. 336 and 338, respectively. 

The relation of activation by para vs. ortho ring-nitrogen in bicy-clics is altered by these special cases. For example, 4-chloroquinazoline (4-Cl-l,3-diaza) is much more reactive than the 2-chloro isomer (2-Cl-l,3-diaza) for two reasons, one being the poor activation in 2-Le-3-aza compounds. 4-Chloro-l,8-naphthyridine will be decreased in reactivity relative to its 2-chloro isomer due to the very poor activation in 4-Le-8-aza compounds and it may be only slightly more reactive than the mono-aza analog 4-chloroquinoline. The greater reactivity at the 2-position of 2,4-dichloro-l,8-naphthyri-dine 3 can be ascribed to this 4-Le-8-aza effect. ... 

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