1. Conjugated Pi Systems and Pericyclic Reactions
Organic Chemistry
Second Edition
David Klein
Chapter 17
Conjugated Pi Systems and Pericyclic Reactions
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Klein, Organic Chemistry 2e

2. 17.1 Classes of Dienes There are three categories for dienes
Cumulated – pi bonds are adjacent
Conjugated – pi bonds are separated by exactly ONE single bond
Isolated – pi bonds are separated by any distance greater than ONE single bond
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Klein, Organic Chemistry 2e

3. 17.1 Classes of Dienes There are three categories for dienes
Cumulated – pi bonds are perpendicular
Conjugated – pi bond overlap extends over the entire system
Isolated – pi bonds are separated by too great a distance to experience extra overlap
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Klein, Organic Chemistry 2e

4. 17.1 Classes of Dienes This chapter focuses on conjugated systems
Heteroatoms may be involved in a conjugated system
Draw a picture of the molecule shown to the right indicating where the pi bonds are and how they overlap
Practice with conceptual checkpoint 17.1
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Klein, Organic Chemistry 2e

5. 17.2 Conjugated Dienes
A sterically hindered base can be used to form dienes while avoiding the competing substitution reaction
Practice with conceptual checkpoint 17.2
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6. Klein, Organic Chemistry 2e
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7. 17.2 Conjugated Dienes
Single bonds that are part of a conjugated pi system are shorter than typical single bonds
What is a pm?
The hybridization of a carbon affects its bond length
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8. 17.2 Conjugated Dienes
The more s-character a carbon has, the shorter its bonds will be. WHY?
Practice with conceptual checkpoint 17.3
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9. 17.2 Conjugated Dienes
HOW do heats of hydrogenation provide information about stability?
WHY is energy released upon hydrogenation?
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10. 17.2 Conjugated Dienes HOW does conjugation affect stability?
Practice conceptual checkpoints 17.4 and 17.5
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11. 17.2 Conjugated Dienes
Rank the following compounds in order of increasing stability
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12. 17.2 Conjugated Dienes In general, single bonds will freely rotate
The two most stable rotational conformations for butadiene are the s-cis and s-trans
What does the “s” of s-cis and s-trans stand for?
Are there any other rotational conformations that you think might be possible?
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Klein, Organic Chemistry 2e

13. 17.2 Conjugated Dienes
The s-cis and s-trans both allow for full pi system overlap
Other possible conformations will be higher in energy
WHY?
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Klein, Organic Chemistry 2e

14. 17.2 Conjugated Dienes Why is s-trans lower in energy?
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15. 17.2 Conjugated Dienes
About 98% of the molecules are in the s-trans form
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16. 17.2 Conjugated Dienes
The highest energy conformer will not be conjugated
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17. 17.4 Electrophilic Addition
Recall the Markovnikov addition of H-X to a C=C double bond from section 9.3
With a conjugated diene as the substrate, two products are observed
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Klein, Organic Chemistry 2e

18. 17.4 Electrophilic Addition
The pi electrons attack the acid to give the most stable carbocation
What intermediate would result if the H were added to any of the other carbons in the molecule?
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Klein, Organic Chemistry 2e

19. 17.4 Electrophilic Addition
The resonance stabilized carbocation can be attacked by the halide at either site that is sharing the (+) charge
How is 1,2-addition different from 1,4-addition?
Practice with SkillBuilder 17.1
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Klein, Organic Chemistry 2e

20. Klein, Organic Chemistry 2e
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Klein, Organic Chemistry 2e

21. Klein, Organic Chemistry 2e
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22. Klein, Organic Chemistry 2e
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23. 17.4 Electrophilic Addition
The addition of bromine to a diene also gives both 1,2 and 1,4 addition
Predict the MAJOR products for the reaction below. Pay close attention to stereochemistry
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24. 17.5 Thermodynamic Control vs. Kinetic Control
The ratio of 1,2 vs. 1,4 addition is often temperature dependant
The energy diagram must be examined to see WHY temperature affects the product distribution
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25. 17.5 Thermodynamic Control vs. Kinetic Control
Why are the products unequal in free energy?
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26. 17.5 Thermodynamic Control vs. Kinetic Control
Predict the MAJOR product for the following reactions
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27. Klein, Organic Chemistry 2e
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28. Klein, Organic Chemistry 2e
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29. 17.6 Intro to Pericyclic Reactions
Pericyclic reactions occur without ionic or free radical intermediates
There are three main types of pericyclic reactions
Cycloaddition reactions
How is it an addition reaction?
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30. 17.6 Intro to Pericyclic Reactions
There are three main types of pericyclic reactions
Electrocyclic reactions
Sigmatropic rearrangements
What is the difference between an addition and a rearrangement?
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Klein, Organic Chemistry 2e

31. 17.6 Intro to Pericyclic Reactions
Pericyclic reactions have 4 general features
The reaction mechanism is concerted. It proceeds without any intermediates
The mechanism involves a ring of electrons moving around a closed loop
The transition state is cyclic
The polarity of the solvent generally has no effect on the reaction rate. WHY is that significant?
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Klein, Organic Chemistry 2e

32. 17.6 Intro to Pericyclic Reactions
Changes in the number of pi and sigma bonds distinguish the pericyclic reactions from one another
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33. 17.7 Diels-Alder Reactions
Diels-Alder reactions can be very useful
They allow a synthetic chemist to quickly build molecular complexity
What is meant by [4+2] cycloaddition?
Like all pericyclic reactions, the mechanism is concerted
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Klein, Organic Chemistry 2e

34. 17.7 Diels-Alder Reactions
The arrows could be drawn in a clockwise or counterclockwise direction
Can you draw a reasonable transition state?
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Klein, Organic Chemistry 2e

35. 17.7 Diels-Alder Reactions
Why do the products generally have lower free energy?
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Klein, Organic Chemistry 2e

36. 17.7 Diels-Alder Reactions
Most Diels-Alder reactions are thermodynamically favored at low and moderate temperatures
At temperatures above 200 C, the retroDiels-Alder can predominate
Will the reaction probably be favored or disfavored by entropy?
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Klein, Organic Chemistry 2e

37. 17.7 Diels-Alder Reactions
The pi  sigma conversion provides a (-)ΔH
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38. 17.7 Diels-Alder Reactions
ΔS should be (-)
Two molecules combine to form ONE
A ring (with limited rotational freedom) forms
What will the sign (+/-) be for the –TΔS term?
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Klein, Organic Chemistry 2e

39. 17.7 Diels-Alder Reactions
Given the signs for ΔH and –TΔS, how should temperature affect reaction spontaneity (reactant vs. product favorability)?
Are there any disadvantages if the temperature is too low? Think kinetics
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Klein, Organic Chemistry 2e

40. 17.7 Diels-Alder Reactions
In the Diels-Alder reaction, the reactants are generally classified as either the diene or dienophile
If a dienophile is not substituted with an electron withdrawing group, it will not be kinetically favored (a lot of activation energy or high temperature is required)
However, high temps do not favor the products thermodynamically
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Klein, Organic Chemistry 2e

41. 17.7 Diels-Alder Reactions
When an electron withdrawing group is attached to the dienophile, the reaction is generally spontaneous
Show how the groups highlighted in red are electron withdrawing using resonance and induction where appropriate
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Klein, Organic Chemistry 2e

42. 17.7 Diels-Alder Reactions
Diels-Alder reactions are stereospecific depending on whether the (E) or (Z) dienophile is used
Which alkene is (E) and which is (Z)?
We will investigate the stereochemical outcome later in this chapter
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Klein, Organic Chemistry 2e

43. 17.7 Diels-Alder Reactions
A CΞC triple bond can also act as a dienophile
Practice with SkillBuilder 17.3
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44. Klein, Organic Chemistry 2e
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Klein, Organic Chemistry 2e

45. Klein, Organic Chemistry 2e
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Klein, Organic Chemistry 2e

46. 17.7 Diels-Alder Reactions
Predict products for the following reactions
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Klein, Organic Chemistry 2e

47. 17.7 Diels-Alder Reactions
Diels-Alder reactions can also be affected by diene structure
Recall that many dienes can exist in an s-cis or an s-trans rotational conformation
Which conformation is generally more stable, and WHY?
Diels-Alder reactions can ONLY proceed when the diene adopts the s-cis conformation
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Klein, Organic Chemistry 2e

48. 17.7 Diels-Alder Reactions
Dienes that can only exist in an s-trans conformation can not undergo Diels-Alder reactions, because carbons 1 and 4 are too far apart
Dienes that are locked into the s-cis conformation undergo Diels-Alder reactions readily
Cyclopentadiene is so reactive, that at room temperature, two molecule will react together. Show the reaction and products 4 1
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Klein, Organic Chemistry 2e

49. 17.7 Diels-Alder Reactions
Draw four potential bicyclic Diels-Alder products for the reaction below
Two of the potential stereoisomers are impossible. WHICH ones and WHY?
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Klein, Organic Chemistry 2e

50. 17.7 Diels-Alder Reactions
When bicyclic systems form, the terms ENDO and EXO are used to describe functional group positioning
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51. 17.7 Diels-Alder Reactions
The electron withdrawing groups attached to dieneophiles tend to occupy the ENDO position
Major Product
Minor Product
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Klein, Organic Chemistry 2e

52. 17.7 Diels-Alder Reactions
The Diels-Alder transition state that produces the ENDO product benefits from favorable pi system interactions
Is this a kinetic or thermodynamic argument?
Draw an appropriate energy diagram
Practice with conceptual
checkpoint 17.19
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Klein, Organic Chemistry 2e

53. Klein, Organic Chemistry 2e
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54. Klein, Organic Chemistry 2e
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55. 17.9 Electrocyclic reactions
Determine how the number of σ and π bonds change for the representative electrocyclic reactions below
Explain why the equilibrium favor either products or reactants in the examples above
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Klein, Organic Chemistry 2e

56. 17.9 Electrocyclic reactions
When substituents are present on the terminal carbons, stereoisomers are possible
Note that the use of light versus heat gives different products. See next few slides for explanation
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Klein, Organic Chemistry 2e

57. 17.9 Electrocyclic reactions
Often the energy present at room temperature is sufficient to promote thermal electrocyclic reactions
Note that with the use heat, the configuration of the reactant determines the product formed
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Klein, Organic Chemistry 2e

58. 17.9 Electrocyclic reactions
Molecular orbitals of pi systems (ethylene):
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59. 17.9 Electrocyclic reactions
Molecular orbitals of pi systems (butadiene):
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60. 17.9 Electrocyclic reactions
The symmetry of the HOMO determines the outcome
The terminal carbons rotate as they become sp3 hybridized and overlap lobes that are in phase
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Klein, Organic Chemistry 2e

61. 17.9 Electrocyclic reactions
The terminal carbons rotate as they become sp3 hybridized and overlap lobes that are in phase
Disrotatory rotation (one rotates clockwise and the other counterclockwise) gives the cis product
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Klein, Organic Chemistry 2e

62. 17.9 Electrocyclic reactions
Use MO theory to explain the products for the reactions below
Will disrotatory or conrotatory rotation be necessary?
Practice with conceptual checkpoint 17.21
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63. Klein, Organic Chemistry 2e
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64. 17.9 Electrocyclic reactions
Predict the major product for the reaction below. Pay close attention to stereochemistry
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Klein, Organic Chemistry 2e

65. 17.9 Electrocyclic reactions
Under photochemical conditions, light energy excites an electron from the HOMO to the LUMO
What was the LUMO becomes the new HOMO
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66. 17.9 Electrocyclic reactions
Will the new excited HOMO react disrotatory or conrotatory?
Draw the expected product
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Klein, Organic Chemistry 2e

67. 17.9 Electrocyclic reactions
Make the same MO analysis to predict the symmetry-allowed product for the reaction below. Pay close attention to stereochemistry
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Klein, Organic Chemistry 2e

68. 17.9 Electrocyclic reactions
The disrotatory nature of the photochemical [2+2] electrocyclic ring-closing is difficult to observe directly, because the thermodynamically favors ring opening
The ring-opening reaction gives products that result from disrotatory rotation. Predict products below
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Klein, Organic Chemistry 2e

69. 17.9 Electrocyclic reactions
The Woodward-Hoffmann rules for thermal and photochemical electrocyclic reactions are found in table 17.2
Practice with SkillBuilder 17.4
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70. Klein, Organic Chemistry 2e
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71. Klein, Organic Chemistry 2e
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72. Klein, Organic Chemistry 2e
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73. Klein, Organic Chemistry 2e
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74. 17.10 Sigmatropic Rearrangements
Sigmatropic Rearrangements – a pericyclic reaction in which one sigma bond is replaced with another
Note that the pi bonds move their location
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75. 17.10 Sigmatropic Rearrangements
The notation for sigmatropic rearrangements is different from reactions we have seen so far
Count the number of atoms on each side of the sigma bonds that are breaking and forming
This is a [3,3] sigmatropic rearrangement
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Klein, Organic Chemistry 2e

76. 17.10 Sigmatropic Rearrangements
The reaction below is a [1,5] sigmatropic rearrangement
Practice with conceptual checkpoint 17.25
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77. Klein, Organic Chemistry 2e
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78. Klein, Organic Chemistry 2e
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Klein, Organic Chemistry 2e

79. 17.10 Sigmatropic Rearrangements
The Cope rearrangement is a [3,3] sigmatropic reaction in which all 6 atoms in the cyclic transition state are CARBONS
In general, what factors affect the spontaneity of the reaction (product favored vs. reactant favored)?
Practice with conceptual checkpoint 17.26
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80. Klein, Organic Chemistry 2e
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81. 17.10 Sigmatropic Rearrangements
The Claisen rearrangement is a [3,3] sigmatropic reaction in which one of the 6 atoms in the cyclic transition state is an OXYGEN
In general, what factors affect the spontaneity of the reaction?
Practice with conceptual checkpoints and 17.28
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82. Klein, Organic Chemistry 2e
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83. 17.10 Sigmatropic Rearrangements
Two pericyclic reactions occur in the biosynthesis of Vitamin D
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Klein, Organic Chemistry 2e

84. 17.12 Color
The visible region of the spectrum ( nm) is lower energy than UV radiation
Lycopene is responsible for the red color of tomatoes
Β-carotene is responsible for the orange color of carrots
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Klein, Organic Chemistry 2e

85. 17.12 Color
The color observed by your eyes will be the opposite of what is required to cause the π  π* excitation. WHY?
Practice with conceptual checkpoint 17.31
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86. Klein, Organic Chemistry 2e
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87. 17.12 Color
Bleaching agents generally work by breaking up conjugation through an addition reaction
Destroying long range conjugation destroys the ability to absorb colored light. WHY?
Does bleach actually remove stains?
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Klein, Organic Chemistry 2e

88. Additional Practice Problems
Explain the relationship between heat of hydrogenation and stability of a pi system.
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Klein, Organic Chemistry 2e

89. Additional Practice Problems
Explain why the instability of electrons in a pi MO directly relates to the number of nodes the orbital posses.
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Klein, Organic Chemistry 2e

90. Additional Practice Problems
Give a complete mechanism and predict the major product for the addition reaction below.
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Klein, Organic Chemistry 2e

91. Additional Practice Problems
Predict the products and give necessary conditions for the compound below to undergo a retro Diels-Alder
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Klein, Organic Chemistry 2e

92. Additional Practice Problems
Predict the products for the electrocyclic ring-opening below with proper stereochemical configuration.
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Klein, Organic Chemistry 2e