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Organic Chemistry

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Title: Organic Chemistry


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

2
Conjugated Dienes
Chapter 23
3
Conjugated Dienes
  • Dienes are divided into three groups
  • from heats of hydrogenation, we can compare
    relative stabilities of conjugated and
    unconjugated dienes

4
Conjugated Dienes
  • .

5
Conjugated Dienes
  • conjugation of the double bonds in 1,3-butadiene
    gives an extra stability of approximately 17 kJ
    (4.1 kcal)/mol

6
Conjugated Dienes
  • the pi system of butadiene is derived from the
    combination of four 2p atomic orbitals there are
    two bonding MOs and two antibonding MOs

7
Conjugated Systems
  • systems containing conjugated double bonds, not
    just those of dienes, are more stable than those
    containing unconjugated double bonds

8
1,2- and 1,4-Addition
  • Addition of 1 mole of HBr to butadiene at -78C
    gives a mixture of two constitutional isomers
  • we account for these products by the following
    two-step mechanism

9
1,2- and 1,4-Addition
  • the key intermediate is a resonance-stabilized
    allylic carbocation

10
1,2- and 1,4-Addition
  • Addition of 1 mole of Br2 to butadiene at -15C
    also gives a mixture of two constitutional
    isomers
  • we account for the formation of these 1,2- and
    1,4-addition products by a similar mechanism

11
Additional Exptl Info
  • for addition of HBr at -78C and Br2 at -15C,
    the 1,2-addition products predominate at higher
    temperatures (40 to 60C), the 1,4-addition
    products predominate
  • if the products of low temperature addition are
    warmed to the higher temperature, the product
    composition becomes identical to the higher
    temperature distribution the same result can be
    accomplished using a Lewis acid catalyst, such as
    FeCl3 or ZnCl2
  • if either pure 1,2- or pure 1,4- addition product
    is dissolved in an inert solvent at the higher
    temperature and a Lewis acid catalyst added, an
    equilibrium mixture of 1,2- and 1,4-product
    forms the same equilibrium mixture is obtained
    regardless of which isomer is used as the
    starting material

12
1,2- and 1,4-Addition
  • We interpret these results using the concepts of
    kinetic and thermodynamic control of reactions
  • Kinetic control the distribution of products is
    determined by their relative rates of formation
  • in addition of HBr and Br2 to a conjugated diene,
    1,2-addition occurs faster than 1,4-addition

13
1,2- and 1,4-Addition
  • Thermodynamic control the distribution of
    products is determined by their relative
    stabilities
  • in addition of HBr and Br2 to a butadiene, the
    1,4-addition product is more stable than the
    1,2-addition product

14
1,2- and 1,4-Addition
  • Is it a general rule that where two or more
    products are formed from a common intermediate,
    that the thermodynamically less stable product is
    formed at a greater rate?
  • No
  • whether the thermodynamically more or less stable
    product is formed at a greater rate from a common
    intermediate depends very much on the particular
    reaction and reaction conditions

15
Diels-Alder Reaction
  • Diels-Alder reaction a cycloaddition reaction of
    a conjugated diene and certain types of double
    and triple bonds
  • dienophile diene-loving
  • Diels-Alder adduct the product of a Diels-Alder
    reaction

16
Diels-Alder Reaction
  • alkynes also function as dienophiles
  • cycloaddition reaction a reaction in which two
    reactants add together in a single step to form a
    cyclic product

17
Diels-Alder Reaction
  • we write a Diels-Alder reaction in the following
    way
  • the special value of a D-A reaction is that it
  • (1) forms six-membered rings
  • (2) forms two new C-C bonds at the same time
  • (3) is stereospecific and regioselective

18
Diels-Alder Reaction
  • the conformation of the diene must be s-cis

19
Diels-Alder Reaction
  • (2Z,4Z)-2,4-hexadiene is unreactive in
    Diels-Alder reactions because nonbonded
    interactions prevent it from assuming the planar
    s-cis conformation

20
Diels-Alder Reaction
  • reaction is facilitated by a combination of
    electron-withdrawing substituents on one reactant
    and electron-releasing substituents on the other

21
Diels-Alder Reaction
22
Diels-Alder Reaction
  • the Diels-Alder reaction can be used to form
    bicyclic systems

23
Diels-Alder Reaction
  • exo and endo are relative to the double bond
    derived from the diene

24
Diels-Alder Reaction
  • for a Diels-Alder reaction under kinetic control,
    endo orientation of the dienophile is favored

25
Diels-Alder Reaction
  • the configuration of the dienophile is retained

26
Diels-Alder Reaction
  • Mechanism
  • no evidence for the participation of either
    radical of ionic intermediates
  • chemists propose that the Diels-Alder reaction is
    a pericyclic reaction
  • Pericyclic reaction a reaction that takes place
    in a single step, without intermediates, and
    involves a cyclic redistribution of bonding
    electrons

27
Aromatic Transition States
  • Hückel criteria for aromaticity the presence of
    (4n 2) pi electrons in a ring that is planar
    and fully conjugated
  • Just as aromaticity imparts a special stability
    to certain types of molecules and ions, the
    presence of (4n 2) electrons in a cyclic
    transition state imparts a special stability to
    certain types of transition states
  • reactions involving 2, 6, 10, 14.... electrons in
    a cyclic transition state have especially low
    activation energies and take place particularly
    readily

28
Aromatic Transition States
  • decarboxylation of ?-keto acids and
    ?-dicarboxylic acids (Section 17.9)
  • Cope elimination of amine N-oxides (Section 22.11)

29
Aromatic Transition States
  • the Diels-Alder reaction
  • We now look at examples of two more reactions
    that proceed by aromatic transition states
  • Claisen rearrangement
  • Cope rearrangement

30
Claisen Rearrangement
  • Claisen rearrangement a thermal rearrangement of
    allyl phenyl ethers to o-allyl phenols

31
Claisen Rearrangement
32
Claisen Rearrangement
  • Example 23.7 Predict the product of this Claisen
    rearrangement

33
Cope Rearrangement
  • Cope rearrangement a thermal isomerization of
    1,5-dienes

34
Cope Rearrangement
  • Example 23.8 Predict the product of these Cope
    rearrangements

35
Prob 23.21
  • Draw the structural formula for the Diels-Alder
    adduct of cyclopentadiene with each of the
    following.

36
Prob 23.22
  • Propose structural formulas for A and B, and
    specify the configuration of B.

37
Prob 23.24
  • Draw a Lewis structure for butadiene sulfone,
    and show by curved arrows the path of this
    reverse Diels-Alder reaction.

38
Prob 23.25
  • This triene undergoes an intramolecular
    Diels-Alder reaction to give the bicycloalkene on
    the right. Show how the triene is coiled to give
    this product, and show by curved arrows how the
    product is formed.

39
Prob 23.26
  • Draw a structural formula for the Diels-Alder
    adduct.

40
Prob 23.27
  • Propose a structural formula for the product of
    this intramolecular Diels-Alder reaction.

41
Prob 23.28
  • Draw a structural formula for the product of
    this Diels-Alder reaction, and show the
    stereochemistry of the adduct.

42
Prob 23.29
  • Propose a synthesis for the starting diene from
    cyclopentanone and acetylene. Rationalize the
    stereochemistry of the target dicarboxylic acid.

43
Prob 23.30
  • Propose a structural formula for compound A.

44
Prob 23.31
  • Predict the product of each Diels-Alder reaction.

45
Prob 23.32
  • Show how (1) and (2) react to give (3).

46
Prob 23.33
  • Provide a mechanism for each step in this
    sequence.

47
Prob 23.34
  • Propose a structural formula for A, and a
    mechanism for formation of the bicyclic product
    of this sequence.

48
Prob 23.35
  • Propose a mechanism for the following reaction,
    which is known alternatively as an allylic
    rearrangement or a conjugate addition.

49
Prob 23.36
  • All attempts to prepare cyclopentadienone give
    only a Diels-Alder adduct. Cycloheptatrienone,
    however, has been prepared by several methods and
    is a stable compound. Draw a structural formula
    for the Diels-Alder adduct, and account for the
    differences in stability of the two ketones.

50
Prob 23.37
  • Show how to synthesize the tricyclic diene on
    the left from 2-bromopropane, cyclopentadiene,
    and 2-cyclohexenone.

51
Prob 23.38
  • Propose a mechanism for this Claisen
    rearrangement.

52
Prob 23.39
  • Provide a mechanism for each reaction

53
Prob 23.40
  • Propose a mechanism for this example of a
    Carroll reaction.

54
Prob 23.41
  • Use curved arrows to show the flow of electrons
    in each photoisomerization.

55
Prob 23.42
  • Draw a structural formula for the product of
    this reaction, and show the stereochemistry of
    the product.

56
Prob 23.43
  • Propose a mechanism for the formation of A, and
    show how A can be converted to tolciclate. Use
    3-methyl-N-methylaniline as the source of the
    amine nitrogen, and thiophosgene, Cl2CS, as the
    source of CS group.

57
Conjugated Dienes
End Chapter 23
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