Free-radical reaction mechanism

However, polypropylene has no functional groups present for the silane to react with. Therefore, vinyl silanes are used. In this case, the vinyl group must react with the polymer molecule via a free radical reaction mechanism. Free radicals can be generated through heat, shear, or with a catalyst, such as an organic peroxide. There are various examples of two-component silane-peroxide systems. In 1986, Union Carbide introduced a product called UCARSIL PC-1 A/ PC-IB. This system was a complex mixture of organosilane and peroxide. The... 

The second mechanism is the one followed when addition occurs opposite to Markovmkov s rule Unlike electrophilic addition via a carbocation intermediate this alternative mechanism is a chain reaction involving free radical intermediates It is pre sented m Figure 6 7... 

Among other possible reactions, these free radicals can initiate ordinary free-radical polymerization. The Ziegler-Natta systems are thus seen to encompass several mechanisms for the initiation of polymerization. Neither ionic nor free-radical mechanisms account for stereoregularity, however, so we must look further for the mechanism whereby the Ziegler-Natta systems produce this interesting effect. 

In the radiant section, the hydrocarbon mixture undergoes reactions involving free radicals (51). These mechanisms have been generalized to include the molecular reactions shown below ... 

This reaction proceeds through a chain mechanism. Free-radical additions to 1-butene, as in the case of HBr, RSH, and H2S to other olefins (19—21), can be expected to yield terminally substituted derivatives. Some polymerization reactions are also free-radical reactions. 

Vitamin E actually consists of a family of compounds, the most active of which is a-tocopherol. The mechanism of the vitamin s action is not completely certain, but it seems likely that it might undergo hydrogen atom transfer reactions with free radicals to give a stable radical (see also Chapter 17, Problem 7). 

CHsSNa in an aprotic solvent or by BusSnH. Both reactions have free-radical mechanisms.Tertiary nitro compounds can be reduced to RH by NaHTe. The compound Bu3SnH also reduces isocyanides (RNC, prepared from RNH2 by formylation followed by 17-33) to a reaction that can also be... 

Aromatic compounds can also be arylated by aryllead tricarboxylates. Best yields ( 70-85%) are obtained when the substrate contains alkyl groups an electrophilic mechanism is likely. Phenols are phenylated ortho to the OH group (and enols are a phenylated) by triphenylbismuth dichloride or by certain other Bi(V) reagents. O-Phenylation is a possible side reaction. As with the aryllead tricarboxylate reactions, a free-radical mechanism is unlikely. ... 

In contrast to chain transfer, termination reactions destroy free radicals. Two mechanisms are considered. Termination by combination produces a single molecule of dead polymer ... 

The chain mechanism is complicated when two hydrocarbons are oxidized simultaneously. Russell and Williamson [1,2] performed the first experiments on the co-oxidation of hydrocarbons with ethers. The theory of these reactions is close to that for the reaction of free radical copolymerization [3] and was developed by several researchers [4-9], When one hydrocarbon R H is oxidized in the liquid phase at a sufficiently high dioxygen pressure chain propagation is limited only by one reaction, namely, R OO + R H. For the co-oxidation of two hydrocarbons R1 and R2H, four propagation reactions are important, viz,... 

In addition to the classification of inhibitors according to their mechanisms of the action on oxidation, they can be classified into consumable and long-lived inhibitors. A consumable inhibitor is irreversibly consumed in its reactions with free radicals (R or RCV) or hydroperoxide. The stoichiometric coefficient of inhibition of such inhibitors is typically equal to one or two per inhibitory functional group. However, in some systems (for example RH 02 InH), an inhibitor can act cyclically so that, getting repeatedly regenerated, the... 

The mechanism of this reaction involves free radical oxidation of butane to butane hydroperoxide, which decomposes to acetaldehyde via P scissions. It is similar to the oxidation of cyclohexane to cyclohexanol and cyclohexanone, which will be discussed in Chapter 11, Section 4. 

Upon irradiation, polyisobutylene and its copolymers tend to degrade. There are a large number of studies determining the nature of the process and mechanisms, and it was established that it involves formation and reaction of free radicals. The radical concentration increases linearly with a dose up to 100 Mrad (1,000 kGy). ... 

However, it was subsequently shown9 that these observations could be more satisfactorily accounted for by the occurrence of free radical chain reactions. The free radicals might arise from ionic or excited species. The radiation chemistry of liquid water was claimed to be explicable10 in terms of the reactions of the hydrogen atom and the hydroxyl free radical. Ionic mechanisms consequently fell into disrepute, but it is interesting that in recent years ionic processes have been recognised as of increasing importance. The wheel has indeed turned full circle ... 

As mentioned above, the secondary reaction in the system is caused by a new reaction of free radical interaction (produced in the elementary dissociation of the radical initiator) with the initiator. In this case, one more active intermediate particle (free radical), not observed at usual peroxide decomposition, is generated in the system. Owing to formation of this active site, conjugated reaction proceeds by the radical-chain mechanism. Thus products formed may be analogous to those obtained at usual initiator decomposition, or different products may be formed—this circumstance is of no importance for detection of induced decomposition. 

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