Kelas XII... Part.3 BENZENA DAN TURUNANNYA
Summary
TLDRThis educational video explains the four main substitution reactions of benzene: halogenation, nitration, sulfonation, and alkylation. It discusses how benzene reacts with halogens, nitric acid, sulfuric acid, and alkyl halides to form various derivatives like chlorobenzene, nitrobenzene, benzenesulfonic acid, and toluene. The speaker provides clear explanations of the mechanisms involved, emphasizing the substitution of hydrogen atoms in the benzene ring by other functional groups. These reactions are fundamental to understanding organic chemistry and the production of benzene derivatives used in various industries.
Takeaways
- đ Benzene is more likely to undergo substitution reactions than addition reactions.
- đ The halogenation of benzene involves its reaction with halogen gas (e.g., chlorine) in the presence of iron(III) chloride (FeClâ) as a catalyst.
- đ The product of halogenation is chlorobenzene (CâHâ Cl), where a hydrogen atom is replaced by a chlorine atom.
- đ Nitration involves reacting benzene with nitric acid (HNOâ) in the presence of sulfuric acid (HâSOâ) as a catalyst.
- đ The result of nitration is nitrobenzene (CâHâ NOâ), where a hydrogen atom is replaced by a nitro group (NOâ).
- đ In the sulfonation reaction, benzene reacts with sulfuric acid (HâSOâ), which both serves as a reagent and catalyst.
- đ The product of sulfonation is benzenesulfonic acid (CâHâ SOâH), where a hydrogen atom is replaced by a sulfonic acid group (SOâH).
- đ Alkylation, or Friedel-Crafts alkylation, occurs when benzene reacts with alkyl halides (e.g., methyl chloride, CHâCl) using aluminum chloride (AlClâ) as a catalyst.
- đ The product of alkylation is toluene (CâHâ CHâ), where a hydrogen atom is replaced by a methyl group (CHâ).
- đ The four main reactions of benzene are halogenation, nitration, sulfonation, and alkylation, each with distinct catalysts and products.
- đ The key substitution in each reaction is the replacement of a hydrogen atom on the benzene ring by another functional group (halogen, nitro, sulfonic, or alkyl group).
Q & A
What are the four main reactions that benzene undergoes?
-The four main reactions that benzene undergoes are: Halogenation, Nitration, Sulfonation, and Alkylation.
What is the role of a catalyst in the reactions of benzene?
-A catalyst is used to speed up the reactions without being consumed. In the case of benzene, catalysts like FeClâ, HâSOâ, and AlClâ are used to facilitate the reactions.
What happens during the Halogenation reaction of benzene?
-During Halogenation, benzene reacts with halogen gases (like Clâ) in the presence of FeClâ, replacing one hydrogen atom with a halogen atom, such as chlorine, to form chlorobenzene.
How does the Nitration reaction of benzene occur?
-In Nitration, benzene reacts with nitric acid (HNOâ) in the presence of sulfuric acid (HâSOâ). The hydrogen atom in benzene is replaced by a nitro group (NOâ), resulting in nitrobenzene.
What is the product of the Sulfonation reaction of benzene?
-The product of the Sulfonation reaction is benzene sulfonic acid, where a hydrogen atom is replaced by a sulfonic acid group (SOâH) in the benzene ring.
In the Alkylation reaction, what happens to benzene?
-In Alkylation, benzene reacts with an alkyl halide (such as methyl chloride) in the presence of AlClâ. The hydrogen atom on the benzene ring is replaced by an alkyl group, such as a methyl group, producing toluene.
Why is FeClâ used in the Halogenation reaction of benzene?
-FeClâ acts as a catalyst in the Halogenation reaction, helping to facilitate the substitution of a hydrogen atom by a halogen atom, such as chlorine, in the benzene ring.
What is the general mechanism behind the substitution reactions of benzene?
-In substitution reactions, the hydrogen atom in the benzene ring is replaced by another atom or group (like Cl, NOâ, SOâH, or alkyl groups) without disrupting the overall structure of the benzene ring.
What is the difference between Halogenation and Alkylation of benzene?
-In Halogenation, benzene reacts with halogen gases to form halobenzenes (like chlorobenzene), while in Alkylation, benzene reacts with alkyl halides to form alkylated benzenes (like toluene). The key difference lies in the substituent group: halogens in Halogenation and alkyl groups in Alkylation.
What is the result of Nitration in terms of the functional group introduced to benzene?
-The result of Nitration is the introduction of a nitro group (NOâ) into the benzene ring, replacing one of its hydrogen atoms. This creates nitrobenzene.
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