Chapter 11. Free Radical Reactions



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hapter 11 Free Radical Reactions A free radical is a species containing one or more unpaired electrons Free radicals are electron-deficient species, but they are usually uncharged, so their chemistry is very different from the chemistry of even-electron electron-deficient species such as carbocations and carbenes The alkyl radical ( R 3 ) is a seven-electron, electron-deficient species The geometry of the alkyl radical is considered to be a shallow pyramid, somewhere between sp 2 and sp 3 hybridization, and the energy required to invert the pyramid is very small In practice, one can usually think of alkyl radicals as if they were sp 2 -hybridized Both alkyl radicals and carbocations are electron-deficient species, and structural features that stabilize carbocations also stabilize radicals Alkyl radicals are stabilized by adjacent lone-pair-bearing heteroatoms and by π bonds, just as carbocations are, and the order of stability of alkyl radicals is 3 > 2 > 1 However, there are two major differences between the energy trends in carbocations and alkyl radicals A atom surrounded by seven electrons is not as electron-deficient as a atom surrounded by six electrons, so alkyl radicals are generally not as high in energy as the corresponding carbocations Thus, the very unstable aryl and 1 alkyl carbocations are almost never seen, whereas aryl and 1 alkyl radicals are reasonably common The amount of extra stabilization that adjacent lone pairs, π bonds, and σ bonds provide to radicals is not as great as that which they provide to carbocations The reason is that the interaction of a filled A or M with an empty A (as in carbocations) puts two electrons in an M of reduced energy, whereas the interaction of a filled A or M with a half-filled A (free radicals) puts two electrons in an M of reduced energy and one electron in an M of increased energy 1

Even though adjacent lone pairs, π bonds, and σ bonds do not stabilize radicals as much as they stabilize carbocations, the cumulative stabilizing effect of several such groups on a radical can be considerable Benzylic radicals (those with the radical on a atom next to a benzene ring, but not in a benzene ring) are particularly low in energy, as the radical center is stabilized by resonance with three π bonds 111 Addition of H to Alkenes The anti-markovnikov addition of H to alkenes was probably the first free-radical addition reaction to be discovered The discovery was inadvertent; around the turn of the twentieth century, scientists studying the regiochemistry of addition of H to alkenes found that the proportion of Markovnikov to anti-markovnikov addition products varied inexplicably from run to run Eventually it was discovered that impurities such as 2 and peroxides greatly increased the amount of anti-markovnikov addition product (See Jones Figure 1123) The results were later explained by a free-radical addition mechanism Thus, 2-methylpropene will react with H in the presence of a peroxide such as t-bu -t-bu to regiospecifically yield the anti- Markvonikov addition product H 2 H R R H 3 H H 2 regiospecific, anti-markovnikov addition The anti-markovnikov regiochemistry derives from the addition of radical to the less substituted atom of the alkene (steric reasons) to give the more stable, more substituted radical (electronic reasons) In a polar, electrophilic addition reaction, the regioselectivity would be 2

such that would add to the more substituted atom of the alkene Mechanism! R R or h! 2 R initiation steps R H R H + H 2 H 2 + H 3 H 3 H 2 propagation steps H H 2 + H 3 H ote that the bromine radical left above can then go back into the reaction and react with another 2-methylpropene molecule The reaction is ended when all of the chain-carrying radicals (those involved in the propagation steps) combine with other radicals in the termination step (for example, below) 2 H H 2 3 H3 H 2 H 3 In contrast to H, the acids Hl and HI do not undergo free-radical addition to alkenes, even in the presence of peroxides or 2 Abstraction of H from Hl is too endothermic, and addition of I to an alkene is too endothermic 112 Free-Radical Polymerization of Alkenes The most important free-radical chain reaction conducted in industry is the free-radical polymerization of ethylene to give polyethylene Industrial processes usually use (t-bu) 2 as the initiator The t-bu radical adds to ethylene to give the beginning of a polymer chain The propagation part has only one step the addition of an alkyl radical at the end of a growing polymer to ethylene to give a new alkyl radical at 3

the end of a longer polymer The termination steps are the usual radical radical combination and disproportionation reactions 113 Free-Radical Substitution of Alkanes Probably the best-known example of a free-radical reaction is the halogenation of alkanes with 2 or BS (-omosuccinimide) This chain reaction is initiated by homolytic cleavage of 2 induced by light or heat The propagation step consists of two atom abstraction reactions 4

When more than one kind of H atom is present, the H atom that is removed is usually the one that will leave behind the lowest energy radical H atoms are never removed from (sp) or (sp 2 ), only from (sp 3 ) Among (sp 3 ) H bonds, it is easiest to remove a H if a heteroatom such as or is attached to the If no such H atom is present, then the H atom that is removed is best allylic or benzylic (the is attached to a = π bond or to a benzene ring) If there are no allylic or benzylic H atoms, then the order of reactivity of H atoms is 3 > 2 > 1 Free-radical halogenation is most commonly applied to allylic or benzylic halogenation because the radicals formed at these positions are most stable ote that alkenes can react with 2 by either an electrophilic addition reaction, to give 1,2-dibromoalkanes, or by a free-radical substitution reaction, giving 3-bromoalkenes The former pathway predominates in the dark, whereas the latter pathway predominates in the presence of strong light 2 2 h! dominates in the dominates in strong dark light BS (-bromosuccinimide) is often used as the source in freeradical brominations This is to keep the concentration of bromine low and hence reduce competition by electrophilic addition of 2 to give 1,2-dibromoalkane In these reactions using BS in l 4, it is thought that 2 is the actual halogenating agent + BS l 4 ; heat or h! 5

2 is generated as follows (i) Homolytic cleavage of the - bond of BS generates a atom, which abstracts an allylic hydrogen from the alkene (cyclopentene) heat or h! + BS H H + (ii) The H thus formed reacts with BS to produce a 2 molecule H (iii) This 2 molecule reacts with the allylic radical formed earlier and a new bromine atom is produced that can begin the cycle anew + f course, in allylic halogenation, transposition of the double bond can easily occur For example, in 4,4-dimethylcyclopentene Elemental chlorine can be used in free-radical halogenation reactions, too, but these reactions are less easily controlled, because the l radical is more reactive than the radical and hence less selective The reagents t-bul and S 2 l 2 are used as alternative chlorinating agents The F radical is so reactive, and the reaction F F + H 6

H F + F is so exothermic, that free-radical fluorinations result in violent and uncontrollable exotherms (explosions) At the other extreme, free-radical iodinations of alkanes do not work well at all, as the H abstraction step is too endothermic 7

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