ALCOHOL

1. ALCOHOL By PuanAzduwinKhasri 6th NOVEMBER 2012

2. INTRODUCTION

3. Reaction of Alcohol SUBSTITUTION ELIMINATION (DEHYDRATION) OXIDATION Others SULFONATE ESTER ALKYL HALIDE KETONE ALDEHIDE CARBOXILIC ACID ALKENE

4. Nucleophilic substitution of Alcohol An alcohol has a strongly base leaving group (HO-) therefore alcohol cannot undergo a nucleophilic substitution reaction Convert the strongly basic leaving group (OH–) into the good leaving group, H2O (a weaker base):

5. Primary, secondary, and tertiary alcohols all undergo nucleophilic substitution reactions with HI, HBr, and HCl:

6. SN1 REACTION OF ALCOHOL Secondary and tertiary alcohols undergo SN1 reactions with hydrogen halides:

7. Look out for rearrangement product in the SN1 reaction of the secondary or tertiary alcohol:

8. SN2 REACTION OF ALCOHOL Primary alcohols undergo SN2 reactions with hydrogen halides:

9. When HCl is used; SN2 reaction is slower, but the rate can be increased using ZnCl2 as catalyst . ZnCl2functions as a Lewis acid that complexes strongly with the lone-pair electrons on oxygen:

10. CLASS EXERCISE 1 Give the major product of each of the following reactions:

11. Other Methods for Converting Alcohols into Alkyl Halides Utilization of phosphorus tribromide: PYRIDINE Other phosphorus reagents can be used: PBr3, phosphorus tribromide PCl3, phosphorus trichloride PCl5, phosphorus pentachloride POCl3, phosphorus oxychloride

12. Activation by SOCl2 Pyridine is generally used as a solvent and also acts as a base:

14. Summary: Converting of Alcohols to Alkyl Halides Recommended procedures:

15. Converting Alcohols into Sulfonate Esters

16. Several sulfonyl chlorides are available to activate OH groups:

17. ELIMINATION REACTION OF ALCOHOL (DEHYDRATION) • Dehydration of alcohol requires acid catalyst and heat • Dehydration of Secondary and Tertiary Alcohols by an E1 Pathway 17

18. Mechanism of E1 Dehydration of an Alcohol

19. The major product is the most stable alkene product: The most stable alkeneproduct has the most stable transition state

20. The rate of dehydration reflects the ease with which the carbocation is formed:

21. Look out for carbocation rearrangement:

22. Resonance-stabilized oxocarbocation Pinicol Rearrangement Protonate alcohol: Eliminate water: Rearrange carbocation: Deprotonate:

23. Ring Expansion and Contraction Mechanism for this reaction: • Protonate the alcohol. • Eliminate water. • Rearrange carbocation to afford the more stable cyclohexane ring. • Deprotonate.

24. Primary Alcohols Undergo Dehydration by an E2 Pathway

25. A Milder Way to Dehydrate an Alcohol

26. Oxidation of Alcohols Oxidation by chromic acid: Secondary alcohols are oxidized to ketones

27. Primary alcohols are oxidized to aldehydesand eventually carboxylic acids: Mechanism:

28. No water present The oxidation of aldehydes to acids requires the presence of water: In the absence of water, the oxidation stops at the aldehyde: PCC, a methylene chloride–soluble reagent:

29. No hydrogen on this carbon A tertiary alcohol cannot be oxidized and is converted to a stable chromate ester instead: Di-tert-Butyl Chromate

30. ETHER

31. Nucleophilic substitution reaction of Ether Ethers, like alcohols, can be activated by protonation: Ether can undergo nucleophilic substitution with HBr and HI only (HClcannot be used because Cl- too poor nucleophile

32. Ether cleavage: an SN1 reaction: Ether cleavage: an SN2 reaction:

33. Reagents such as SOCl2 and PCl3can activate alcohols but not ethers Ethers are frequently used as solvents because only they react with hydrogen halides

34. Nucleophilic Substitution Reactions of Epoxides Acidic condition; HBr: Aqueous acid:

35. Reaction of an epoxide in different substituent Regioselectivity: Mechanism:

36. Neutral or Basic condition: When a nucleophileattacks an unprotonatedepoxide, the reaction is a pure SN2 reaction: Therefore:

37. Epoxides Are Synthetically Useful Reagents Enantiomers

38. CLASS EXERCISE 2 Give the major product of the following reactions:

39. THE END