11.11 The Birch Reduction

1. 11.11The Birch Reduction Dr. Wolf's CHM 201 & 202

2. H H H H H H H H H H H H H H Birch Reduction of Benzene Product is non-conjugated diene. Reaction stops here. There is no further reduction. Reaction is not hydrogenation. H2 is not involved in any way. Na, NH3 CH3OH (80%) Dr. Wolf's CHM 201 & 202

3. H H H H H H • + Na+ • Na •• H H H H – H H Mechanism of the Birch Reduction (Figure 11.8) Step 1: Electron transfer from sodium + Dr. Wolf's CHM 201 & 202

4. H • OCH3 • •• Mechanism of the Birch Reduction (Figure 11.8) Step 2: Proton transfer from methanol H H H • •• H H – H Dr. Wolf's CHM 201 & 202

5. H •• • • OCH3 OCH3 • • •• •• Mechanism of the Birch Reduction (Figure 11.8) Step 2: Proton transfer from methanol H H H H H H • • •• H H H H – H H H – Dr. Wolf's CHM 201 & 202

6. H H H • + • Na H H H H Mechanism of the Birch Reduction (Figure 11.8) Step 3: Electron transfer from sodium Dr. Wolf's CHM 201 & 202

7. H H H • + • Na H H H H Mechanism of the Birch Reduction (Figure 11.8) Step 3: Electron transfer from sodium H – H H •• + Na+ H H H H Dr. Wolf's CHM 201 & 202

8. •• • OCH3 • H Mechanism of the Birch Reduction (Figure 11.8) Step 4: Proton transfer from methanol H – H H •• H H H H Dr. Wolf's CHM 201 & 202

9. •• • OCH3 – •• • • OCH3 • •• H H H H H H H H H Mechanism of the Birch Reduction (Figure 11.8) Step 4: Proton transfer from methanol H – H H •• H H H H Dr. Wolf's CHM 201 & 202

10. H H H H H H H H C(CH3)3 H C(CH3)3 H H H Birch Reduction of an Alkylbenzene Na, NH3 If an alkyl group is present on the ring, it ends up asa substituent on the double bond. CH3OH (86%) Dr. Wolf's CHM 201 & 202

11. 1. Reactions involving the ring a) Reduction Catalytic hydrogenation (Section 11.4) Birch reduction (Section 11.11) b) Electrophilic aromatic substitution (Chapter 12) c) Nucleophilic aromatic substitution (Chapter 23) 2. The ring as a substituent (Sections 11.12-11.17) Dr. Wolf's CHM 201 & 202

12. 11.12Free-Radical Halogenationof Alkylbenzenes Dr. Wolf's CHM 201 & 202

13. C C C C • • The Benzene Ring as a Substituent benzylic carbon is analogous to allylic carbon allylic radical benzylic radical Dr. Wolf's CHM 201 & 202

14. Recall: Bond-dissociation energy for C—H bond is equal to DH° for: The more stable the free radical R•, the weaker the bond, and the smaller the bond-dissociation energy. + R—H R• •H and is about 400 kJ/mol for alkanes. Dr. Wolf's CHM 201 & 202

15. H H H C • H2C CH C H H H H • H C C H H Bond-dissociation energies of propene and toluene 368 kJ/mol H2C CH Low BDEs indicate allyl and benzyl radical are more stable than simple alkyl radicals. -H• 356 kJ/mol -H• Dr. Wolf's CHM 201 & 202

16. C Resonance in Benzyl Radical H H • unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H H H H Dr. Wolf's CHM 201 & 202

17. H H C H H • H H H Resonance in Benzyl Radical unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it Dr. Wolf's CHM 201 & 202

18. H H C H H • H H H Resonance in Benzyl Radical unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it Dr. Wolf's CHM 201 & 202

19. C Resonance in Benzyl Radical H H unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H • H H H Dr. Wolf's CHM 201 & 202

20. CH3 CH2Cl Free-radical chlorination of toluene industrial process highly regioselective for benzylic position Cl2 lightorheat Toluene Benzyl chloride Dr. Wolf's CHM 201 & 202

21. CHCl2 CCl3 Free-radical chlorination of toluene Similarly, dichlorination and trichlorination areselective for the benzylic carbon. Furtherchlorination gives: (Dichloromethyl)benzene (Trichloromethyl)benzene Dr. Wolf's CHM 201 & 202

22. CH2Br CH3 CCl4, 80°C light NO2 Benzylic Bromination is used in the laboratory to introduce a halogen at the benzylic position + Br2 + HBr NO2 p-Nitrotoluene p-Nitrobenzyl bromide (71%) Dr. Wolf's CHM 201 & 202

23. CH2CH3 CHCH3 O O NBr NH O O N-Bromosuccinimide (NBS) Br is a convenient reagent for benzylic bromination CCl4 + + benzoyl peroxide, heat (87%) Dr. Wolf's CHM 201 & 202

24. 11.13Oxidation of Alkylbenzenes Dr. Wolf's CHM 201 & 202

25. CH3 Na2Cr2O7 O H2SO4 CH2R COH H2O heat CHR2 Site of Oxidation is Benzylic Carbon or or Dr. Wolf's CHM 201 & 202

26. O COH CH3 Na2Cr2O7 H2SO4 H2O heat NO2 Example NO2 p-Nitrotoluene p-Nitrobenzoicacid (82-86%) Dr. Wolf's CHM 201 & 202

27. O COH CH(CH3)2 Na2Cr2O7 H2SO4 H2O heat CH3 COH O Example (45%) Dr. Wolf's CHM 201 & 202

28. 11.14 SN1 Reactions of Benzylic Halides Dr. Wolf's CHM 201 & 202

29. CH3 CH3 Cl Cl CH3 C C CH3 CH3 What about SN1? Relative solvolysis rates in aqueous acetone tertiary benzylic carbocation is formedmore rapidly than tertiary carbocation;therefore, more stable 600 1 Dr. Wolf's CHM 201 & 202

30. CH3 CH3 + + CH3 CH3 What about SN1? Relative rates of formation: CH3 C C more stable less stable Dr. Wolf's CHM 201 & 202

31. C C C C + + Compare. benzylic carbon is analogous to allylic carbon allylic carbocation benzylic carbocation Dr. Wolf's CHM 201 & 202

32. C Resonance in Benzyl Cation H H + unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H H H H Dr. Wolf's CHM 201 & 202

33. C Resonance in Benzyl Cation H H unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H + H H H Dr. Wolf's CHM 201 & 202

34. C Resonance in Benzyl Cation H H unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H + H H H Dr. Wolf's CHM 201 & 202

35. C Resonance in Benzyl Cation H H unpaired electron is delocalized between benzylic carbon and the ring carbons that are ortho and para to it H H + H H H Dr. Wolf's CHM 201 & 202

36. CH3 Cl C CH3 CH3 OCH2CH3 C CH3 Solvolysis CH3CH2OH (87%) Dr. Wolf's CHM 201 & 202

37. 11.15SN2 Reactions of Benzylic Halides Dr. Wolf's CHM 201 & 202

38. CH2Cl O2N O NaOCCH3 O CH2OCCH3 O2N Primary Benzylic Halides Mechanism is SN2 acetic acid (78-82%) Dr. Wolf's CHM 201 & 202

39. 11.16Preparation of Alkenylbenzenes • dehydrogenation • dehydration • dehydrohalogenation Dr. Wolf's CHM 201 & 202

40. CH2CH3 CH CH2 Dehydrogenation • industrial preparation of styrene 630°C ZnO + H2 Dr. Wolf's CHM 201 & 202

41. Cl Cl CH CHCH3 CH2 OH Acid-Catalyzed Dehydration of Benzylic Alcohols KHSO4 heat + H2O (80-82%) Dr. Wolf's CHM 201 & 202

42. Cl Cl CH CHCH3 CH2 OH Cl CHCH3 + Acid-Catalyzed Dehydration of Benzylic Alcohols KHSO4 heat (80-82%) Dr. Wolf's CHM 201 & 202

43. CH2CHCH3 H3C Br CH H3C CHCH3 Dehydrohalogenation NaOCH2CH3 ethanol, 50°C (99%) Dr. Wolf's CHM 201 & 202

44. 11.17Addition Reactions of Alkenylbenzenes • hydrogenation • halogenation • addition of hydrogen halides Dr. Wolf's CHM 201 & 202

45. CH3 CH3 C CHCH2CH3 CHCH3 H2 Pt Br Br Hydrogenation (92%) Dr. Wolf's CHM 201 & 202

46. CH CH2 Halogenation Br2 CH CH2 Br Br (82%) Dr. Wolf's CHM 201 & 202

47. Cl HCl Addition of Hydrogen Halides (75-84%) Dr. Wolf's CHM 201 & 202

48. Cl HCl Addition of Hydrogen Halides + via benzylic carbocation Dr. Wolf's CHM 201 & 202

49. CH CH2CH2Br CH2 Free-Radical Addition of HBr HBr peroxides Dr. Wolf's CHM 201 & 202

50. CH CH2CH2Br CH2 Free-Radical Addition of HBr HBr peroxides CH CH2Br • via benzylic radical Dr. Wolf's CHM 201 & 202