Chlorobenzene reactivity

Dinitrophenol may be readily prepared by taking advantage of the great reactivity of the chlorine atom in 2 4-dinitro-l-chlorobenzene ... 

Characteristics of the system as nitrating reagents Wibaut, who introduced the competitive method for determining reactivities (his experiments with toluene, benzene and chlorobenzene were performed under heterogeneous conditions and were not successful), pointed out that solutions of nitric acid in acetic anhydride are useful in making comparisons of reactivities because aromatic compounds are soluble in them. ... 

Chlorination is carried out m a manner similar to brommation and provides a ready route to chlorobenzene and related aryl chlorides Fluormation and lodmation of benzene and other arenes are rarely performed Fluorine is so reactive that its reaction with ben zene is difficult to control lodmation is very slow and has an unfavorable equilibrium constant Syntheses of aryl fluorides and aryl iodides are normally carried out by way of functional group transformations of arylammes these reactions will be described m Chapter 22... 

An ortho nitro group exerts a comparable rate enhancing effect m Chloronitrobenzene although much more reactive than chlorobenzene itself is thousands of times less reac tive than either o or p chloronitrobenzene... 

Dinitrochlorobenzene can be manufactured by either dinitration of chlorobenzene in filming sulfuric acid or nitration ofy -nitrochlorobenzene with mixed acids. Further substitution on the aromatic ring is difficult because of the deactivating effect of the chlorine atom, but the chlorine is very reactive and is displaced even more readily than in the mononitrochlorobenzenes. 

Chemical Properties and Reactivity. LLDPE is a saturated branched hydrocarbon. The most reactive parts of LLDPE molecules are the tertiary CH bonds in branches and the double bonds at chain ends. Although LLDPE is nonreactive with both inorganic and organic acids, it can form sulfo-compounds in concentrated solutions of H2SO4 (>70%) at elevated temperatures and can also be nitrated with concentrated HNO. LLDPE is also stable in alkaline and salt solutions. At room temperature, LLDPE resins are not soluble in any known solvent (except for those fractions with the highest branching contents) at temperatures above 80—100°C, however, the resins can be dissolved in various aromatic, aUphatic, and halogenated hydrocarbons such as xylenes, tetralin, decalin, and chlorobenzenes. 

A method for the polymerization of polysulfones in nondipolar aprotic solvents has been developed and reported (9,10). The method reUes on phase-transfer catalysis. Polysulfone is made in chlorobenzene as solvent with (2.2.2)cryptand as catalyst (9). Less reactive crown ethers require dichlorobenzene as solvent (10). High molecular weight polyphenylsulfone can also be made by this route in dichlorobenzene however, only low molecular weight PES is achievable by this method. Cross-linked polystyrene-bound (2.2.2)cryptand is found to be effective in these polymerizations which allow simple recovery and reuse of the catalyst. 

Halides derived from certain heterocyclic aromatic compounds are often quite reactive toward nucleophiles. 2-Chloropyridine, for exfflnple, reacts with sodium methoxide some 230 million times faster than chlorobenzene at 50°C. 

The halogen atom in benz-chloro substituted quinazolines is very stable (as in chlorobenzene), whereas the halogen atoms in positions 2 and 4 show the enhanced reactivity observed with halogen atoms on carbon atoms placed a and y to heterocyclic ring nitrogens. The chlorine atom in position 4 is more reactive than in position 2, and this property has been used to introduce two different substituents in the pyrimidine ring. ... 

Chlorine and iodine can be introduced into aromatic rings by electrophilic substitution reactions, but fluorine is too reactive and only poor yields of monofluoro-aromatic products are obtained by direct fluorinafion. Aromatic rings react with CI2 in the presence of FeCl3 catalyst to yield chlorobenzenes, just as they react with Bi 2 and FeBr3. This kind of reaction is used in the synthesis of numerous pharmaceutical agents, including the antianxiety agent diazepam, marketed as Valium. 

More than twenty years ago, Nesmeyanov s group showed that chlorine can be substituted by a variety of nucleophiles in FeCp(r 6-PhCl)+ [83, 84]. Indeed the chlorine substituent in the chlorobenzene (even) ligand is 1000 times more reactive than when it is located on the cyclopentadienyl (odd) ligand [85]. The FeCp+ is a good withdrawing group which is equivalent to two nitro groups in terms of activation. The reactions proceed under ambient conditions with primary or secondary amines and have been extended to other substituted chloroarene complexes [86, 87] Eq. (22), Table 2. 

From this work a relative reactivity for chlorobenzene to benzene of 0.065 is obtained and this may be compared with a value of 0.34 obtained by Kilpatrick and Meyer163 for bromobenzene at 12.3 °C this is rather a large difference in view of the fact that there is very little ortho sulphonation of either substrate. 

With 77 % aqueous acetic acid, the rates were found to be more affected by added perchloric acid than by sodium perchlorate (but only at higher concentrations than those used by Stanley and Shorter207, which accounts for the failure of these workers to observe acid catalysis, but their observation of kinetic orders in hypochlorous acid of less than one remains unaccounted for). The difference in the effect of the added electrolyte increased with concentration, and the rates of the acid-catalysed reaction reached a maximum in ca. 50 % aqueous acetic acid, passed through a minimum at ca. 90 % aqueous acetic acid and rose very rapidly thereafter. The faster chlorination in 50% acid than in water was, therefore, considered consistent with chlorination by AcOHCl+, which is subject to an increasing solvent effect in the direction of less aqueous media (hence the minimum in 90 % acid), and a third factor operates, viz. that in pure acetic acid the bulk source of chlorine ischlorineacetate rather than HOC1 and causes the rapid rise in rate towards the anhydrous medium. The relative rates of the acid-catalysed (acidity > 0.49 M) chlorination of some aromatics in 76 % aqueous acetic acid at 25 °C were found to be toluene, 69 benzene, 1 chlorobenzene, 0.097 benzoic acid, 0.004. Some of these kinetic observations were confirmed in a study of the chlorination of diphenylmethane in the presence of 0.030 M perchloric acid, second-order rate coefficients were obtained at 25 °C as follows209 0.161 (98 vol. % aqueous acetic acid) ca. 0.078 (75 vol. % acid), and, in the latter solvent in the presence of 0.50 M perchloric acid, diphenylmethane was approximately 30 times more reactive than benzene. 

A p-PhS02 group enhances the electrophilic reactivity of chlorobenzene towards KOH far more than a p-PhSO group, and the p-isomer is much more reactive than the m-isomer in each group. 

TABLE 6. Reactivities of m- and p-sulfur-containing substituted chlorobenzenes with KOH in 2 1 v/v DMSO water (after Reference 36)... 

TABLE 7. Relative reactivities of p-substituted chlorobenzenes with KOH in 70% ethanol-water at 105 °C (after Reference 37)... 

Chlorobenzenes, sulphur-containing, reactivities of 590, 591 Chloropalladiosulphonylation 172 Chromanones, synthesis of 328 Chromatographic methods for detection and determination 111-113, 119-121... 

The order in reactivity in the Y-zeolite catalyzed bromination found is toluene > benzene > fluorobenzene > chlorobenzene > bromobenzene... 

It is noteworthy to point out once more the much higher reactivity of the bromobenzene compared to the chlorobenzene the chlorobenzene affords only 30 % of the phenyl ether after 4 days, whereas the bromobenzene gives already 100 % after only 20 hours. 

By comparison of the hydrolysis rate for the chloro- and bromobenzene catalyzed with cuprous oxide (Fig. 16), it is easy to show that the reactivity of bromobenzene as arylating agent is much higher than the reactivity of chlorobenzene the yields in phenolate is higher than 90 % after half an hour at 230 °C for the bromobenzene whereas the chlorobenzene affords only about 65 % after 15 hours, even at higher temperature (250°C). 

---