p. 445

1. Chapter 12: Organohalides 12.5 – 12.15 : Substitution and Elimination Reactions 12.4 : The Grignard Reagent 12.1-12.3 : Preparation of Alkyl Halides p. 445

2. Properties of Alkyl Halides Table 12-1, p. 446

3. Properties of Alkyl Halides p. 447

4. Synthesis of alkyl halides : review • Addition of HX to an alkene (section 7.6) p. 227

5. Synthesis of alkyl halides : review • Addition of HX to an alkene (section 7.6) • Obeys Markovnikov’s Rule (section 7.7) • Carbocations that can rearrange, will rearrange (section 7.10) p. 239

6. Synthesis of alkyl halides : review 2. Addition of X2 to an alkene (section 8.2)

7. Synthesis of alkyl halides : review 3. Radical Halogenation (section 6.3)

8. Synthesis of alkyl halides : New • From alkenes • Allylicbromination with N-BromoSuccinimide • From Alcohols • Using strong acid • Via Tosylates • Using SOCl2 and PBr3

9. The Allyl Radical

10. Synthesis of alkyl halides : New • From alkynes • Allylicbromination with N-BromoSuccinimide • From Alcohols • Using strong acid • Via Tosylates • Using SOCl2 and PBr3

11. Synthesis of alkyl halides : New • From alkynes • Allylicbromination with N-BromoSuccinimide • From Alcohols • Using strong acid • Via Tosylates • Using SOCl2 and PBr3

12. Synthesis of alkyl halides : New • From alkynes • Allylicbromination with N-BromoSuccinimide • From Alcohols • Using strong acid • Via Tosylates • Using SOCl2 and PBr3

13. Organometallics

14. The Grignard Reagent

15. The Gilman Reagent

16. The Suzuzi – Miyaura Cross Coupling The Nobel Prize in Chemistry 2010 "for palladium-catalyzed cross couplings in organic synthesis" Richard F. Heck Ei-ichiNegishi Akira Suzuki

17. Substitution and Elimination Reactions

18. Characteristics of the SN2 reaction • Rate equation

19. Characteristics of the SN2 reaction • Rate equation • Mechanism

20. Fig. 12-5, p. 459

21. The Walden Inversion Cycle (1896) (-)-Maleic Acid [a]D = -2.3 (+)-chlorosuccinic acid (+)-Maleic Acid [a]D = +2.3 (-)-chlorosuccinic acid Fig. 12-2, p. 455

22. SN2

23. Characteristics of the SN2 reaction • Rate equation • Mechanism • Molecular factors effecting SN2 reaction rate

24. The Effect of Reactant and Transition Structure Energies on Reaction Rate Fig. 12-6, p. 460

25. Effect of ELECTROPHILIC CARBON on SN2 rate p. 461

26. Effect of ELECTROPHILIC CARBON on SN2 rate Fig. 12-7, p. 461

27. Effect of ELECTROPHILIC CARBON on SN2 rate

28. Effect of LEAVING GROUP on SN2 rate p. 463

29. Effect of LEAVING GROUP on SN2 rate

30. Effect of NUCLEOPHILE on SN2 rate Table 12-2, p. 462

31. Effect of NUCLEOPHILE on SN2 rate

32. Effect of Solvent on SN2 rate

33. Effect of Solvent on SN2 rate

34. Solvent effects on SN2 rate

35. Characteristics of the SN1 reaction • Rate equation

36. Characteristics of the SN1 reaction • Rate equation • 2. Mechanism of SN1 reaction

37. Stereochemical effects of the SN1 mechanism

38. Stereochemical effects of the SN1 mechanism

39. Characteristics of the SN1 reaction • Rate equation • 2. Mechanism of SN1 reaction • 3. Molecular factors effecting SN1 reaction rate

40. Effect of electrophilic carbon on SN1 rate p. 467

41. Effect of electrophilic carbon on SN1 rate:Carbocation Stability

42. Effect of electrophilic carbon on SN1 rate: Resonance in Carbocations Fig. 12-13, p. 471

43. Bond Disassociation Energies and Carbocation Stability p. 472

44. Bond Disassociation Energies and Carbocation Stability <  p. 472

45. Effect of LEAVING GROUP on SN1 rate p. 472

46. Effect of LEAVING GROUP on SN1 rate Effect of LEAVING GROUP on SN2 rate p. 472

47. Effect of Solvent on SN1 rate Fig. 12-15, p. 474

48. Effect of Solvent on SN1 rate p. 474

49. Predict mechanism for the reactions below.

50. Predict mechanism for the reactions below.