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Ch. 12 - 1

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Title: Ch. 12 - 1


1
Chapter 12
  • Alcohols from
  • Carbonyl Compounds
  • Oxidation-Reduction Organometallic
  • Compounds

2
  1. Structure of the Carbonyl Group
  • Carbonyl compounds

3
  • Structure
  • Carbonyl carbon sp2 hybridized
  • Planar structure

4
  • Polarity and resonance structure

5
1A. Reactions of Carbonyl Compoundswith
Nucleophiles
  • One of the most important reactions of carbonyl
    compounds is nucleophilic addition to the
    carbonyl group.

6
  • Two important nucleophiles
  • Hydride ions (from NaBH4 and LiAlH4).
  • Carbanions (from RLi and RMgX).
  • Another important reaction

7
  1. Oxidation-Reduction Reactions inOrganic Chemistry
  • Reduction of an organic molecule usually
    corresponds to increasing its hydrogen content or
    decreasing its oxygen content.

oxygen content decreases
hydrogen content increases
carboxylic acid
aldehyde
8
  • The opposite reaction of reduction is oxidation.
    Increasing the oxygen content of on organic
    molecule or decreasing its hydrogen content is
    oxidation.

lowest oxidation state
highest oxidation state other than CO2
9
  • Oxidation of an organic compound may be more
    broadly defined as a reaction that increases its
    content of any element more electronegative than
    carbon.

10
2A. Oxidation States in Organic Chemistry
  • Rules
  • For each CH (or CM) bond ? -1
  • For each CC bond ? 0
  • For each CZ bond ? 1
  • (where M electropositive element and is
    equivalent to H, e.g. Li, K, etc. Z
    electronegative heteroatom, e.g. OR, SR, PR2,
    halogen, etc.).
  • The oxidation state of each carbon is based on
    the number of bonds it forms to atoms more (or
    less) electronegative than carbon.

11
  • Examples

Bonds to C
4 to H (- 1) x 4 - 4
Total - 4
Oxidation state of C - 4 Or as indicated in
class, the more electronegative atom controls
the shared electrons. Here C controls 8 es.
12
  • Examples

Bonds to C
3 to H - 3
1 to O 1
Total - 2
Oxidation state of C - 2 Here C controls 6 es
compared to its 4 valence es.
13
  • Examples

Bonds to C
2 to H - 2
2 to O 2
Total 0
Oxidation state of C 0 Here C controls 4 es
which equals its of valence es.
14
  • Examples

Bonds to C
1 to H - 1
3 to O 3
Total 2
Oxidation state of C 2 Here C controls 2 es
compared to its 4 valence es.
15
  • Overall order of oxidation states of C

oxidation state
lowest oxidation state of carbon
highest oxidation state of carbon
16
  1. Alcohols by Reduction of Carbonyl Compounds

(1o alcohol)
17
3A. Lithium Aluminum Hydride
  • LiAlH4 (LAH)
  • Not only nucleophilic, but also very basic.
  • React violently with H2O or acidic protons (e.g.
    ROH).
  • Usually reactions run in ethereal solvents (e.g.
    dry Et2O or THF).
  • Reduces all carbonyl groups and requires two
    separate steps.

18
  • Examples

19
  • Mechanism

Esters are reduced to 1o alcohols
20
3B. Sodium Borohydride
  • NaBH4
  • less reactive and less basic than LiAlH4.
  • can use protic solvent (e.g. ROH) separate
    acidification is not needed.
  • reduces only more reactive carbonyl groups (i.e.
    aldehydes and ketones) but not reactive towards
    esters or carboxylic acids.

21
  • Examples

22
  • Mechanism

Aldehydes are reduced to 1 alcohols ketones
are reduced to 2 alcohols
23
3C. Overall Summary of LiAlH4 and NaBH4
Reactivity
reduced by LiAlH4
reduced by NaBH4
ease of reduction
24
  1. Oxidation of Alcohols

4A. Oxidation of Primary Alcohols to Aldehydes
  • The oxidation of aldehydes to carboxylic acids in
    aqueous solutions is easier than oxidation of 1o
    alcohols to aldehydes.
  • Therefore, it is difficult to stop the oxidation
    of a 1o alcohol to the aldehyde stage unless
    specialized reagents are used.

25
  • PCC oxidation (mild oxidant)

Reagent
26
  • PCC oxidation

1o
2o
3o
27
4B. Oxidation of Primary Alcohols toCarboxylic
Acids
  • Chromic acid (H2CrO4) usually prepared by

Jones reagent
28
  • Jones oxidation
  • Reagent CrO3 H2SO4
  • A Cr(VI) oxidant

29
4D. Mechanism of Chromate Oxidations
Formation of the Chromate Ester intermediate
30
  • The oxidation step

31
4E. A Chemical Test for Primary andSecondary
Alcohols
32
4F. Spectroscopic Evidence for Alcohols
  • Alcohols give rise to broad O-H stretching
    absorptions from 3200 to 3600 cm-1 in IR spectra.
  • The alcohol hydroxyl hydrogen typically produces
    a broad 1H NMR signal of variable chemical shift
    which can be eliminated by exchange with
    deuterium from D2O.
  • Hydrogen atoms on the carbon of a 1o or 2o
    alcohol produce a signal in the 1H NMR spectrum
    between d 3.3 and d 4.0 ppm that integrates for 2
    and 1 hydrogens, respectively.
  • The 13C NMR spectrum of an alcohol shows a signal
    between d 50 and d 90 ppm for the alcohol carbon.

33
  1. Organometallic Compounds
  • Compounds that contain carbon-metal bonds are
    called organometallic compounds.

34
  1. Preparation of Organolithium Organomagnesium
    Compounds

6A. Organolithium Compounds
  • Preparation of organolithium compounds
  • Order of reactivity of RX
  • RI gt RBr gt RCl

35
  • Example

36
6B. Grignard Reagents
  • Preparation of organomagnesium compounds
    (Grignard reagents).
  • Order of reactivity of RX
  • RI gt RBr gt RCl

37
  • Example

38
  1. Reactions of Organolithium andOrganomagnesium
    Compounds

7A. Reactions with Compounds Con-taining Acidic
Hydrogen Atoms
  • Grignard reagents and organolithium compounds are
    very strong bases.

39
  • Examples
  • As base

40
  • Examples
  • As base

A good method for the preparation of
alkynylmagnesium halides
41
7B. Reactions of Grignard Reagentswith Epoxides
(Oxiranes)
  • Grignard reagents react as nucleophiles with
    epoxides (oxiranes), providing convenient
    synthesis of alcohols.

42
  • Proceeds via an SN2 reaction

43
  • Also work for substituted epoxides
  • (attacks the least substituted side).

44
7C. Reactions of Grignard Reagentswith Carbonyl
Compounds
45
  • Mechanism

46
  1. Alcohols from Grignard Reagents

47
  • R, R H (formaldehyde)
  • Yields a 1o alcohol.

48
  • R alkyl, R H (higher aldehydes)
  • Yields a 2o alcohol.

49
  • R, R alkyl (ketone)
  • Yields a 3o alcohol.

50
  • Reaction with esters
  • Yields a 3o alcohol

51
  • Mechanism

52
  • Examples (note two separate steps)

53
  • Examples

54
  • Examples

55
  • Examples (reacts twice with an ester)

56
8A. How to Plan a Grignard Synthesis
  • Synthesis of

57
  • Method 1
  • Retrosynthetic analysis
  • Synthesis

58
  • Method 2
  • Retrosynthetic analysis
  • Synthesis

59
  • Method 3
  • Retrosynthetic analysis
  • Synthesis

60
8B. Restrictions on the Use ofGrignard Reagents
  • Grignard reagents are useful nucleophiles but
    they are also very strong bases.
  • It is not possible to prepare a Grignard reagent
    from a compound that contains any hydrogen more
    acidic than the hydrogen atoms of an alkane or
    alkene.

61
  • A Grignard reagent cannot be prepared from a
    compound containing an OH group, an NH group,
    an SH group, a CO2H group, or an SO3H group.
  • Since Grignard reagents are powerful
    nucleophiles, we cannot prepare a Grignard
    reagent from any organic halide that contains a
    carbonyl, epoxy, nitro, or cyano (CN) group.

62
  • Grignard reagents cannot be prepared in the
    presence of the following groups because they
    will react with them

63
8C. The Use of Lithium Reagents
  • Organolithium reagents have the advantage of
    being somewhat more reactive than Grignard
    reagents although they are more difficult to
    prepare and handle

64
8D. The Use of Sodium Alkynides
  • Preparation of sodium alkynides
  • Reaction via ketones (or aldehydes).

65
  1. Protecting Groups

66
  • Retrosynthetic analysis
  • However

67
  • Need to protect the OH group first

68
  • Synthesis

69
? END OF CHAPTER 12 ?
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