MS 913 - Benzene EAS Reactions, EDG/EWG, and ortho/meta/para Directors

MS 913 - Benzene EAS Reactions, EDG/EWG, and ortho/meta/para Directors

Textbook and Chapter: Carey and Giuliano 8th Ed. (2010), Chapter 12

Keywords: EAS mechanism, EDG and EWG, Friedel-Crafts

Description: Covers electrophilic aromatic substitution (EAS) reactions in detail.

It includes many, many resonance exercises that show why:

  • Electron donating groups (EDG) are ortho-para directors
  • Electron withdrawing groups (EWG) are meta-directors
  • Pyrrole undergoes EAS at C-2 and not C-3
  • Pyridine undergoes EAS at C-3 and not C-2 or C-4
  • Naphthalene undergoes EAS at C-1 and not C-2

Total Problems: 11

  1. Problem # 587

    Use curved arrows to draw a mechanism for the generic electrophilic aromatic substitution (EAS) reaction below.

  2. Problem # 596

    Indicate the eletrophile formed by each set of reagents/conditions below.

  3. Problem # 595
     

    Phenol can be prepared from benzene and hydrogen peroxide in the presence of a really strong acid. Propose a mechanism for this reaction.

  4. Problem # 588

    Let's draw resonance forms to see why some groups are EDG or EWG. (I've started you off)

    Where are the positive or negative charges placed in EDG/EWG? (ortho/meta/para) Why would this affect EAS reactions?

    Note: EDG = electron donating group, EWG = electron withdrawing group

  5. Problem # 589

     -OR is an EDG and an ortho-para director. Let's draw an EAS reaction's cyclohexadienyl cation intermediates to demonstrate why this is true. I've started you off.

    What's good about ortho/para? What's bad about meta?

  6. Problem # 590

    -NO2 is an EWG and a meta director. Let's draw an EAS reaction's cyclohexadienyl cation intermediates to demonstrate why this is true. I've started you off.

    What's good about meta? What's bad about ortho/para?

  7. Problem # 591

    Pyrrole undergoes eletrophilic aromatic substitution at C-2. Let's compare the resonance forms of EAS carbocation intermediates to see why this is the case. What do you think? Why C-2 and not C-3?

  8. Problem # 592

    Naphthalene undergoes eletrophilic substitution at C-1.

    Why is this the case, even though substitution at C-2 gives more resonance forms?

  9. Problem # 593

    a) Rationalize the relative stabilities of the cation species below.

     

    b) Pyridine undergoes eletrophilic substitution at C-3. Let's compare the resonance forms of EAS carbocation intermediates to see why this is the case. Consider part a) in your explanation.

  10. Problem # 594
     

    A chemist tried to prepare compound A from benzene via Friedel-Crafts alkylation and instead produced compound B.

    Why did this happen? How could the chemist prepare compound A?

  11. Problem # 722

    Show how to prepare vinyl benzene from benzene.