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Halogenation of Benzene

Halogenation is an example of electrophillic aromatic substitution. In electrophilic aromatic substitutions, a benzene is attacked by an electrophile which results in substition of hydrogens. However, halogens are not electrophillic enough to break the aromaticity of benzenes, which require a catalyst to activate.

Activation of Halogen

  • (where X= Br or Cl, we will discuss further in detail later why other members of the halogen family Flourine and Iodine are not used in halogenation of benzenes)
  • Other Aromatic Substitutions | Chemistry Optional Notes for UPSCHence, Halogen needs the help and aid of Lewis Acidic Catalysts to activate it to become a very strong electrophile. Examples of these activated halogens are Ferric Hallides (FeX3) Aluminum Halides (AlX3) where X= Br or Cl. In the following examples, the halogen we will look at is Bromine. In the example of bromine, in order to make bromine electrophillic enough to react with benzene, we use the aid of an aluminum halide such as aluminum bromide.
    Other Aromatic Substitutions | Chemistry Optional Notes for UPSC
  • With aluminum bromide as a Lewis acid, we can mix Br2 with AlBr3 to give us Br+. The presence of Br+ is a much better electrophile than Br2 alone. Bromination is acheived with the help of AlBr3 (Lewis acid catalysts) as it polarizes the Br-Br bond. The polarization causes polarization causes the bromine atoms within the Br-Br bond to become more electrophillic. The presence of Br+ compared to Br2 alone is a much better electrophille that can then react with benzene.
    Other Aromatic Substitutions | Chemistry Optional Notes for UPSC
  • As the bromine has now become more electrophillic after activation of a catalyst, an electrophillic attack by the benzene occurs at the terminal bromine of Br-Br-AlBr3. This allows the other bromine atom to leave with the AlBr3 as a good leaving group, AlBr4-.
    Other Aromatic Substitutions | Chemistry Optional Notes for UPSC
  • After the electrophilic attack of bromide to the benzene, the hydrogen on the same carbon as bromine substitutes the carbocation in which resulted from the attack. Hence it being an electrophilic aromatic SUBSTITUTION. Since the by-product aluminum tetrabromide is a strong nucleophile, it pulls of a proton from the Hydrogen on the same carbon as bromine.
    Other Aromatic Substitutions | Chemistry Optional Notes for UPSC
  • In the end, AlBr3 was not consumed by the reaction and is regenerated. It serves as our catalyst in the halogenation of benzenes.

Question for Other Aromatic Substitutions
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Which halogenation reaction is the most exothermic?
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Dissociation Energies of Halogens and its Effect on Halogenation of Benzenes

  • The electrophillic bromination of benzenes is an exothermic reaction. Considering the exothermic rates of aromatic halogenation decreasing down the periodic table in the Halogen family. Flourination is the most exothermic and Iodination would be the least. 
  • Being so exothermic, a reaction of flourine with benzene is explosive! For iodine, electrophillic iodination is generally endothermic, hence a reaction is often not possible. Similar to bromide, chlorination would require the aid of an activating presence such as Alumnium Chloride or Ferric Chloride. The mechanism of this reaction is the same as with Bromination of benzene.
  • Nitration and sulfonation of benzene are two examples of electrophilic aromatic substitution. The nitronium ion (NO2+) and sulfur trioxide (SO3) are the electrophiles and individually react with benzene to give nitrobenzene and benzenesulfonic acid respectively.

Question for Other Aromatic Substitutions
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What is the purpose of sulfuric acid in the nitration of benzene?
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Nitration of Benzene

The source of the nitronium ion is through the protonation of nitric acid by sulfuric acid, which causes the loss of a water molecule and formation of a nitronium ion.

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

Sulfuric Acid Activation of Nitric Acid

  • The first step in the nitration of benzene is to activate HNO3with sulfuric acid to produce a stronger electrophile, the nitronium ion.

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

  • Because the nitronium ion is a good electrophile, it is attacked by benzene to produce Nitrobenzene.

Mechanism

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

(Resonance forms of the intermediate can be seen in the generalized electrophilic aromatic substitution)

Sulfonation of Benzene

Sulfonation is a reversible reaction that produces benzenesulfonic acid by adding sulfur trioxide and fuming sulfuric acid. The reaction is reversed by adding hot aqueous acid to benzenesulfonic acid to produce benzene.

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

Mechanism

To produce benzenesulfonic acid from benzene, fuming sulfuric acid and sulfur trioxide are added. Fuming sulfuric acid, also refered to as oleum, is a concentrated solution of dissolved sulfur trioxide in sulfuric acid. The sulfur in sulfur trioxide is electrophilic because the oxygens pull electrons away from it because oxygen is very electronegative. The benzene attacks the sulfur (and subsequent proton transfers occur) to produce benzenesulfonic acid.

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

Reverse Sulfonation

Sulfonation of benzene is a reversible reaction. Sulfur trioxide readily reacts with water to produce sulfuric acid and heat. Therefore, by adding heat to benzenesulfonic acid in diluted aqueous sulfuric acid the reaction is reversed.

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC

Further Applications of Nitration and Sulfonation

  • Nitration is used to add nitrogen to a benzene ring, which can be used further in substitution reactions. The nitro group acts as a ring deactivator. Having nitrogen present in a ring is very useful because it can be used as a directing group as well as a masked amino group. The products of aromatic nitrations are very important intermediates in industrial chemistry.
  • Because sulfonation is a reversible reaction, it can also be used in further substitution reactions in the form of a directing blocking group because it can be easily removed. The sulfonic group blocks the carbon from being attacked by other substituents and after the reaction is completed it can be removed by reverse sulfonation. Benzenesulfonic acids are also used in the synthesis of detergents, dyes, and sulfa drugs. Bezenesulfonyl Chloride is a precursor to sulfonamides, which are used in chemotherapy.

Solved Examples

Example 1: What is/are the required reagent(s)for the following reaction:

Other Aromatic Substitutions | Chemistry Optional Notes for UPSC
Ans:
SO3 and H2SO4 (fuming)

Example 2: Why is it important that the nitration of benzene by nitric acid occurs in sulfuric acid?
Ans: 
Sulfuric acid is needed in order for a good electrophile to form. Sulfuric acid protonates nitric acid to form the nitronium ion (water molecule is lost). The nitronium ion is a very good electrophile and is open to attack by benzene. Without sulfuric acid the reaction would not occur.

The document Other Aromatic Substitutions | Chemistry Optional Notes for UPSC is a part of the UPSC Course Chemistry Optional Notes for UPSC.
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FAQs on Other Aromatic Substitutions - Chemistry Optional Notes for UPSC

1. What is halogenation of benzene?
Ans. Halogenation of benzene is a chemical reaction where a halogen atom (such as chlorine or bromine) is substituted for one or more hydrogen atoms in a benzene ring. This reaction is typically carried out in the presence of a Lewis acid catalyst, such as iron or aluminum chloride.
2. How does the dissociation energy of halogens affect the halogenation of benzenes?
Ans. The dissociation energy of a halogen refers to the energy required to break the bond between two atoms of the same halogen. Higher dissociation energies indicate stronger halogen atoms. In the context of halogenation of benzenes, halogens with higher dissociation energies (such as chlorine) are more reactive and therefore more likely to undergo substitution reactions with benzene. On the other hand, halogens with lower dissociation energies (such as iodine) are less reactive and may require harsher reaction conditions to facilitate the halogenation process.
3. What is nitration of benzene?
Ans. Nitration of benzene is a chemical process in which a nitro group (-NO2) is introduced into a benzene ring. This reaction is typically carried out by treating benzene with a mixture of concentrated nitric acid and sulfuric acid as a catalyst. Nitration is an important reaction in organic chemistry as it allows the synthesis of various nitroaromatic compounds, which have applications in the production of dyes, pharmaceuticals, and explosives.
4. What is sulfonation of benzene?
Ans. Sulfonation of benzene is a chemical reaction in which a sulfonic acid group (-SO3H) is introduced into a benzene ring. This reaction is typically achieved by treating benzene with concentrated sulfuric acid. Sulfonation is an important reaction in organic chemistry as it allows the synthesis of various sulfonated aromatic compounds, which have applications in the production of detergents, pharmaceuticals, and dyes.
5. What are further applications of nitration and sulfonation?
Ans. The nitration and sulfonation reactions have numerous applications in organic chemistry. Some of the further applications include: - Nitration and sulfonation are key steps in the synthesis of various pharmaceuticals, including antibiotics, analgesics, and antihypertensive drugs. - Nitration and sulfonation reactions are used in the production of dyes and pigments, allowing for the introduction of specific functional groups that impart color to the final product. - Nitration and sulfonation reactions are employed in the synthesis of explosives, such as trinitrotoluene (TNT) and nitroglycerin. - Sulfonated aromatic compounds find applications in the production of detergents and surfactants, which are used in cleaning products. - Nitration and sulfonation reactions are important in the synthesis of various intermediates for further chemical transformations, allowing for the introduction of specific functional groups and modifications to aromatic compounds.
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