Show the complete mechanism for anisole chlorination at the para position, using arrows, formal charges, and electron pairs.

Transcribed Image Text:

This image depicts a chemical reaction used in organic chemistry, specifically an electrophilic aromatic substitution reaction. **Reactants:** - **Anisole** (\(C_7H_8O\), typically represented as \(CH_3OC_6H_5\)): The structure shown is anisole, where a methoxy group (\(CH_3O-\)) is attached to a benzene ring. - **Chlorine (\(Cl_2\)):** This is used as the chlorinating agent. - **Aluminum Chloride (\(AlCl_3\)):** A catalyst that facilitates the reaction. **Product:** - The product depicted is para-chloroanisole (\(C_7H_7ClO\)), where a chlorine (\(Cl\)) atom has substituted a hydrogen atom on the benzene ring para to the methoxy group. The structure retains the methoxy group on the benzene ring. **Reaction Mechanism:** - The presence of \(AlCl_3\) as a Lewis acid increases the electrophilic nature of \(Cl_2\), allowing the chlorine to substitute a hydrogen atom on the benzene ring. - The methoxy group is an ortho/para-director and activates the benzene ring towards electrophilic substitution, hence the para substitution is preferred. This example demonstrates the use of Friedel-Crafts halogenation in producing chloro-substituted aromatic compounds.