2. The Shapes of Molecules
10.1 Depicting Molecules and Ions with Lewis Structures
10.2 Using Lewis Structures and Bond Energies to
Calculate Heats of Reaction
10.3 Valence-Shell Electron-Pair Repulsion (VSEPR)
Theory and Molecular Shape
10.4 Molecular Shape and Molecular Polarity
3. Figure 10.1
The steps in converting a molecular formula into a Lewis structure.
Molecular
formula
Atom
placement
Sum of
valence e-
Remaining
valence e-
Lewis
structure
Place atom
with lowest
EN in center
Add A-group
numbers
Draw single bonds.
Subtract 2e-
for each bond.
Give each
atom 8e-
(2e-
for H)
Step 1
Step 2
Step 3
Step 4
5. SAMPLE PROBLEM 10.1 Writing Lewis Structures for Molecules with
One Central Atom
SOLUTION:
PROBLEM: Write a Lewis structure for CCl2F2, one of the compounds
responsible for the depletion of stratospheric ozone.
PLAN: Follow the steps outlined in Figure 10.1 .
Step 1: Carbon has the lowest EN and is the central atom.
The other atoms are placed around it.
C
Steps 2-4:
C has 4 valence e-
, Cl and F each have 7. The
sum is 4 + 4(7) = 32 valence e-
.
Cl
Cl F
F
C
Cl
Cl F
F
Make bonds and fill in remaining valence
electrons placing 8e-
around each atom.
:
::
::
:
:
::
: :
:
6. SAMPLE PROBLEM 10.2 Writing Lewis Structure for Molecules with
More than One Central Atom
PROBLEM: Write the Lewis structure for methanol (molecular formula
CH4O), an important industrial alcohol that is being used as a
gasoline alternative in car engines.
SOLUTION: Hydrogen can have only one bond so C and O must be next
to each other with H filling in the bonds.
There are 4(1) + 4 + 6 = 14 valence e-
.
C has 4 bonds and O has 2. O has 2 pair of nonbonding e-
.
C O H
H
H
H
::
7. SAMPLE PROBLEM 10.3 Writing Lewis Structures for Molecules with
Multiple Bonds.
PLAN:
SOLUTION:
PROBLEM: Write Lewis structures for the following:
(a) Ethylene (C2H4), the most important reactant in the
manufacture of polymers
(b) Nitrogen (N2), the most abundant atmospheric gas
For molecules with multiple bonds, there is a Step 5 which follows the
other steps in Lewis structure construction. If a central atom does not
have 8e-
, an octet, then e-
can be moved in to form a multiple bond.
(a) There are 2(4) + 4(1) = 12 valence e-
. H can have only
one bond per atom.
CC
H
H H
H
:
CC
H
H H
H
(b) N2 has 2(5) = 10 valence e-
. Therefore a triple bond is required to make
the octet around each N.
N
:
N
:
. .
..
N
:
N
:
. . N
:
N
:
8. Resonance: Delocalized Electron-Pair Bonding
Resonance structures have the same relative atom placement but a
difference in the locations of bonding and nonbonding electron pairs.
O
O O
A
B
C
O
O O
A
B
C
O3 can be drawn in 2 ways - O
O O
O
O O
Neither structure is actually correct but can be drawn to represent a structure
which is a hybrid of the two - a resonance structure.
O
O O
9. SAMPLE PROBLEM 10.4 Writing Resonance Structures
PLAN:
SOLUTION:
PROBLEM: Write resonance structures for the nitrate ion, NO3
-
.
After Steps 1-4, go to 5 and then see if other structures can be
drawn in which the electrons can be delocalized over more than
two atoms.
Nitrate has 1(5) + 3(6) + 1 = 24 valence e-
N
O
O O
N
O
O O
N
O
O O
N does not have an
octet; a pair of e-
will move in to form
a double bond.
N
O
O O
N
O
O O
N
O
O O
10. Formal Charge: Selecting the Best Resonance Structure
An atom “owns” all of its nonbonding electrons and half of its bonding electrons.
Formal charge of atom =
# valence e-
- (# unshared electrons + 1/2 # shared electrons)
O
O O
A
B
C
For OA
# valence e-
= 6
# nonbonding e-
= 4
# bonding e-
= 4 X 1/2 = 2
Formal charge = 0
For OB
# valence e-
= 6
# nonbonding e-
= 2
# bonding e-
= 6 X 1/2 = 3
Formal charge = +1
For OC
# valence e-
= 6
# nonbonding e-
= 6
# bonding e-
= 2 X 1/2 = 1
Formal charge = -1
11. Resonance (continued)
Smaller formal charges (either positive or negative) are preferable
to larger charges;
Avoid like charges (+ + or - - ) on adjacent atoms;
A more negative formal charge should exist on an atom with a
larger EN value.
Three criteria for choosing the more important resonance
structure:
12. EXAMPLE: NCO-
has 3 possible resonance forms -
Resonance (continued)
N C O
A
N C O
B
N C O
C
N C O N C O N C O
formal charges
-2 0 +1 -1 0 0 0 0 -1
Forms B and C have negative formal charges on N and O; this makes them
more important than form A.
Form C has a negative charge on O which is the more electronegative
element, therefore C contributes the most to the resonance hybrid.
13. SAMPLE PROBLEM 10.5 Writing Lewis Structures for Exceptions to the
Octet Rule.
PLAN:
SOLUTION:
PROBLEM: Write Lewis structures for (a) H3PO4 and (b) BFCl2. In (a)
decide on the most likely structure.
Draw the Lewis structures for the molecule and determine if there is
an element which can be an exception to the octet rule. Note that
(a) contains P which is a Period-3 element and can have an
expanded valence shell.
(a) H3PO4 has two resonance forms and formal charges
indicate the more important form.
O
PO O
O
H
H
H
O
PO O
O
H
H
H
-1
0
0
0
0
0
0
+1
0
0
0
0
0
0
0
0
lower formal charges
more stable
(b) BFCl2 will have only 1
Lewis structure.
F
B
Cl Cl
14. 10.2 Using Lewis Structures and Bond Energies to
Calculate Heats of Reaction
15. The enthalpy change required to break a particular bond in one
mole of gaseous molecules is the bond energy.
H2 (g) H (g) + H (g) ∆H0
= 436.4 kJ
Cl2 (g) Cl (g) + Cl (g) ∆H0
= 242.7 kJ
HCl (g) H (g) + Cl (g) ∆H0
= 431.9 kJ
O2 (g) O (g) + O (g) ∆H0
= 498.7 kJ O O
N2 (g) N (g) + N (g) ∆H0
= 941.4 kJ N N
Bond Energy
Bond Energies
Single bond < Double bond < Triple bond
16. Average bond energy in polyatomic molecules
H2O (g) H (g) + OH (g) ∆H0
= 502 kJ
OH (g) H (g) + O (g) ∆H0
= 427 kJ
Average OH bond energy =
502 + 427
2
= 464.5 kJ
17. Bond Energies (BE) and Enthalpy changes in reactions
∆H0
= total energy input – total energy released
= ΣBE(reactants) – ΣBE(products)
Imagine reaction proceeding by breaking all bonds in the
reactants and then using the gaseous atoms to form all the
bonds in the products.
18. Use bond energies to calculate the enthalpy change for:
H2 (g) + F2 (g) 2HF (g)
∆H0
= ΣBE(reactants) – ΣBE(products)
Type of
bonds broken
Number of
bonds broken
Bond energy
(kJ/mol)
Energy
change (kJ)
H H 1 436.4 436.4
F F 1 156.9 156.9
Type of
bonds formed
Number of
bonds formed
Bond energy
(kJ/mol)
Energy
change (kJ)
H F 2 568.2 1136.4
∆H0
= 436.4 + 156.9 – 2 x 568.2 = -543.1 kJ
19. Figure 10.2 Using bond energies to calculate ∆H0
rxn
∆H0
rxn = ∆H0
reactant bonds broken + ∆H0
product bonds formed
∆H0
1 = + sum of BE ∆H0
2 = - sum of BE
∆H0
rxn
Enthalpy,H
20. SAMPLE PROBLEM 10.6 Calculating Enthalpy Changes from Bond
Energies
SOLUTION:
PROBLEM: Use Table 9.2 (button at right) to calculate ∆H0
rxn for the
following reaction:
CH4(g) + 3Cl2(g) CHCl3(g) + 3HCl(g)
PLAN: Write the Lewis structures for all reactants and products and
calculate the number of bonds broken and formed.
H
C H
H
H + Cl Cl3
Cl
C Cl
Cl
H + H Cl3
bonds broken bonds formed
22. Because there is no way to measure the absolute value of
the enthalpy of a substance, must I measure the enthalpy
change for every reaction of interest?
Establish an arbitrary scale with the standard enthalpy of
formation (∆H0
) as a reference point for all enthalpy
expressions.
f
Standard enthalpy of formation (∆H0
) is the heat change
that results when one mole of a compound is formed from
its elements at a pressure of 1 atm.
f
The standard enthalpy of formation of any element in its
most stable form is zero.
∆H0
(O2) = 0f
∆H0
(O3) = 142 kJ/molf
∆H0
(C, graphite) = 0f
∆H0
(C, diamond) = 1.90 kJ/molf
23.
24. The standard enthalpy of reaction (∆H0
) as the enthalpy of
a reaction carried out at 1 atm.
rxn
aA + bB cC + dD
∆H0
rxn d∆H0
(D)fc∆H0
(C)f= [ + ] - b∆H0
(B)fa∆H0
(A)f[ + ]
∆H0
rxn n∆H0
(products)f= Σ m∆H0
(reactants)fΣ-
Hess’s Law: When reactants are converted to products,
the change in enthalpy is the same whether the reaction
takes place in one step or in a series of steps.
(Enthalpy is a state function. It doesn’t matter how you get
there, only where you start and end.)
25. Calculate the standard enthalpy of formation of CS2 (l)
given that:
C(graphite) + O2 (g) CO2 (g) ∆H0
= -393.5 kJrxn
S(rhombic) + O2 (g) SO2 (g) ∆H0
= -296.1 kJrxn
CS2(l) + 3O2 (g) CO2 (g) + 2SO2 (g) ∆H0
= -1072 kJrxn
1. Write the enthalpy of formation reaction for CS2
C(graphite) + 2S(rhombic) CS2 (l)
2. Add the given rxns so that the result is the desired rxn.
rxnC(graphite) + O2 (g) CO2 (g) ∆H0
= -393.5 kJ
2S(rhombic) + 2O2 (g) 2SO2 (g) ∆H0
= -296.1x2 kJrxn
CO2(g) + 2SO2 (g) CS2 (l) + 3O2 (g) ∆H0
= +1072 kJrxn+
C(graphite) + 2S(rhombic) CS2 (l)
∆H0
= -393.5 + (2x-296.1) + 1072 = 86.3 kJrxn
26. Benzene (C6H6) burns in air to produce carbon dioxide and
liquid water. What is the heat released per mole of
benzene combusted? The standard enthalpy of formation
of benzene is 49.04 kJ/mol.
2C6H6 (l) + 15O2 (g) 12CO2 (g) + 6H2O (l)
∆H0
rxn n∆H0
(products)f= Σ m∆H0
(reactants)fΣ-
∆H0
rxn 6∆H0
(H2O)f12∆H0
(CO2)f= [ + ] - 2∆H0
(C6H6)f[ ]
∆H0
rxn = [ 12x–393.5 + 6x–187.6 ] – [ 2x49.04 ] = -5946 kJ
-5946 kJ
2 mol
= 2973 kJ/mol C6H6
27. The enthalpy of solution (∆Hsoln) is the heat generated or
absorbed when a certain amount of solute dissolves in a
certain amount of solvent.
∆Hsoln = Hsoln - Hcomponents
Which could be used for
melting ice?
Which could be used for a
cold pack?
29. Valence shell electron pair repulsion (VSEPR) model:
Predict the geometry of the molecule from the electrostatic
repulsion between the electron (bonding and nonbonding) pairs.
AB2 2 0
Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
linear linear
B B
Examples:
CS2, HCN, BeF2
30. Cl ClBe
2 atoms bonded to central atom0 lone pairs on central atom
31. AB2 2 0 linear linear
Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3 3 0
trigonal
planar
trigonal
planar
Examples:
SO3, BF3, NO3
-
, CO3
2-
33. AB2 2 0 linear linear
Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3 3 0
trigonal
planar
trigonal
planar
AB4 4 0 tetrahedral tetrahedral
Examples:
CH4, SiCl4, SO4
2-
, ClO4
-
34.
35. AB2 2 0 linear linear
Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3 3 0
trigonal
planar
trigonal
planar
AB4 4 0 tetrahedral tetrahedral
AB5 5 0
trigonal
bipyramidal
trigonal
bipyramidal
Examples: PF5
AsF5
SOF4
36.
37. AB2 2 0 linear linear
Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3 3 0
trigonal
planar
trigonal
planar
AB4 4 0 tetrahedral tetrahedral
AB5 5 0
trigonal
bipyramidal
trigonal
bipyramidal
AB6 6 0 octahedraloctahedral
SF6
IOF5
40. Factors Affecting Actual Bond Angles
Bond angles are consistent with theoretical angles when the atoms
attached to the central atom are the same and when all electrons are
bonding electrons of the same order.
C O
H
Hideal
1200
1200
larger EN
greater
electron
density
C O
H
H
1220
1160
real
lone pairs repel bonding pairs
more strongly than bonding
pairs repel each other
Sn
Cl Cl
950
Effect of Double Bonds
Effect of Nonbonding Pairs
42. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3 3 0
trigonal
planar
trigonal
planar
AB2E 2 1
trigonal
planar
bent
43. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB3E 3 1
AB4 4 0 tetrahedral tetrahedral
tetrahedral
trigonal
pyramidal
NH3
PF3
ClO3
H3O+
44. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB4 4 0 tetrahedral tetrahedral
AB3E 3 1 tetrahedral
trigonal
pyramidal
AB2E2 2 2 tetrahedral bent
H
O
HH2O
OF2
SCl2
45. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB5 5 0
trigonal
bipyramidal
trigonal
bipyramidal
AB4E 4 1
trigonal
bipyramidal
distorted
tetrahedron
SF4
XeO2F2
IF4
+
IO2F2
-
46. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB5 5 0
trigonal
bipyramidal
trigonal
bipyramidal
AB4E 4 1
trigonal
bipyramidal
distorted
tetrahedron
AB3E2 3 2
trigonal
bipyramidal
T-shaped
ClF
F
F
ClF3
BrF3
47. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB5 5 0
trigonal
bipyramidal
trigonal
bipyramidal
AB4E 4 1
trigonal
bipyramidal
distorted
tetrahedron
AB3E2 3 2
trigonal
bipyramidal
T-shaped
AB2E3 2 3
trigonal
bipyramidal
linear
I
I
I
H2O
OF2
48. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB6 6 0 octahedraloctahedral
AB5E 5 1 octahedral square
pyramidal
Br
F F
FF
F
BrF5
TeF5
-
XeOF
4
49. Class
# of atoms
bonded to
central atom
# lone
pairs on
central atom
Arrangement of
electron pairs
Molecular
Geometry
VSEPR
AB6 6 0 octahedraloctahedral
AB5E 5 1 octahedral square
pyramidal
AB4E2 4 2 octahedral
square
planar
Xe
F F
FF
XeF4
ICl4
-
50. Predicting Molecular Geometry
1. Draw Lewis structure for molecule.
2. Count number of lone pairs on the central atom and
number of atoms bonded to the central atom.
3. Use VSEPR to predict the geometry of the molecule.
What is the molecular geometry of SO2 and SF4?
SO O
AB2E
bent
S
F
F
F F
AB4E
distorted
tetrahedron
51. Factors Affecting Actual Bond Angles
Bond angles are consistent with theoretical angles when the atoms
attached to the central atom are the same and when all electrons are
bonding electrons of the same order.
C O
H
Hideal
1200
1200
larger EN
greater
electron
density
C O
H
H
1220
1160
real
lone pairs repel bonding pairs
more strongly than bonding
pairs repel each other
Sn
Cl Cl
950
Effect of Double Bonds
Effect of Nonbonding Pairs
53. Figure 10.7 The two molecular shapes of the trigonal planar electron-
group arrangement.
Class
Shape
Examples:
SO3, BF3, NO3
-
, CO3
2-
Examples:
SO2, O3, PbCl2, SnBr2
54. Figure 10.8 The three molecular shapes of the tetrahedral electron-
group arrangement.
Examples:
CH4, SiCl4,
SO4
2-
, ClO4
-
NH3
PF3
ClO3
H3O+
H2O
OF2
SCl2
56. Figure 10.10 The four molecular shapes of the trigonal bipyramidal
electron-group arrangement.
SF4
XeO2F2
IF4
+
IO2F2
-
ClF3
BrF3
XeF2
I3
-
IF2
-
PF5
AsF5
SOF4
57. Figure 10.11 The three molecular shapes of the octahedral electron-
group arrangement.
SF6
IOF5
BrF5
TeF5
-
XeOF4
XeF4
ICl4
-
58. Figure 10.12
The steps in determining a molecular shape.
Molecular
formula
Lewis
structure
Electron-group
arrangement
Bond
angles
Molecular
shape
(AXmEn)
Count all e-
groups around central
atom (A)
Note lone pairs and double
bonds
Count bonding and
nonbonding e-
groups separately.
Step 1
Step 2
Step 3
Step 4
See Figure
10.1
59. SAMPLE PROBLEM 10.7 Predicting Molecular Shapes with Two, Three,
or Four Electron Groups
PROBLEM: Draw the molecular shape and predict the bond angles (relative
to the ideal bond angles) of (a) PF3 and (b) COCl2.
SOLUTION: (a) For PF3 - there are 26 valence electrons, 1 nonbonding pair
PF F
F
The shape is based upon the tetrahedral arrangement.
The F-P-F bond angles should be <109.50
due
to the repulsion of the nonbonding electron
pair.
The final shape is trigonal pyramidal.
P
F F
F
<109.50
The type of shape is
AX3E
60. SAMPLE PROBLEM 10.7 Predicting Molecular Shapes with Two, Three,
or Four Electron Groups
continued
(b) For COCl2, C has the lowest EN and will be the center atom.
There are 24 valence e-
, 3 atoms attached to the center atom.
CCl O
Cl
C does not have an octet; a pair of nonbonding
electrons will move in from the O to make a
double bond.
The shape for an atom with three atom
attachments and no nonbonding pairs on the
central atom is trigonal planar.C
Cl
O
Cl The Cl-C-Cl bond angle will
be less than 1200
due to
the electron density of the
C=O.
C
Cl
O
Cl
124.50
1110
Type AX3
61. SAMPLE PROBLEM 10.8 Predicting Molecular Shapes with Five or Six
Electron Groups
PROBLEM: Determine the molecular shape and predict the bond angles
(relative to the ideal bond angles) of (a) SbF5 and (b) BrF5.
SOLUTION: (a) SbF5 - 40 valence e-
; all electrons around central
atom will be in bonding pairs; shape is AX5 - trigonal
bipyramidal.
F
SbF
F F
F
F Sb
F
F
F
F
(b) BrF5 - 42 valence e-
; 5 bonding pairs and 1 nonbonding pair on central
atom. Shape is AX5E, square pyramidal.
Br
F
F F
F
F
64. SAMPLE PROBLEM 10.9 Predicting Molecular Shapes with More Than
One Central Atom
SOLUTION:
PROBLEM: Determine the shape around each of the central atoms in
acetone, (CH3)2C=O.
PLAN: Find the shape of one atom at a time after writing the Lewis
structure.
C C C
O
H
H
H
HH
H
tetrahedral tetrahedral
trigonal planar
C
O
H
C
HHH
C
H
H
>1200
<1200
65. Dipole Moments and Polar Molecules
H F
electron rich
region
electron poor
region
δ+ δ−
µ = Q x r
Q is the charge
r is the distance between charges
1 D = 3.36 x 10-30
C m
68. Which of the following molecules have a dipole moment?
H2O, CO2, SO2, and CH4
O
H
H
dipole moment
polar molecule
S
O
O
CO O
no dipole moment
nonpolar molecule
dipole moment
polar molecule
C
H
H
HH
no dipole moment
nonpolar molecule
69.
70. SAMPLE PROBLEM 10.10 Predicting the Polarity of Molecules
(a) Ammonia, NH3 (b) Boron trifluoride, BF3
(c) Carbonyl sulfide, COS (atom sequence SCO)
PROBLEM: From electronegativity (EN) values (button) 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 when applicable:
PLAN: Draw the shape, find the EN values and combine the concepts to
determine the polarity.
SOLUTION: (a) NH3
N
H
H
H
ENN = 3.0
ENH = 2.1
N
H
H
H
N
H
H
H
bond dipoles molecular
dipole
The dipoles reinforce each
other, so the overall
molecule is definitely polar.
71. SAMPLE PROBLEM 10.10 Predicting the Polarity of Molecules
continued
(b) BF3 has 24 valence e-
and all electrons around the B will be involved in
bonds. The shape is AX3, trigonal planar.
F
B
F
F
F (EN 4.0) is more electronegative
than B (EN 2.0) and all of the dipoles
will be directed from B to F. Because
all are at the same angle and of the
same magnitude, the molecule is
nonpolar.
1200
(c) COS is linear. C and S have the same EN (2.0) but the C=O bond is
quite polar(∆EN) so the molecule is polar overall.
S C O