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Halohydrins from Alkenes - Addition of HO-X

Another example of an electrophilic addition is the reaction an alkene with either Br2 or Clin the presence of water to yield a 1,2-halo alcohol, called a halohydrin.
Halohydrins from Alkenes - Addition of HO-X | Chemistry Optional Notes for UPSC

We saw in the previous section that when Br2 reacts with an alkene, the cyclic bromonium ion intermediate reacts with the only nucleophile present, Br ion. If the reaction is carried out in the presence of an additional nucleophile, however, the intermediate bromonium ion can be intercepted by the added nucleophile and diverted to a different product. In the presence of a high concentration of water, for instance, water competes with Br ion as a nucleophile and reacts with the bromonium ion intermediate to yield a bromohydrin. The net effect is addition of HO−Br to the alkene by the pathway shown in Figure 8.3.

Figure 8.3 MECHANISM Bromohydrin formation by reaction of an alkene with Br2 in the presence of water. Water acts as a nucleophile in step 2 to react with the intermediate bromonium ion.
Halohydrins from Alkenes - Addition of HO-X | Chemistry Optional Notes for UPSC

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Which solvent is commonly used in bromohydrin formation reactions?
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In practice, few alkenes are soluble in water, and bromohydrin formation is often carried out in a solvent such as aqueous dimethyl sulfoxide, CH3SOCH3 (DMSO), using a reagent called N-bromosuccinimide (NBS) as a source of Br2. NBS is a stable, easily handled compound that slowly decomposes in water to yield Br2 at a controlled rate. Bromine itself can also be used in the addition reaction, but it is more dangerous and more difficult to handle than NBS.
Halohydrins from Alkenes - Addition of HO-X | Chemistry Optional Notes for UPSC

Notice that the aromatic ring in the above example does not react with Br2, even though it appears to have three carbon–carbon double bonds. Aromatic rings are a good deal more stable and less reactive than might be expected.

There are a number of biological examples of halohydrin formation, particularly in marine organisms. As with halogenation, halohydrin formation is carried out by haloperoxidases. For example:
Halohydrins from Alkenes - Addition of HO-X | Chemistry Optional Notes for UPSC

The document Halohydrins from Alkenes - Addition of HO-X | Chemistry Optional Notes for UPSC is a part of the UPSC Course Chemistry Optional Notes for UPSC.
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FAQs on Halohydrins from Alkenes - Addition of HO-X - Chemistry Optional Notes for UPSC

1. What are halohydrins and how are they formed from alkenes?
Ans. Halohydrins are organic compounds containing both a halogen atom and a hydroxyl group. They are formed from alkenes through the addition of a halogen and a hydroxyl group. This addition reaction occurs when an alkene reacts with a halogen acid, such as HCl or HBr, in the presence of water.
2. What is the purpose of adding HO-X to alkenes?
Ans. The addition of HO-X to alkenes, where X represents a halogen atom, allows for the synthesis of halohydrins. Halohydrins have various applications in organic synthesis and can be used as intermediates for the production of pharmaceuticals, agrochemicals, and other valuable compounds.
3. How does the addition of HO-X to alkenes occur?
Ans. The addition of HO-X to alkenes follows a mechanism called electrophilic addition. The pi bond of the alkene acts as the nucleophile and attacks the electrophilic halogen atom of the HO-X molecule. This leads to the formation of a cyclic intermediate, which is then hydrolyzed by water to yield the halohydrin product.
4. What factors influence the addition reaction of HO-X to alkenes?
Ans. Several factors can influence the addition reaction of HO-X to alkenes. The nature of the alkene, the concentration and temperature of the reaction, the presence of catalysts or solvents, and the reactivity of the specific HO-X molecule all play a role in determining the reaction rate and selectivity.
5. Can the addition of HO-X to alkenes result in the formation of multiple products?
Ans. Yes, the addition of HO-X to alkenes can result in the formation of multiple products. This is because alkenes can have different sites of reactivity, and the addition of HO-X can occur at any of these sites. The regioselectivity of the reaction can be influenced by factors such as the stability of the intermediate and the steric hindrance around the alkene molecule.
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