Reactions at the Allylic Position - Online Tutor, Practice Problems & Exam Prep

The allylic position in organic chemistry refers to the carbon atom adjacent to a double bond. This position is significant because it exhibits unique reactivity due to the stability provided by resonance. For example, in a molecule with a double bond between two carbons (C=C), the carbon atoms directly attached to these double-bonded carbons are in the allylic position. This position is more reactive in certain reactions, such as SN1, E1, and radical reactions, compared to non-allylic positions.

Allylic carbocations are more stable than alkyl carbocations due to resonance stabilization. In an allylic carbocation, the positive charge can be delocalized over multiple atoms through resonance structures. This delocalization distributes the charge more evenly, reducing the energy of the carbocation and increasing its stability. In contrast, alkyl carbocations are primarily stabilized by hyperconjugation, which is less effective than resonance.

Allylic anions are more acidic than alkyl anions because the conjugate base of an allylic anion is resonance-stabilized. When a proton is removed from the allylic position, the resulting negative charge can be delocalized over multiple atoms through resonance. This stabilization lowers the pKa of the allylic proton, making it more acidic compared to an alkyl proton, which lacks such resonance stabilization.

Allylic halogenation is a reaction where a halogen replaces an allylic hydrogen atom. This process is facilitated by radical initiators such as heat, UV light, or peroxides. For example, using N-bromosuccinimide (NBS) in the presence of UV light can selectively brominate the allylic position. The reaction involves the formation of a radical intermediate, which allows the halogen to replace the allylic hydrogen, resulting in an allylic halide.

Manganese(IV) oxide (MnO₂) is used as an oxidizing agent in allylic oxidation to selectively oxidize allylic alcohols to carbonyl compounds. This reaction occurs without affecting the alkene double bond. For instance, an allylic alcohol can be converted to an allylic ketone or aldehyde using MnO₂ in a methylene chloride solvent. This selective oxidation is useful in organic synthesis for transforming specific functional groups while preserving others.