Carbon-halogen bonds reactivity order

Similar reactions occur with all aliphatic halides and the rates of substitution are related to the degree of ionic character of the carbon-halogen bond. For preparation purposes, trityl bromide or propargyl bromide are more convenient than allyl bromide. The compounds obtained are listed in Table XI. They were obtained pure and characterized fully. Zr (allyl) 3Br and Zr(allyl)2Br2 are sufficiently soluble in toluene for polymerizations to be initially homogeneous. Their relative reactivities are listed in Table XI. In all cases hydrogen was used to reduce the molecular weight of the polymer formed. In this respect the polymer derived from Zr (allyl )3Br was more readily modified than that from Zr (allyl) 4, but in order to avoid... 

The reactivity order also appears to correlate with the C-X bond energy, inasmuch as the tertiary alkyl halides both are more reactive and have weaker carbon-halogen bonds than either primary or secondary halides (see Table 4-6). In fact, elimination of HX from haloalkenes or haloarenes with relatively strong C-X bonds, such as chloroethene or chlorobenzene, is much less facile than for haloalkanes. Nonetheless, elimination does occur under the right conditions and constitutes one of the most useful general methods for the synthesis of alkynes. For example,... 

Olah and Kuhn S found that fluorochloro-, fluorobromo- and fluoroiodo-alkanes are effective chloro-, bromo- and iodo-aikylating agents, respectively, in Friedel-Crafts alkylations of arenes in the presence of boron halide catalysts (equation 86). Boron trihalides catalyzq reactions of only the C—F bonds, but not of the C—Cl, C—Br or C—I bonds. The order of reactivity of the catalysts was found to be BI3 > BBr3 > BCI3 > BF3, and that of the carbon-halogen bonds C—F > C—Cl > C—Br > C—I. 

Another route to block copolymers in conjunction with conventional radical systems is to use azo initiators bearing reactive carbon—halogen bonds such as (chloromethyl)benzyl, 2-bromoisobutyroyl, and trichloromethyl groups.338,386 This method can afford diblock (B-74 and B-75) and triblock (B-81) copolymers, depending on the mode of termination reactions in the conventional radical polymerizations with the azo compounds. In these cases, the order of... 

As in all Michaelis-Arbuzov and Michaelis-Becker reactions, the usual order of decreasing reactivity at the carbon-halogen bond, I > Br > Cl > F, applies with carbon-fluorine bonds tending to be unreactive, other than in exceptional circumstances. Even for diiodomethane, the most reactive dihalomethane, reactions with trialkyl phosphites can be made to yield esters of (iodomethyl)phosphonic acid (11 R = O-alkyl, R = alkyl, n=, X = I or in the presence of more phosphite ester, the methylenebisphosphonic ester 12... 

The measured half-lives range from 19 sec to 7000 yr, suggesting that structure variation can have significant effects on hydrolysis rates. The reactivity of these chemicals can be rationalized in terms of the limiting mechanisms presented for nucleophilic substitution. It is apparent from the data in Table 2.2 that the fluori-nated aliphatics are much more stable than the chlorinated aliphatics, which in turn are more stable than the brominated aliphatics. This trend in reactivity reflects the strength of the carbon-halogen bond, which follows the order F>Cl>Br, that is broken in the nucleophilic substitution reaction. 

Both parts of the Lapworth mechanism enol formation and enol halogenation are new to us Let s examine them m reverse order We can understand enol halogenation by analogy to halogen addition to alkenes An enol is a very reactive kind of alkene Its carbon-carbon double bond bears an electron releasing hydroxyl group which makes it electron rich and activates it toward attack by electrophiles... 

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