5 Must Know Facts For Your Next Test

1. Nitric acid is commonly used in the synthesis of explosives, fertilizers, and various organic compounds through its ability to introduce nitro groups.
2. The reaction of nitric acid with sulfuric acid creates the nitronium ion (NO₂⁺), which is the active electrophile in nitration reactions.
3. Nitric acid can react with metals and nonmetals, producing nitrogen oxides and other products, making it important in both organic synthesis and industrial applications.
4. In electrophilic aromatic substitution, the orientation of the nitro group can affect further substitution reactions due to its deactivating nature compared to other groups.
5. Nitric acid is highly corrosive and must be handled with care; it can cause severe burns and damage to living tissues.

Review Questions

• How does nitric acid function as an electrophilic aromatic substitution agent, and what role does it play in nitration?
  • Nitric acid acts as a nitrating agent by generating the nitronium ion (NO₂⁺) when mixed with sulfuric acid. This ion serves as the electrophile in electrophilic aromatic substitution reactions. When an aromatic compound reacts with this electrophile, it substitutes a hydrogen atom with a nitro group (-NO₂), thereby modifying the compound's properties and reactivity.
• Compare the roles of nitric acid and sulfuric acid in the nitration process. Why is sulfuric acid necessary when using nitric acid?
  • In the nitration process, nitric acid provides the nitro group while sulfuric acid acts as a catalyst that helps generate the nitronium ion (NO₂⁺). Sulfuric acid's strong dehydrating properties increase the efficiency of the reaction by removing water produced during the process, thus driving the equilibrium towards product formation. This collaboration enhances the overall reaction rate and yield of nitro-substituted products.
• Evaluate how introducing a nitro group via nitric acid affects the reactivity of aromatic compounds in subsequent reactions.
  • Introducing a nitro group via nitric acid significantly alters the reactivity of aromatic compounds. Nitro groups are electron-withdrawing, making the ring less reactive towards further electrophilic substitution due to decreased electron density. This means that while initial nitration may enhance certain reactivities, subsequent reactions often require different conditions or catalysts. Understanding these changes is crucial for effectively planning synthetic pathways in organic chemistry.

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