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Aromatic Nucleophilic Substitution
- 1. Nair Vijayalakshmi MSc (Inorganic Chemistry) Part I Organic Chemistry Aromatic Nucleophilic Substitution
- 2. CONTENT • Aromatic Nucleophilic Substitution • SNAr mechanism • SN1 mechanism • Benzyne mechanism
- 3. Aromatic Nucleophilic Substitution • Under normal conditions, aryl halides do not undergo nucleophilic substitution reactions. They are less reactive towards the substitution reactions by nucleophile due to the following reasons: 1. In case of alkyl halides, the carbon of C-X bond is sp3 hybridised and its bond length of 177pm. In aryl halides, carbon of C-X bond is sp2 hybridised and its bond length of 170pm. Shorter the bond length stronger is the bond and greater energy will be required to break the bond. 2. The lone pair of electrons of halogen atom in aryl halides is in conjugation with π-electrons of the ring. 3. Due to the resonance, the C-X bond in aryl halides possesses double bond character.
- 4. SNAr mechanism • Aryl halides does not undergo this mechanism easily because of the conjugation between lone pair of electrons on Cl and the C-atom in the ring. • But if there is a strong withdrawing group in the ring such as nitro (-NO2) group then it would undergo the reaction readily. • It's important that the withdrawing group must be present either at ortho or para-position. As the resonating structures do not have negative charge at meta-position, hence the presence of withdrawing group on meta-position has no effect on reactivity.
- 5. MECHANISM
- 6. SN1 mechanism • It is very rare mechanism in aromatic compounds and is observed in Benzene diazonium compounds. • As you know, it is a two step mechanism and the rate is independent of the nucleophile.
- 7. MECHANISM
- 9. Benzyne mechanism • It is also known as SNEA mechanism as elimination and addition reaction occurs. • It would not be easy to remove the chloride group from the ring due to conjugation between lone pair of electrons of chloride atom and carbon atom in the ring. • It was possible in SNAr mechanism due to presence of a strong withdrawing group. • So here, the adjacent H-atom in the ring is used for the reaction.
- 10. Here, we are using C14, radioactive isotope of carbon. Two products are produced here, one is directly or ipso substituted product and the other is cine substituted product (direct= on the same position and cine=adjacent position).
- 11. MECHANISM
- 12. Ipso = at the same position Cine= at the adjacent position (2,6) Tele= more than 1 carbon atom far away from the leaving group (3,4,5)
- 13. Reference 1. Organic Chemistry, J. Claydens, N. Greeves, S. Warren and P. Wothers, Oxford University Press. 2. Advanced Organic Chemistry, B.S. Bahl and Arun Bahl, S. Chand and company Ltd. 3. https://nptel.ac.in 4. https://m.youtube.com
- 14. Acknowledgement I would like to express my gratitude to our HOD, Prof.Sandeep Borde and Prof.Jameson Masih for giving me this opportunity. I also thank my friends for their support.