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CARBOCATION REARRANGEMENTS & FREE-RADICAL ADDITION

CARBOCATION REARRANGEMENTS & FREE-RADICAL ADDITION . Carbocation Rearrangements. Oleh Siti Nursiami (4301410002) Ana Yustika (4301410005) Fransisca Ditawati N.P (43014100xx) Lutfia Rizqy Amalia (43014100xx). Free-Radical Addition.

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CARBOCATION REARRANGEMENTS & FREE-RADICAL ADDITION

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  1. CARBOCATION REARRANGEMENTS & FREE-RADICAL ADDITION Carbocation Rearrangements Oleh SitiNursiami (4301410002) Ana Yustika (4301410005) FransiscaDitawati N.P (43014100xx) LutfiaRizqyAmalia (43014100xx) Free-Radical Addition

  2. CARBOCATION REARRANGEMENTS IN HYDROGEN HALIDE ADDITION TO ALKENES Our belief that carbocations are intermediates in the addition of hydrogen halides to alkenes is strengthened by the observation that rearrangements sometimes occur. For example, the reaction of hydrogen chloride with 3-methyl-1-butene is expected to produce 2-chloro-3-methylbutane. Instead, a mixture of 2-chloro-3-methylbutane and 2- chloro-2-methylbutane results.

  3. HCl 0oC 3-Methyl-1-butene Cl Cl CH2=CHCH(CH3)2 CH3CHCH(CH3)2+ CH3CH2C(CH3)2 2-Chloro-3-methylbutane (40%) 2-Chloro-2-methylbutane (60%) Addition begins in the usual way, by protonation of the double bond to give, in this case, a secondary carbocation. This carbocation can be captured by chloride to give 2-chloro-3-methylbutane (40%) or it can rearrange by way of a hydride shift to give a tertiary carbocation. The tertiary carbocation reacts with chloride ion to give 2-chloro-2-methylbutane (60%).

  4. Hydride shift + + CH3CH—C(CH3)2 CH3CH—C(CH3)2 │ │ H H 1,2-Dimethylpropyl cation (secondary) 1,1-Dimethylpropyl cation (tertiary) The similar yields of the two alkyl chloride products indicate that the rate of attack by chloride on the secondary carbocation and the rate of rearrangement must be verysimilar.

  5. FREE-RADICAL ADDITION OF HYDROGEN BROMIDE TO ALKENES For a long time the regioselectivity of addition of hydrogen bromide to alkenes was unpredictable. Sometimes addition occurred according to Markovnikov’s rule, but at other times, seemingly under the same conditions, the opposite regioselectivity(anti- Markovnikovaddition) was observed. In 1929, Morris S. Kharasch and his students at the University of Chicago began a systematic investigation of this puzzle.

  6. After hundreds of experiments, Kharasch concluded that anti-Markovnikov addition occurred when peroxides, that is, organic compounds of the type ROOR, were present in the reaction mixture. He and his colleagues found, for example, that carefully purified 1-butene reacted with hydrogen bromide to give only 2-bromobutane—the product expected on the basis of Markovnikov’s rule. CH2=CHCH2CH3+ HBr CH3CHCH2CH3 │ Br no peroxides Hydrogen bromide 1-Butene 2-Bromobutane (only product; 90% yield)

  7. On the other hand, when the same reaction was performed in the presence of an added peroxide, only 1-bromobutane was formed. CH2=CHCH2CH3+ HBr BrCH2CH2CH2CH3 peroxides Hydrogen bromide 1-Butene 1-Bromobutane (only product; 95% yield)

  8. Kharaschtermed this phenomenon the peroxide effect and demonstrated that it could occur even if peroxides were not deliberately added to the reaction mixture. Unless alkenes are protected from atmospheric oxygen, they become contaminated with small amounts of alkyl hydroperoxides, compounds of the type ROOH. These alkyl hydroperoxides act in the same way as deliberately added peroxides to promote addition in the direction opposite to that predicted by Markovnikov’s rule.

  9. Kharaschproposed that hydrogen bromide can add to alkenes by two different mechanisms, both of which are, in modern terminology, regiospecific. The first mechanism is the one we discussed in the preceding section, electrophilic addition, and fol lows Markovnikov’s rule. It is the mechanism followed when care is taken to ensure that no peroxides are present. The second mechanism is the free-radical chain process.

  10. Peroxides are initiators; they are not incorporated into the product but act as a source of radicals necessary to get the chain reaction started. The oxygen–oxygen bond of a peroxide is relatively weak, and the free-radical addition of hydrogen bromide to alkenes begins when a peroxide molecule undergoes homolytic cleavage to two alkoxy radicals. This is depicted in step 1, bromine atom is generated in step 2 when one of these alkoxy radicals abstracts a proton from hydrogen bromide. Once a bromine atom becomes available, the propagation phase of the chain reaction begins. In the propagation phase as shown in step 3, a bromine atom adds to the alkene in the direction that produces the more stable alkyl radical.

  11. ROOR light or heat 1-Butene The overall reaction: CH3CH2CH=CH2 + HBr CH3CH2CH2CH2Br 1-Bromobutane Hydrogen bromide

  12. The mechanism • Initiation step 1: Dissociation of a peroxide into two alkoxy radicals: RO : OR RO + OR . . . . . . . .

  13. Step 2: Hydrogen atom abstraction from hydrogen bromide by an alkoxy radical: RO. H : Br RO H + Br

  14. (b) Chain propagation Step 3: Addition of a bromine atom to the alkene: CH3CH2CH=CH2 Br CH3CH2CH2—CH2 :Br:

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