Organic Chemistry

1. Organic Chemistry William H. Brown Christopher S. Foote Brent L. Iverson

2. Alcoholsand Thiols Chapter 10

3. Structure - Alcohols • The functional group of an alcohol is an -OH group bonded to an sp3 hybridized carbon • bond angles about the hydroxyl oxygen atom are approximately 109.5° • Oxygen is sp3 hybridized • two sp3 hybrid orbitals form sigma bonds to carbon and hydrogen • the remaining two sp3 hybrid orbitals each contain an unshared pair of electrons

4. Nomenclature-Alcohols • IUPAC names • the parent chain is the longest chain that contains the OH group • number the parent chain to give the OH group the lowest possible number • change the suffix -e to -ol • Common names • name the alkyl group bonded to oxygen followed by the word alcohol

5. Nomenclature-Alcohols • Examples

6. C H C H C H C H C H C H C H C H 3 2 2 2 2 2 H O O H O H O H H O H O O H 1,2-Ethanediol 1,2-Propanediol 1,2,3-Propanetriol (Ethylene glycol) (Propylene glycol) (Glycerol, Glycerine) Nomenclature of Alcohols • Compounds containing more than one OH group are named diols, triols, etc.

7. Nomenclature of Alcohols • Unsaturated alcohols • show the double bond by changing the infix from -an- to -en- • show the the OH group by the suffix -ol • number the chain to give OH the lower number

8. Physical Properties • Alcohols are polar compounds • they interact with themselves and with other polar compounds by dipole-dipole interactions • Dipole-dipole interaction:the attraction between the positive end of one dipole and the negative end of another

9. Physical Properties • Hydrogen bonding:when the positive end of one dipole is an H bonded to F, O, or N (atoms of high electronegativity) and the other end is F, O, or N • the strength of hydrogen bonding in water is approximately 21 kJ (5 kcal)/mol • hydrogen bonds are considerably weaker than covalent bonds • nonetheless, they can have a significant effect on physical properties

10. Hydrogen Bonding

11. C H C H O H C H O C H 3 2 3 3 bp 78° C Physical Properties • Ethanol and dimethyl ether are constitutional isomers. • Their boiling points are dramatically different • ethanol forms intermolecular hydrogen bonds which increase attractive forces between its molecules resulting in a higher boiling point • there is no comparable attractive force between molecules of dimethyl ether Dimethyl ether Ethanol bp -24°C

12. Physical Properties • In relation to alkanes of comparable size and molecular weight, alcohols • have higher boiling points • are more soluble in water • The presence of additional -OH groups in a molecule further increases solubility in water and boiling point

13. Physical Properties

14. Acidity of Alcohols • In dilute aqueous solution, alcohols are weakly acidic

15. Acidity of Alcohols

16. Acidity of Alcohols • Acidity depends primarily on the degree of stabilization and solvation of the alkoxide ion • the negatively charged oxygens of methanol and ethanol are about as accessible as hydroxide ion for solvation; these alcohol are about as acidic as water • as the bulk of the alkyl group increases, the ability of water to solvate the alkoxide decreases, the acidity of the alcohol decreases, and the basicity of the alkoxide ion increases

17. Reaction with Metals • Alcohols react with Li, Na, K, and other active metals to liberate hydrogen gas and form metal alkoxides • Alcohols are also converted to metal alkoxides by reaction with bases stronger than the alkoxide ion • one such base is sodium hydride

18. Reaction with HX • 3° alcohols react very rapidly with HCl, HBr, and HI • low-molecular-weight 1° and 2° alcohols are unreactive under these conditions • 1° and 2° alcohols require concentrated HBr and HI to form alkyl bromides and iodides

19. Reaction with HX • with HBr and HI, 2° alcohols generally give some rearranged product • 1° alcohols with extensive -branching give large amounts of rearranged product

20. Reaction with HX • Based on • the relative ease of reaction of alcohols with HX (3° > 2° > 1°) and • the occurrence of rearrangements, • Chemists propose that reaction of 2° and 3° alcohols with HX • occurs by an SN1 mechanism, and • involves a carbocation intermediate

21. Reaction with HX - SN1 Step 1: proton transfer to the OH group gives an oxonium ion Step 2: loss of H2O gives a carbocation intermediate

22. Reaction with HX - SN1 Step 3: reaction of the carbocation intermediate (an electrophile) with halide ion (a nucleophile) gives the product

23. Reaction with HX - SN2 • 1° alcohols react with HX by an SN2 mechanism Step 1: rapid and reversible proton transfer Step 2: displacement of HOH by halide ion

24. Reaction with HX • For 1° alcohols with extensive -branching • SN1 is not possible because this pathway would require a 1° carbocation • SN2 is not possible because of steric hindrance created by the -branching • These alcohols react by a concerted loss of HOH and migration of an alkyl group

25. Reaction with HX • Step 1: proton transfer gives an oxonium ion • Step 2: concerted elimination of HOH and migration of a methyl group gives a 3° carbocation

26. Reaction with HX Step 3: reaction of the carbocation intermediate (an electrophile) with halide ion (a nucleophile) gives the product

27. Reaction with PBr3 • An alternative method for the synthesis of 1° and 2° bromoalkanes is reaction of an alcohol with phosphorus tribromide • this method gives less rearrangement than with HBr

28. Reaction with PBr3 Step 1: formation of a protonated dibromophosphite converts H2O, a poor leaving group, to a good leaving group Step 2: displacement by bromide ion gives the alkyl bromide

29. Reaction with SOCl2 • Thionyl chloride is the most widely used reagent for the conversion of 1° and 2° alcohols to alkyl chlorides • a base, most commonly pyridine or triethylamine, is added to catalyze the reaction and to neutralize the HCl

30. Reaction with SOCl2 • Reaction of an alcohol with SOCl2 in the presence of a 3° amine is stereoselective • it occurs with inversion of configuration

31. Reaction with SOCl2 Step 1: formation of an alkyl chlorosulfite Step 2: nucleophilic displacement of this leaving group by chloride ion gives the chloroalkane

32. - R - S - C l R - S - O H R - S - O A sulfonate anion A sulfonyl A sulfonic acid (a very weak base and chloride (a very strong acid) stable anion; a very good leaving group Alkyl Sulfonates • Sulfonyl chlorides are derived from sulfonic acids • sulfonic acids, like sulfuric acid, are strong acids O O O O O O

33. Alkyl Sulfonates • A commonly used sulfonyl chloride is p-toluenesulfonyl chloride (Ts-Cl)

34. Alkyl Sulfonates • Another commonly used sulfonyl chloride is methanesulfonyl chloride (Ms-Cl)

35. Alkyl Sulfonates • Sulfonate anions are very weak bases (the conjugate base of a strong acid) and are very good leaving groups for SN2 reactions • Conversion of an alcohol to a sulfonate ester converts HOH, a very poor leaving group, into a sulfonic ester, a very good leaving group

36. Alkyl Sulfonates • This two-step procedure converts (S)-2-octanol to (R)-2-octyl acetate Step 1: formation of a p-toluenesulfonate (Ts) ester Step 2: nucleophilic displacement of tosylate

37. Dehydration of ROH • An alcohol can be converted to an alkene by acid-catalyzed dehydration (a type of -elimination) • 1° alcohols must be heated at high temperature in the presence of an acid catalyst, such as H2SO4 or H3PO4 • 2° alcohols undergo dehydration at somewhat lower temperatures • 3° alcohols often require temperatures at or slightly above room temperature

38. H S O 2 4 C H C H O H C H = C H + H O 3 2 2 2 2 O H H S O 2 4 + H O 2 140° C C H C H 3 3 H S O 2 4 C H C O H H O C H C = C H 2 3 3 2 50° C C H 3 2-Methyl-2-propanol 2-Methylpropene ( tert- Butyl alcohol) (Isobutylene) Dehydration of ROH 180°C Cyclohexanol Cyclohexene +

39. Dehydration of ROH • where isomeric alkenes are possible, the alkene having the greater number of substituents on the double bond (the more stable alkene) usually predominates (Zaitsev rule)

40. H S O 2 4 O H 3,3-Dimethyl- 2,3-Dimethyl- 2,3-Dimethyl- 2-butanol 2-butene 1-butene (80%) (20%) Dehydration of ROH • Dehydration of 1° and 2° alcohols is often accompanied by rearrangement • acid-catalyzed dehydration of 1-butanol gives a mixture of three alkenes + 140 - 170°C

41. Dehydration of ROH • Based on evidence of • ease of dehydration (3° > 2° > 1°) • prevalence of rearrangements • Chemists propose a three-step mechanism for the dehydration of 2° and 3° alcohols • because this mechanism involves formation of a carbocation intermediate in the rate-determining step, it is classified as E1

42. Dehydration of ROH Step 1: proton transfer to the -OH group gives an oxonium ion Step 2: loss of H2O gives a carbocation intermediate

43. Dehydration of ROH Step 3: proton transfer from a carbon adjacent to the positively charged carbon to water; the sigma electrons of the C-H bond become the pi electrons of the carbon-carbon double bond

44. Dehydration of ROH • 1° alcohols with little -branching give terminal alkenes and rearranged alkenes • Step 1: proton transfer to OH gives an oxonium ion • Step 2: loss of H from the -carbon and H2O from the -carbon gives the terminal alkene

45. Dehydration of ROH Step 3: shift of a hydride ion from -carbon and loss of H2O from the -carbon gives a carbocation Step 4: proton transfer to solvent gives the alkene

46. Dehydration of ROH • Dehydration with rearrangement occurs by a carbocation rearrangement

47. Dehydration of ROH • Acid-catalyzed alcohol dehydration and alkene hydration are competing processes • Principle of microscopic reversibility:the sequence of transition states and reactive intermediates in the mechanism of a reversible reaction must be the same, but in reverse order, for the reverse reaction as for the forward reaction

48. Pinacol Rearrangement • The products of acid-catalyzed dehydration of a glycol are different from those of alcohols

49. Pinacol Rearrangement Step 1: proton transfer to OH gives an oxonium ion Step 2: loss of water gives a carbocation intermediate

50. Pinacol Rearrangement Step 3: a 1,2- shift of methyl gives a more stable carbocation Step 4: proton transfer to solvent completes the reaction