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Chapter 4 Alkanes & Cycloalkane Conformations

Chapter 4 Alkanes & Cycloalkane Conformations. Conformations of Alkanes: Rotation about Carbon–Carbon Bonds . Conformational Analysis Drawing Acyclic Molecules. Newman Projections. Conformational Analysis Drawing Acyclic Molecules. Sawhorse Drawings. Question.

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Chapter 4 Alkanes & Cycloalkane Conformations

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  1. Chapter 4 Alkanes & Cycloalkane Conformations

  2. Conformations of Alkanes: Rotation about Carbon–Carbon Bonds

  3. Conformational AnalysisDrawingAcyclic Molecules • Newman Projections

  4. Conformational AnalysisDrawingAcyclic Molecules • Sawhorse Drawings

  5. Question Which of the following is a Newman projection of the following structure?

  6. Different Conformations of Ethane • A staggered conformer is more stable than an eclipsed • conformer • Torsional strain: repulsion between pairs of bonding • electrons

  7. Conformations of n-Butane • Steric strain: repulsion between the electron clouds of • atoms or groups

  8. Question Which of the following is the lowest in energy?

  9. Cycloalkanes: Ring Strain • Angle strain results when bond angles deviate from the • ideal 109.5° bond angle

  10. The Shapes of Cycloalkanes:Planar or Nonplanar?

  11. Adolf von Baeyer (19th century) • Assumed cycloalkanes were planar polygons. • Believed distortion of bond angles from 109.5° gives angle strain to some cycloalkanes. • One for two is great in baseball.

  12. Types of Strain • Torsional strain strain that results from eclipsed bonds (measure of the dihedral angle) • Van der Waals strain or (Steric strain) strain that results from atoms being too close together. • Angle strain results from distortion of bond angles from normal values, for a tetrahedron 109.5o

  13. TORSIONAL STRAIN • Can be explained using VSEPR theory or molecular orbital theory. • In the favored staggered conformation, the bonding and antibonding MOs of neighboring carbons overlap but atoms do not overlap.

  14. Measuring Strain in Cycloalkanes • Heats of combustion can be used to comparestabilities of isomers. • But cyclopropane, cyclobutane, etc. are not isomers. • All heats of combustion increase as the numberof carbon atoms increase.

  15. Measuring Strain in Cycloalkanes • Therefore, divide heats of combustion by number of carbons and compare heats of combustion on a "per CH2 group" basis.

  16. Heats of Combustion in Cycloalkanes • Cycloalkane kJ/mol Per CH2 • Cyclopropane 2,091 697 • Cyclobutane 2,721 681 • Cyclopentane 3,291 658 • Cyclohexane 3,920 653 • Cycloheptane 4,599 657 • Cyclooctane 5,267 658 • Cyclononane 5,933 659 • Cyclodecane 6,587 659

  17. Heats of Combustion in Cycloalkanes • Cycloalkane kJ/mol Per CH2 • According to Baeyer, cyclopentane should • have less angle strain than cyclohexane. • Cyclopentane 3,291 658 • Cyclohexane 3,920 653 • The heat of combustion per CH2 group is • less for cyclohexane than for cyclopentane. • Therefore, cyclohexane has less strain than • cyclopentane.

  18. Cyclic Alkanes – Cyclopropane • Cyclopropane is 44 kJ/mol less stable than cyclohexane per CH2 group. It is highly strained and very reactive due to: • Angle strain: • Bond angles of 60° cause electron pair repulsion in adjacent bonds • Inefficient sigma bond overlap • Torsional strain: • Eclipsing C–H bonds all the way around the ring—see Newman projection

  19. Cyclic Alkanes – Cyclobutane • Cyclobutane is 27 kJ/mol less stable than cyclohexane per CH2 group. It is also strained and reactive: • Angle strain results from bond angles of 88°, although it is not as severe as the 60° angles in cyclopropane. • Slight torsional strain results because adjacent C–H bonds are neither fully eclipsed nor fully staggered.

  20. Cyclic Alkanes – Cyclopentane • Cyclopentane is only 5 kJ/mol less stable than cyclohexane per CH2 group: • Angles are close to the optimal value. • Identify the minimal but significant torsional strain in the structure. It is very helpful to use a handheld model.

  21. Conformations of Cyclohexane • Heat of combustion suggests that angle strain is unimportant in cyclohexane. • Tetrahedral bond angles require nonplanar geometries. • The chair and boat conformations.

  22. Cyclic Alkanes – Cyclohexane • Cyclohexane is considered to have ZERO ring strain in its optimal conformation, the CHAIR: • No angle strain—angles must be 109.5°. • No torsional strain—all adjacent C–H bonds must be staggered.

  23. Cyclic Alkanes – Cyclohexane • Other conformations of hexane exist but are a bit less stable. Consider THE BOAT. • No angle strain—angles are 109.5°. • Torsional strain: • Use a molecular model to identify all four pairs of eclipsing C–H bonds • Draw a Newman projection that illustrates the torsional strain • Steric strain—flagpole interactions. WHERE?

  24. The chair conformation of cyclohexane is free of strain

  25. Chair is the most stable conformation of cyclohexane • All of the bonds are staggered and the bond angles at carbon are close to tetrahedral.

  26. Boat conformation is less stable than the chair 180 pm • All of the bond angles are close to tetrahedral but close contact between flagpole hydrogens causes strain in boat.

  27. Boat conformation is less stable than the chair • Eclipsed bonds bonds gives torsional strain to boat.

  28. Skew boat is slightly more stable than boat Boat • Less van der Waals strain and less torsional strain in skew boat. Skew or Twist Boat

  29. Generalization • The chair conformation of cyclohexane is themost stable conformation and derivativesof cyclohexane almost always exist in the chair conformation

  30. Axial and Equatorial Bonds in Cyclohexane

  31. Drawing Cyclohexane

  32. The 12 bonds to the ring can be divided into two sets of 6.

  33. 6 Bonds are axial Axial bonds point "north and south"

  34. The 12 bonds to the ring can be divided into two sets of 6.

  35. 6 Bonds are equatorial Equatorial bonds lie along the equator

  36. Conformational Inversion(Ring-Flipping) in Cyclohexane

  37. Conformational Inversion • chair-chair interconversion (ring-flipping) • rapid process (activation energy = 45 kJ/mol) • all axial bonds become equatorial and vice versa

  38. Half-chair

  39. Half-chair Skewboat

  40. Half-chair Skewboat

  41. Half-chair Skewboat

  42. 45 kJ/mol 45 kJ/mol 23 kJ/mol

  43. The Conformations of Cyclohexane and Their Energies

  44. Conformational Analysis of Monosubstituted Cyclohexanes • most stable conformation is chair • substituent is more stable when equatorial

  45. Steric Strain of 1,3-Diaxial Interaction in Methylcyclohexane

  46. CH3 CH3 Methylcyclohexane axial • Chair chair interconversion occurs, but at any instant 95% of the molecules have their methyl group equatorial. • An axial methyl group is more crowded than an equatorial one. equatorial 5% 95%

  47. Methylcyclohexane • Hydrogen atoms closer than 2.4 Angstroms will cause steric strain. • This is called a "1,3-diaxial repulsion" a type of van der Waals strain or Steric strain. 5% 95%

  48. Fluorocyclohexane F • Crowding is less pronounced with a "small" substituent such as fluorine. • Size of substituent is related to its branching. F 40% 60%

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