1. Chemical Bonding II: Molecular Geometry and Hybridization of Atomic Orbitals
Chapter 10

2. 10.1

3. Valence Shell Electron-Pair Repulsion (VSEPR) Theory
Molecular Shapes
Valence Shell Electron-Pair Repulsion
(VSEPR) Theory
Each group of valence electrons around a
central atom is located as far away from the
others as possible in order to minimize
repulsion.
An electron group may be a single, double,
or triple bond or a lone pair.

4. Balloon Analogy for the Mutual Repulsion of Electron Groups
Two
Three Four Five Six
Number of Electron Groups

6. First we will look at examples where there are no lone pairs of electrons on the central atom. In this case the molecular geometry is the same as the electron geometry.

7. Valence shell electron pair repulsion (VSEPR) model:
Predict the geometry of the molecule from the electrostatic repulsions between the electron (bonding and nonbonding) pairs.
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB2 2
linear
linear B
10.1

8. 0 lone pairs on central atom 2 atoms bonded to central atomCl Be
0 lone pairs on central atom
2 atoms bonded to central atom
10.1

9. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB2 2
linear
linear
trigonal planar
trigonal planar
AB3 3
10.1

10. 10.1

11. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB2 2
linear
linear
AB3 3
trigonal planar
AB4 4
tetrahedral
tetrahedral
10.1

12. 10.1

13. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB2 2
linear
linear
AB3 3
trigonal planar
AB4 4
tetrahedral
tetrahedral
trigonal
bipyramidal
trigonal
bipyramidal
AB5 5
10.1

14. 10.1

15. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB2 2
linear
linear
AB3 3
trigonal planar
AB4 4
tetrahedral
tetrahedral
AB5 5
trigonal
bipyramidal
AB6 6
octahedral
octahedral
10.1

16. 10.1

17. Chapter 10 Homework
1-5, 7, 8, 10-14, 16-24,
26, 28, 29, 32, 34-36,
41, 42

18. Last Test – Dec 6 or 7 EH Assignment Due Nov 29
Unit 12 Polyatomic Structures
Minimum score
Sec 1 Electronegativity and Bond Polarity 90
Sec 2 Lewis Dot Diagrams 88
Sec 3 Shapes of Ions and Molecules
later
Sec 4 Resonance and Formal Charge
Sec 5 Review of Molecular Shapes
Last Test – Dec 6 or 7

19. Molecular Shapes
You must distinguish between the electron-group
arrangement and the molecular shape. The
molecular shape is defined by the relative positions
of the atomic nuclei. If there are no lone pairs of
electrons the molecular shape is the same as the
electron-group arrangement.
If there are lone pairs the molecular shape is only
part of the electron arrangement. The ideal bond
angles are determined by the electron-group angles.

20. bonding-pair vs. bonding
pair repulsion
lone-pair vs. lone pair
repulsion
lone-pair vs. bonding
>

21. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
trigonal planar
trigonal planar
AB3 3
trigonal planar
AB2E 2 1
bent
SO2
10.1

22. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB4 4
tetrahedral
tetrahedral
trigonal pyramidal
AB3E 3 1
tetrahedral
10.1

23. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB4 4
tetrahedral
tetrahedral
AB3E 3 1
tetrahedral
trigonal
pyramidal
AB2E2 2 2
tetrahedral
bent H O
10.1

24. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
trigonal
bipyramidal
trigonal
bipyramidal
AB5 5
trigonal
bipyramidal
seesaw
AB4E 4 1
SF4
10.1

25. VSEPR trigonal bipyramidal trigonal bipyramidal AB5 5 AB4E 4 1
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
trigonal
bipyramidal
trigonal
bipyramidal
AB5 5
AB4E 4 1
trigonal
bipyramidal
distorted tetrahedron
trigonal
bipyramidal
AB3E2 3 2
T-shaped Cl F
10.1

26. VSEPR trigonal bipyramidal trigonal bipyramidal AB5 5 AB4E 4 1
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
trigonal
bipyramidal
trigonal
bipyramidal
AB5 5
AB4E 4 1
trigonal
bipyramidal
distorted tetrahedron
AB3E2 3 2
trigonal
bipyramidal
T-shaped
trigonal
bipyramidal
AB2E3 2 3
linear I
10.1

27. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB6 6
octahedral
square pyramidal Br F
AB5E 5 1
octahedral
10.1

28. Arrangement of electron pairs
VSEPR
Class
# of atoms
bonded to central atom
# lone
pairs on central atom
Arrangement of electron pairs
Molecular
Geometry
AB6 6
octahedral
AB5E 5 1
octahedral
square pyramidal
square planar Xe F
AB4E2 4 2
octahedral
10.1

29. Predicting Molecular Geometry
Draw Lewis structure for molecule.
Count number of lone pairs on the central atom and number of atoms bonded to the central atom.
Use VSEPR to predict the geometry of the molecule.
What are the molecular geometries of AsH3,
OF2, AlCl4-, H3O+, C2H4, SnCl5-, and C2H2?
10.1

30. Molecular Shapes with More Than
One Central Atom
For more complicated molecules you must give the shape and
bond angles around each central atom.
Examples: ethanol

31. The Tetrahedral Centers of Ethane and of Ethanol

32. Polar Molecules - Dipole moments
In chapter 9 you learned about covalent bonds that are polar.
A polar molecule is one the has a positive end and a negative end. (The center of positive charge and the center of negative charge do not coincide.) A polar molecule is said to have a dipole moment.
A molecule with two or more polar bonds can be nonpolar if it is symmetric.
Dipole moment = charge x distance

33. Dipole Moments and Polar MoleculesH F
electron rich
region
electron poor
region d+ d-
m = Q x r
Q is the charge
r is the distance between charges
1 D = 3.36 x C m
10.2

34. 10.2

35. - - - - .. .. .. .. .. .. Polarity of CO2 and H2O + O O C O H H + +
Water - H2O
Carbon Dioxide - CO2 - - - + - .. .. .. .. O O C O .. .. H H + +
A non- polar molecule
A Polar molecule
The bonds are polar,
but the molecule is
symmetrical, so that the
molecule overall is
non-polar.
The bonds are polar, and
the molecule is
non-symmetrical.

36. .. .. .. Predicting The Polarity of Molecules
Problem: From electronegativity, and their periodic trends, predict
whether each of the following molecules is polar and show the direction
of bond dipoles and the overall molecular dipole.
(a) Phosphine, PH3
(b) Carbon disulfide, CS2 (also OCS)
(c) Aluminum chloride, AlCl3 .. .. ..
(a) P P P H H H H H H H H H
Molecular Dipole
Bond dipoles
Molecular shape

37. 10.2

38. Which of the following molecules have a dipole moment?
H2O, CO2, SO2, and CH4 O H S O
dipole moment
polar molecule
dipole moment
polar molecule C H C O
no dipole moment
nonpolar molecule
no dipole moment
nonpolar molecule
10.2

39. Which of these are polar? CH4, CCl4, CHCl3,, CH2Cl2, CH3Cl.
10.2

40. Valence Bond Theory Basic Principle of Valence Bond Theory:
a covalent bond forms when the orbitals from
two atoms overlap and a pair of electrons
occupies the region between the nuclei.
Usually this means that each bonding orbital
should contain one electron. The electrons
must have opposite spins.
The bond strength depends on the attraction of nuclei for
the shared electrons, so the greater the orbital overlap,
the stronger the bond.

42. 10.4

43. Change in electron density as two hydrogen atoms approach each other.
10.3

44. The sp Hybrid Orbitals in Gaseous BeCl2

46. The total number of orbitals doesn’t change.
Hybridization is the mixing of atomic orbitals in an atom to generate a set of new orbitals called hybrid orbitals.
The total number of orbitals doesn’t change.
Covalent bonds are formed by:
Overlap of hybrid orbitals with atomic orbitals
Overlap of hybrid orbitals with other hybrid orbitals

49. 10.4

50. 10.4

51. How do I predict the hybridization of the central atom?
Count the groups of electrons
and determine the electron geometry.
# electron groups +
Electron geometry
Hybridization
Examples
2 (linear) sp
BeCl2
3 (trigonal planar)
sp2
BF3
4 (tetrahedral)
sp3
CH4, NH3, H2O
5 (trig. bipyramid)
sp3d
PCl5
6 (octahedral)
sp3d2
SF6
10.4

52. The sp3d Hybrid Orbitals in PCl5

53. The sp3d2 Hybrid Orbitals in SF6
Sulfur Hexafluoride SF6

54. Predict correct
bond angle

55. All the bonds we have seen so far are called
sigma bonds: the highest electron density is along
the bond axis. All single bonds are sigma bonds
and the first bond in double or triple bonds is a
sigma bond.
A pi bond is formed by a side-to-side overlap of
p orbitals. There are regions of high electron
density above and below the bond axis. The second
bond of a double bond is a pi bond, as are two of the
bonds in a triple bond.

56. Describe the bonding in C2H4
10.5

57. 10.5

58. Sigma bond (s) – electron density between the 2 atoms
Pi bond (p) – electron density above and below plane of nuclei of the bonding atoms
Sigma bond (s) – electron density between the 2 atoms
10.5

59. 10.5

60. For Chapter 10
See Test 1 Spring 2001
Test

61. Last Test – EH Assignment Due Dec 1 Unit 12 Polyatomic Structures
Minimum score
Sec 1 Electronegativity and Bond Polarity -
Sec 2 Lewis Dot Diagrams
Sec 3 Shapes of Ions and Molecules 90
Sec 4 Resonance and Formal Charge
Sec 5 Review of Molecular Shapes
Last Test –

62. Last Test – EH Assignment Due Dec 2 Unit 13 Covalent Bonding
Minimum score
Sec 1 Orbital Shapes 90
Sec 2 Hybridization 85
Sec 3 Bonding in Organic Structures
Sec 4 Polarity of Molecules
Sec 5 Molecular Orbital Structures
optional
Last Test –

63. Describe the bonding in C2H2
10.5

64. 10.5

65. Sigma (s) and Pi Bonds (p)
1 sigma bond
Single bond
Double bond
1 sigma bond and 1 pi bond
Triple bond
1 sigma bond and 2 pi bonds
How many s and p bonds are in the acetic acid
(vinegar) molecule CH3COOH? C H O
s bonds = 6
+ 1 = 7
p bonds = 1
10.5

66. Skip pages 318-326 molecular orbitals
Resonance implies electron delocalization. This can be explained by valence bond and molecular orbital theory.
This occurs when a p orbital overlaps with more than one other p orbital. The  electrons are free to move around three or more atoms.
Examples: ozone, benzene, sulfur trioxide.
Structures with delocalized electrons always have greater stability than similar structures without delocalized electrons.

67. Delocalized electrons are not confined between two adjacent bonding atoms, but actually extend over three or more atoms.
10.8

68. Electron density above and below the plane of the benzene molecule.
10.8

69. Experiments show O2 is paramagnetic
No unpaired e-
Should be diamagnetic
Molecular orbital theory – bonds are formed from interaction of atomic orbitals to form molecular orbitals.
10.6

70. Energy levels of bonding and antibonding molecular orbitals in hydrogen (H2).
A bonding molecular orbital has lower energy and greater stability than the atomic orbitals from which it was formed.
An antibonding molecular orbital has higher energy and lower stability than the atomic orbitals from which it was formed.
10.6

71. 10.6

72. 10.6

73. 10.6

74. Molecular Orbital (MO) Configurations
The number of molecular orbitals (MOs) formed is always equal to the number of atomic orbitals combined.
The more stable the bonding MO, the less stable the corresponding antibonding MO.
The filling of MOs proceeds from low to high energies.
Each MO can accommodate up to two electrons.
Use Hund’s rule when adding electrons to MOs of the same energy.
The number of electrons in the MOs is equal to the sum of all the electrons on the bonding atoms.
10.7

75. ( ) - bond order = 1 2 Number of electrons in bonding MOs
Number of electrons in antibonding MOs ( - )
bond order 1
10.7

76. 10.7