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Organic Chemistry

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Prob 21.21 Which ring in each compound undergoes electrophilic aromatic substitution more readily? Draw the product of nitration of each compound. – PowerPoint PPT presentation

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Title: Organic Chemistry


1
Organic Chemistry
  • William H. Brown Christopher S. Foote

2
Aromatics II
Chapter 21
  • Chapter 20

3
Reactions of Benzene
  • The most characteristic reaction of aromatic
    compounds is substitution at a ring carbon

4
Reactions of Benzene
5
Electrophilic Aromatic Sub
  • Electrophilic aromatic substitution a reaction
    in which a hydrogen atom of an aromatic ring is
    replaced by an electrophile
  • We study
  • several common types of electrophiles
  • how each is generated
  • the mechanism by which each replaces hydrogen

6
Chlorination
  • Step 1 formation of a chloronium ion

7
Chlorination
  • Step 2 attack of the chloronium ion on the
    aromatic ring
  • Step 3 proton transfer regenerates the aromatic
    character of the ring

8
EAS General Mechanism
  • A general mechanism
  • General question what is the electrophile and
    how is it generated?

9
Nitration
  • The electrophile is NO2, generated in this way

10
Nitration
  • Step 1 attack of the nitronium ion (an
    electrophile) on the aromatic ring (a
    nucleophile)
  • Step 2 proton transfer regenerates the aromatic
    ring

11
Nitration
  • A particular value of nitration is that the nitro
    group can be reduced to a 1 amino group

12
Sulfonation
  • Carried out using concentrated sulfuric acid
    containing dissolved sulfur trioxide

13
Friedel-Crafts Alkylation
  • Friedel-Crafts alkylation forms a new C-C bond
    between an aromatic ring and an alkyl group

14
Friedel-Crafts Alkylation
  • Step 1 formation of an alkyl cation as an ion
    pair
  • Step 2 attack of the alkyl cation on the
    aromatic ring
  • Step 3 proton transfer regenerates the aromatic
    ring

15
Friedel-Crafts Alkylation
  • There are two major limitations on Friedel-Crafts
    alkylations
  • 1. carbocation rearrangements are common

16
Friedel-Crafts Alkylation
  • the isobutyl chloride/AlCl3 complex rearranges to
    the tert-butyl cation/AlCl4- ion pair, which is
    the electrophile

17
Friedel-Crafts Alkylation
  • 2. F-C alkylation fails on benzene rings bearing
    one or more of these strongly electron-withdrawing
    groups

18
Friedel-Crafts Acylation
  • Friedel-Crafts acylation forms a new C-C bond
    between a benzene ring and an acyl group

19
Friedel-Crafts Acylation
  • The electrophile is an acylium ion

20
Friedel-Crafts Acylation
  • an acylium ion is a resonance hybrid of two major
    contributing structures
  • F-C acylations are free of a major limitation of
    F-C alkylations acylium ions do not rearrange

21
Friedel-Crafts Acylation
  • A special value of F-C acylations is preparation
    of unrearranged alkylbenzenes

22
Other Aromatic Alkylations
  • Carbocations are generated by
  • treatment of an alkene with a protic acid, most
    commonly H2SO4, H3PO4, or HF/BF3

23
Other Aromatic Alkylations
  • by treating an alkene with a Lewis acid
  • and by treating an alcohol with H2SO4 or H3PO4

24
Di- and Polysubstitution
  • Existing groups on a benzene ring influence
    further substitution in both orientation and rate
  • Orientation
  • certain substituents direct preferentially to
    ortho para positions others direct
    preferentially to meta positions
  • substituents are classified as either
  • ortho-para directing or meta directing

25
Di- and Polysubstitution
  • Rate
  • certain substituents cause the rate of a second
    substitution to be greater than that for benzene
    itself others cause the rate to be lower
  • substituents are classified as activating or
    deactivating toward further substitution

26
Di- and Polysubstitution
  • -OCH3 is ortho-para directing

27
Di- and Polysubstitution
  • -NO2 is meta directing

28
Di- and Polysubstitution
29
Di- and Polysubstitution
  • From the information in Table 21.1, we can make
    these generalizations
  • alkyl, phenyl, and all other groups in which the
    atom bonded to the ring has an unshared pair of
    electrons are ortho-para directing. All other
    groups are meta directing
  • all ortho-para directing groups except the
    halogens are activating toward further
    substitution. The halogens are weakly deactivating

30
Di- and Polysubstitution
  • the order of steps is important

31
Theory of Directing Effects
  • The rate of EAS is limited by the slowest step in
    the reaction
  • For almost every EAS, the rate-determining step
    is attack of E on the aromatic ring to give a
    resonance-stabilized cation intermediate
  • The more stable this cation intermediate, the
    faster the rate-determining step and the faster
    the overall reaction

32
Theory of Directing Effects
  • For ortho-para directors, ortho-para attack forms
    a more stable cation than meta attack
  • ortho-para products are formed faster than meta
    products
  • For meta directors, meta attack forms a more
    stable cation than ortho-para attack
  • meta products are formed faster than ortho-para
    products

33
Theory of Directing Effects
  • -OCH3 assume meta attack

34
Theory of Directing Effects
  • -OCH3 assume ortho-para attack

35
Theory of Directing Effects
  • -NO2 assume meta attack

36
Theory of Directing Effects
  • -NO2 assume ortho-para attack

37
Activating-Deactivating
  • Any resonance effect, such as that of -NH2, -OH,
    and -OR, that delocalizes the positive charge on
    the cation intermediate lowers the activation
    energy for its formation, and has an activating
    effect toward further EAS
  • Any resonance or inductive effect, such as that
    of -NO2, -CN, -CO, or -SO3H, that decreases
    electron density on the ring deactivates the ring
    toward further EAS

38
Activating-Deactivating
  • Any inductive effect, such as that of -CH3 or
    other alkyl group, that releases electron density
    toward the ring activates the ring toward further
    EAS
  • Any inductive effect, such as that of -halogen,
    -NR3, -CCl3, or -CF3, that decreases electron
    density on the ring deactivates the ring toward
    further EAS

39
Halogens
  • for the halogens, the inductive and resonance
    effects run counter to each other, but the former
    is somewhat stronger
  • the net effect is that halogens are deactivating
    but ortho-para directing

40
Nucleophilic Aromatic Sub.
  • Aryl halides do not undergo nucleophilic
    substitution by either SN1 or SN2 pathways
  • They do undergo nucleophilic substitutions, but
    by mechanisms quite different from those of
    nucleophilic aliphatic substitution
  • Nucleophilic aromatic substitutions are far less
    common than electrophilic aromatic substitutions

41
Benzyne Intermediates
  • When heated under pressure with aqueous NaOH,
    chlorobenzene is converted to sodium phenoxide.
    Neutralization with HCl gives phenol.

42
Benzyne Intermediates
  • the same reaction with 2-chlorotoluene gives a
    mixture of ortho- and meta-cresol
  • the same type of reaction can be brought about
    using of sodium amide in liquid ammonia

43
Benzyne Intermediates
  • ?-elimination of HX gives a benzyne intermediate,
    that then adds the nucleophile to give products

44
Nu Addition-Elimination
  • when an aryl halide contains electron-withdrawing
    NO2 groups ortho and/or para to X, nucleophilic
    aromatic substitution takes place readily
  • neutralization with HCl gives the phenol

45
Meisenheimer Complex
  • reaction involves a Meisenheimer complex
    intermediate

46
Prob 21.7
  • Write a mechanism for each reaction.

47
Prob 21.8
  • Offer an explanation for the preferential
    nitration of pyridine in the 3 position rather
    than the 2 position.

48
Prob 21.9
  • Offer an explanation for the preferential
    nitration of pyrrole in the 2 position rather
    than in the 3 position.

49
Prob 21.15
  • Predict the major product(s) from treatment of
    each compound with HNO3/H2SO4.

50
Prob 21.16
  • Account for the fact that N-phenylacetamide is
    less reactive toward electrophilic aromatic
    substitution than aniline.

51
Prob 21.17
  • Propose an explanation for the fact that the
    trifluoromethyl group is meta directing.

52
Prob 21.19
  • Arrange the compounds in each set in order of
    decreasing reactivity toward electrophilic
    aromatic substitution.

53
Prob 21.19 (contd)
  • Arrange the compounds in each set in order of
    decreasing reactivity toward electrophilic
    aromatic substitution.

54
Prob 21.20
  • Draw a structural formula for the major product
    of nitration of each compound.

55
Prob 21.21
  • Which ring in each compound undergoes
    electrophilic aromatic substitution more readily?
    Draw the product of nitration of each compound.

56
Prob 21.22
  • Propose a mechanism for the formation of
    bisphenol A.

57
Prob 21.23
  • Propose a mechanism for the formation of BHT.

58
Prob 21.24
  • Propose a mechanism for the formation of DDT.

59
Prob 21.27
  • Propose a mechanism for this reaction.

60
Prob 21.28
  • Account for the regioselectivity of the
    nitration in Step 1, and propose a mechanism for
    Step 2.

61
Prob 21.29
  • Propose a mechanism for the displacement of
    chlorine by (1) the NH2 group of the dye and (2)
    an -OH group of cotton.

62
Prob 21.31
  • Show how to prepare (a) and (b) from
    1-phenyl-1-propanone.

63
Prob 21.33
  • Show how to bring about each conversion.

64
Prob 21.35
  • Propose a synthesis for each compound from
    benzene.

65
Prob 21.36
  • Propose a synthesis of 2,4-D from chloroacetic
    acid and phenol.

66
Prob 21.41
  • Propose a synthesis of this compound from
    benzene.

67
Prob 21.42
  • Propose a synthesis of this compound from
    3-methylphenol.

68
Prob 21.43
  • Propose a synthesis of this compound from
    toluene and phenol.

69
Prob 21.44
  • Propose a mechanism for this example of
    chloromethylation (introduction of a CH2Cl group
    on an aromatic ring). Show how to convert the
    product of chloromethylation to piperonal.

70
Prob 21.45
  • Given this retrosynthetic analysis, propose a
    synthesis for Dinocap from phenol and 1-octene.

71
Prob 21.46
  • Show how to synthesize this trichloro derivative
    of toluene from toluene.

72
Prob 21.47
  • Given this retrosynthetic analysis, propose a
    synthesis for bupropion.

73
Aromatics II
End Chapter 21
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