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GASES II – Unit 11

•
•
•
•

5-1

THEIR PROPERTIES AND
BEHAVIORS
Chapter 9.4-9.9 (McM)
Chapter 5.4-5.6 Silberberg
Chapter 5

Gases and the Kinetic-Molecular Theory

5-2
Gases and the Kinetic Molecular Theory - II

5.4 Rearrangements of the Ideal Gas Law
5.5 The Kinetic-Molecular Theory: A Model for Gas Behavior
5.6 Real Gases: Deviations from Ideal Behavior

5-3
Goals & Objectives
• See the Learning Objectives on
pages 217.
• Understand these Concepts:
• 5.5-12.
• Master these Skills:
• 5.4-5.7
5-4
Application of the Gas Laws
•
•
•
•

5-5

Partial Pressures
Collecting Gases over Water
Densities of gases
Combining Volumes
Dalton’s Law of Partial
Pressures
• The total pressure exerted by a
mixture of gases is the sum of the
partial pressures of the individual
gases.
• Partial pressure(p) is the pressure a
gas would exert if it occupied the
volume alone.
• PT = p1 + p2 + p3 + ………..
5-6
Figure 5.17

5-7

A molecular view of Dalton’s law
Exercises
• If 100 mL of hydrogen measured at
25 C and 3.00 atm pressure, and 100
mL of oxygen measured at 25 C and
2.00 atm pressure, are forced into
one of the containers at 25 C,
determine the pressure of the mixture
of gases.

5-8
5-9
5-10
Figure 5.12

5-11

Collecting a water-insoluble gaseous product
and determining its pressure.
Table 5.2 Vapor Pressure of Water (P

H2O

T(0C)

T(0C)

0
5
10
12
14
16
18
20
22
24
26
28
30
35

5-12

P
(torr)
H2O
4.6
6.5
9.2
10.5
12.0
13.6
15.5
17.5
19.8
22.4
25.2
28.3
31.8
42.2

40
45
50
55
60
65
70
75
80
85
90
95
100

) + at Different T

P

H2O

(torr)

55.3
71.9
92.5
118.0
149.4
187.5
233.7
289.1
355.1
433.6
525.8
633.9
760.0
Exercises
• A sample of hydrogen was collected
by displacement of water at 25 C .
The atmospheric pressure was 748
torr. Determine the pressure exerted
by dry hydrogen in this container. The
vapor pressure of water at 25 C is
23.8 torr.

5-13
5-14
5-15
Exercises
• A sample of oxygen was collected by
displacement of water. The mixture
occupied 742 mL at 27 C. The
barometric pressure was 753 torr.
Determine the volume of dry oxygen
under these conditions. The vapor
pressure of water at 27 C is 26.7 torr.

5-16
5-17
The Ideal Gas Law and Gas Density
The density of a gas is
- directly proportional to its molar mass and
- inversely proportional to its temperature.
m
density =
V
PV =

m
V
5-18

and
m

M

=d=

moles =

RT

M xP
RT

m

M
Sample Problem 5.7
PROBLEM:

Calculating Gas Density

Find the density (in g/L) of CO2 (g)
(a) at STP.

PLAN:

We can use the molar mass of CO2 to find its density from
the ideal gas equation.

SOLUTION:

d=

(a) At STP, or 273 K and 1.00 atm:

M xP
RT

44.01 g/mol x 1.00 atm
=

0.0821 atm·L x 273 K

= 1.96 g/L

mol·K

1.96 g CO2 x 1 mol CO2 x 6.022 x 1023 molecules
1L
1 mol
44.01 g CO2
= 2.68 x 1022 molecules CO2/L

5-19
Densities of Gases
• Determine the density of a 25.9 g
sample of He gas at 25 C and .989
atm.
• (Molar mass of He = 4.00g/mol)

5-20
5-21
5-22
Exercises
• One (1.00) mole of a gas occupies
36.5 liters, and its density is 1.36 g/L
at a given temperature and pressure.
• Determine its molecular weight.
• Calculate the density of this gas at
STP.

5-23
5-24
5-25
Molar Mass from the Ideal Gas Law

n=

m

M

M=

5-26

=

PV

RT

mRT

PV
Molar Masses
• A 250 mL flask contains 0.423 g of
vapor at 100 C and 746 torr.
Determine the density and molar
mass of this compound.

5-27
5-28
5-29
Exercises
• A compound that contains only C and
H is 80.0% C and 20.0% H by mass.
At STP 546 mL of the gas has a
mass of 0.732 g. Find the molecular
formula for the compound.
Molar masses: C, 12.0 g/mol; H, 1.0
g/mol

5-30
5-31
5-32
Gay-Lussac’s Law of
Combining Gas Volumes
• The volumes of gases involved in a
reaction bear a small whole-number
relationship to each other.
• This law applies only at constant
temperature and pressure.
• Gases combine in definite and simple
proportions by volume.

5-33
Gay-Lussac’s Law of
Combining Gas Volumes
• 4NH3(g) +5O2(g)=4NO(g)+6H2O(g)
• 4 moles 5 moles 4 moles 6 moles
• 4 mL 5mL
4mL
6mL
• 4L
5L
4L
6L

5-34
Gay-Lussac’s Law of
Combining Gas Volumes
• Determine the volume of NO that
would be produced in the previous
reaction if 25mL of NH3 reacts with
25mL of O2 if all gases are measured
at the same temperature and
pressure. Assume the reaction
occurs until all of one reactant is
consumed.
5-35
5-36
5-37
The Ideal Gas Law and Stoichiometry
P, V, T
of gas A

P, V, T
of gas B

Amount (mol)
of gas A

Amount (mol)
of gas B

Figure 15.13
The relationships among the amount (mol, n) of gaseous
reactant (or product) and the gas pressure (P), volume (V),
and temperature (T).

5-38
Sample Problem 5.11

Using Gas Variables to Find Amounts of
Reactants and Products I

PROBLEM: What volume of H2 gas at 765 torr and 225 C is needed
to reduce 35.5 g of copper(II) oxide to form pure copper
and water?
PLAN: Write a balanced equation. Convert the mass of copper (II) oxide
to moles and find the moles of H2, using the mole ratio from the
balanced equation. Calculate the corresponding volume of H2
using the ideal gas law.
mass (g) of CuO
divide by M

mol CuO
use mole ratio

mol H2

volume of H2
ideal gas law

5-39
Sample Problem 5.11
SOLUTION:

CuO(s) + H2(g) → Cu(s) + H2O(g)

35.5 g CuO x 1 mol CuO x 1 mol H2 = 0.446 mol H
2
79.55 g CuO
1 mol CuO
P = 765 torr x

V=

5-40

nRT
=
P

1 atm
= 1.01 atm
760 torr

T = 225 C + 273.15 K = 498 K

0.446 mol H2 x 0.0821
1.01 atm

atm·L
x 498 K
mol·K

= 18.1 L H2
Sample Problem 5.12
PROBLEM:

PLAN:

Using Gas Variables to Find Amounts of
Reactants and Products II

What mass of potassium chloride forms when 5.25 L of
chlorine gas at 0.950 atm and 293 K reacts with 17.0 g of
potassium metal?

First we must write a balanced equation. Since the quantities of
both reactants are given, we must next determine which reactant
is limiting. We will use the ideal gas law to calculate the moles of
Cl2 present.

SOLUTION:

The balanced equation is:
Cl2(g) + 2K(s) → 2KCl(s)

For Cl2:
P = 0.950 atm V = 5.25 L
T = 293 K
n = unknown

5-41
Sample Problem 5.12
n

Cl2 =

PV =
RT

0.50 atm
0.0821

x
atm·L
mol·K

5.253 L
x 293 K

= 0.207 mol Cl2

2 mol KCl
= 0.435 mol KCl
1 mol Cl2

For Cl2:

0.207 mol Cl2 x

For K:

17.0 g K x 1 mol K x 2 mol KCl = 0.414 KCl
39.10 g K
2 mol K
Cl2 is the limiting reactant.

0.435 mol KCl x 74.55 g KCl
1 mol KCl

5-42

= 30.9 g KCl
Exercise
• Determine the volume of O2,
measured at STP, that can be
produced by the thermal
decomposition of 120g of KClO3.
• 2KClO3(s)
2KCl(s)+3O2(g)

5-43
5-44
5-45
The Kinetic-Molecular Theory:
A Model for Gas Behavior
Postulate 1:
Gas particles are tiny with large spaces between them. The volume
of each particle is so small compared to the total volume of the gas
that it is assumed to be zero.

Postulate 2:
Gas particles are in constant, random, straight-line motion except
when they collide with each other or with the container walls.

Postulate 3:
Collisions are elastic, meaning that colliding particles exchange
energy but do not lose any energy due to friction. Their total kinetic
energy is constant. Between collisions the particles do not influence
each other by attractive or repulsive forces.

5-46
Figure 5.14 Distribution of molecular speeds for N2 at three
temperatures.

5-47
Figure 5.15

5-48

Pressure arise from countless collisions between
gas particles and walls.
Kinetic Energy and Gas Behavior
At a given T, all gases in a sample have the same
average kinetic energy.
1
Ek = mass x speed2
2

Kinetic energy depends on both the mass and the
speed of a particle.
At the same T, a heavier gas particle moves more
slowly than a lighter one.

5-49
Figure 5.20 The relationship between molar mass and molecular
speed.

5-50
Graham’s Law of Effusion
Effusion is the process by which a gas escapes
through a small hole in its container into an evacuated
space.
Graham’s law of effusion states that the rate of effusion
of a gas is inversely proportional to the square root of its
molar mass.

A lighter gas moves more quickly and therefore has a
higher rate of effusion than a heavier gas at the same T.
Rate of effusion

5-51

1

√M
Graham’s Law of Effusion
• In 1846, Thomas Graham concluded
that the rate of effusion of a gas is
inversely proportional to the square
root of its molar mass.
• Rate gas A / Rate Gas B = the
square root of mass of Gas B / mass
of Gas A.
5-52
Thomas Graham
• Chemist
•

5-53

(December 21, 1805 -September
16,1869) was born in Glasgow,
Scotland. He became a student at
the University of Glasgow in 1819.
There he developed a strong
interest in chemistry. He later
became a professor of chemistry
at numerous colleges. He is
known for developing Graham’s
law and his work with dialysis.

• Developed Dialysis
Figure 5.21

5-54

Effusion. Lighter (black) particles effuse faster than
heavier (red) particles.
Sample Problem 5.13

Applying Graham’s Law of Effusion

PROBLEM: A mixture of helium (He) and methane (CH4) is placed in an
effusion apparatus. Calculate the ratio of their effusion rates.

PLAN: The effusion rate is inversely proportional √M for each gas, so
we find the molar mass for each substance using its formula and
take the square root. The ratio of the effusion rates is the
inverse of the ratio of these square roots.
SOLUTION:

rate

rate

5-55

M of CH4 = 16.04 g/mol

He
CH4

=

√ 4.003
16.04

M of He = 4.003 g/mol

= 2.002
Sample Effusion Problems
• Calculate the ratio of effusion rates of
He and CH4.
• What is the ratio of the effusion rates
between H2 and UF6?
• What is the ratio of the effusion rates
between O2 and Kr?

5-56
5-57
5-58
Effusion Problems –
Unknown Molar Mass
• A sample of an unknown gas effuses
in 11.1 min. An equal volume of H2 in
the same apparatus at the same
temperature and pressure effuses in
2.42 min.
• What is the molar mass of the
unknown gas?
5-59
5-60
5-61
5-62

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  • 1. GASES II – Unit 11 • • • • 5-1 THEIR PROPERTIES AND BEHAVIORS Chapter 9.4-9.9 (McM) Chapter 5.4-5.6 Silberberg
  • 2. Chapter 5 Gases and the Kinetic-Molecular Theory 5-2
  • 3. Gases and the Kinetic Molecular Theory - II 5.4 Rearrangements of the Ideal Gas Law 5.5 The Kinetic-Molecular Theory: A Model for Gas Behavior 5.6 Real Gases: Deviations from Ideal Behavior 5-3
  • 4. Goals & Objectives • See the Learning Objectives on pages 217. • Understand these Concepts: • 5.5-12. • Master these Skills: • 5.4-5.7 5-4
  • 5. Application of the Gas Laws • • • • 5-5 Partial Pressures Collecting Gases over Water Densities of gases Combining Volumes
  • 6. Dalton’s Law of Partial Pressures • The total pressure exerted by a mixture of gases is the sum of the partial pressures of the individual gases. • Partial pressure(p) is the pressure a gas would exert if it occupied the volume alone. • PT = p1 + p2 + p3 + ……….. 5-6
  • 7. Figure 5.17 5-7 A molecular view of Dalton’s law
  • 8. Exercises • If 100 mL of hydrogen measured at 25 C and 3.00 atm pressure, and 100 mL of oxygen measured at 25 C and 2.00 atm pressure, are forced into one of the containers at 25 C, determine the pressure of the mixture of gases. 5-8
  • 9. 5-9
  • 10. 5-10
  • 11. Figure 5.12 5-11 Collecting a water-insoluble gaseous product and determining its pressure.
  • 12. Table 5.2 Vapor Pressure of Water (P H2O T(0C) T(0C) 0 5 10 12 14 16 18 20 22 24 26 28 30 35 5-12 P (torr) H2O 4.6 6.5 9.2 10.5 12.0 13.6 15.5 17.5 19.8 22.4 25.2 28.3 31.8 42.2 40 45 50 55 60 65 70 75 80 85 90 95 100 ) + at Different T P H2O (torr) 55.3 71.9 92.5 118.0 149.4 187.5 233.7 289.1 355.1 433.6 525.8 633.9 760.0
  • 13. Exercises • A sample of hydrogen was collected by displacement of water at 25 C . The atmospheric pressure was 748 torr. Determine the pressure exerted by dry hydrogen in this container. The vapor pressure of water at 25 C is 23.8 torr. 5-13
  • 14. 5-14
  • 15. 5-15
  • 16. Exercises • A sample of oxygen was collected by displacement of water. The mixture occupied 742 mL at 27 C. The barometric pressure was 753 torr. Determine the volume of dry oxygen under these conditions. The vapor pressure of water at 27 C is 26.7 torr. 5-16
  • 17. 5-17
  • 18. The Ideal Gas Law and Gas Density The density of a gas is - directly proportional to its molar mass and - inversely proportional to its temperature. m density = V PV = m V 5-18 and m M =d= moles = RT M xP RT m M
  • 19. Sample Problem 5.7 PROBLEM: Calculating Gas Density Find the density (in g/L) of CO2 (g) (a) at STP. PLAN: We can use the molar mass of CO2 to find its density from the ideal gas equation. SOLUTION: d= (a) At STP, or 273 K and 1.00 atm: M xP RT 44.01 g/mol x 1.00 atm = 0.0821 atm·L x 273 K = 1.96 g/L mol·K 1.96 g CO2 x 1 mol CO2 x 6.022 x 1023 molecules 1L 1 mol 44.01 g CO2 = 2.68 x 1022 molecules CO2/L 5-19
  • 20. Densities of Gases • Determine the density of a 25.9 g sample of He gas at 25 C and .989 atm. • (Molar mass of He = 4.00g/mol) 5-20
  • 21. 5-21
  • 22. 5-22
  • 23. Exercises • One (1.00) mole of a gas occupies 36.5 liters, and its density is 1.36 g/L at a given temperature and pressure. • Determine its molecular weight. • Calculate the density of this gas at STP. 5-23
  • 24. 5-24
  • 25. 5-25
  • 26. Molar Mass from the Ideal Gas Law n= m M M= 5-26 = PV RT mRT PV
  • 27. Molar Masses • A 250 mL flask contains 0.423 g of vapor at 100 C and 746 torr. Determine the density and molar mass of this compound. 5-27
  • 28. 5-28
  • 29. 5-29
  • 30. Exercises • A compound that contains only C and H is 80.0% C and 20.0% H by mass. At STP 546 mL of the gas has a mass of 0.732 g. Find the molecular formula for the compound. Molar masses: C, 12.0 g/mol; H, 1.0 g/mol 5-30
  • 31. 5-31
  • 32. 5-32
  • 33. Gay-Lussac’s Law of Combining Gas Volumes • The volumes of gases involved in a reaction bear a small whole-number relationship to each other. • This law applies only at constant temperature and pressure. • Gases combine in definite and simple proportions by volume. 5-33
  • 34. Gay-Lussac’s Law of Combining Gas Volumes • 4NH3(g) +5O2(g)=4NO(g)+6H2O(g) • 4 moles 5 moles 4 moles 6 moles • 4 mL 5mL 4mL 6mL • 4L 5L 4L 6L 5-34
  • 35. Gay-Lussac’s Law of Combining Gas Volumes • Determine the volume of NO that would be produced in the previous reaction if 25mL of NH3 reacts with 25mL of O2 if all gases are measured at the same temperature and pressure. Assume the reaction occurs until all of one reactant is consumed. 5-35
  • 36. 5-36
  • 37. 5-37
  • 38. The Ideal Gas Law and Stoichiometry P, V, T of gas A P, V, T of gas B Amount (mol) of gas A Amount (mol) of gas B Figure 15.13 The relationships among the amount (mol, n) of gaseous reactant (or product) and the gas pressure (P), volume (V), and temperature (T). 5-38
  • 39. Sample Problem 5.11 Using Gas Variables to Find Amounts of Reactants and Products I PROBLEM: What volume of H2 gas at 765 torr and 225 C is needed to reduce 35.5 g of copper(II) oxide to form pure copper and water? PLAN: Write a balanced equation. Convert the mass of copper (II) oxide to moles and find the moles of H2, using the mole ratio from the balanced equation. Calculate the corresponding volume of H2 using the ideal gas law. mass (g) of CuO divide by M mol CuO use mole ratio mol H2 volume of H2 ideal gas law 5-39
  • 40. Sample Problem 5.11 SOLUTION: CuO(s) + H2(g) → Cu(s) + H2O(g) 35.5 g CuO x 1 mol CuO x 1 mol H2 = 0.446 mol H 2 79.55 g CuO 1 mol CuO P = 765 torr x V= 5-40 nRT = P 1 atm = 1.01 atm 760 torr T = 225 C + 273.15 K = 498 K 0.446 mol H2 x 0.0821 1.01 atm atm·L x 498 K mol·K = 18.1 L H2
  • 41. Sample Problem 5.12 PROBLEM: PLAN: Using Gas Variables to Find Amounts of Reactants and Products II What mass of potassium chloride forms when 5.25 L of chlorine gas at 0.950 atm and 293 K reacts with 17.0 g of potassium metal? First we must write a balanced equation. Since the quantities of both reactants are given, we must next determine which reactant is limiting. We will use the ideal gas law to calculate the moles of Cl2 present. SOLUTION: The balanced equation is: Cl2(g) + 2K(s) → 2KCl(s) For Cl2: P = 0.950 atm V = 5.25 L T = 293 K n = unknown 5-41
  • 42. Sample Problem 5.12 n Cl2 = PV = RT 0.50 atm 0.0821 x atm·L mol·K 5.253 L x 293 K = 0.207 mol Cl2 2 mol KCl = 0.435 mol KCl 1 mol Cl2 For Cl2: 0.207 mol Cl2 x For K: 17.0 g K x 1 mol K x 2 mol KCl = 0.414 KCl 39.10 g K 2 mol K Cl2 is the limiting reactant. 0.435 mol KCl x 74.55 g KCl 1 mol KCl 5-42 = 30.9 g KCl
  • 43. Exercise • Determine the volume of O2, measured at STP, that can be produced by the thermal decomposition of 120g of KClO3. • 2KClO3(s) 2KCl(s)+3O2(g) 5-43
  • 44. 5-44
  • 45. 5-45
  • 46. The Kinetic-Molecular Theory: A Model for Gas Behavior Postulate 1: Gas particles are tiny with large spaces between them. The volume of each particle is so small compared to the total volume of the gas that it is assumed to be zero. Postulate 2: Gas particles are in constant, random, straight-line motion except when they collide with each other or with the container walls. Postulate 3: Collisions are elastic, meaning that colliding particles exchange energy but do not lose any energy due to friction. Their total kinetic energy is constant. Between collisions the particles do not influence each other by attractive or repulsive forces. 5-46
  • 47. Figure 5.14 Distribution of molecular speeds for N2 at three temperatures. 5-47
  • 48. Figure 5.15 5-48 Pressure arise from countless collisions between gas particles and walls.
  • 49. Kinetic Energy and Gas Behavior At a given T, all gases in a sample have the same average kinetic energy. 1 Ek = mass x speed2 2 Kinetic energy depends on both the mass and the speed of a particle. At the same T, a heavier gas particle moves more slowly than a lighter one. 5-49
  • 50. Figure 5.20 The relationship between molar mass and molecular speed. 5-50
  • 51. Graham’s Law of Effusion Effusion is the process by which a gas escapes through a small hole in its container into an evacuated space. Graham’s law of effusion states that the rate of effusion of a gas is inversely proportional to the square root of its molar mass. A lighter gas moves more quickly and therefore has a higher rate of effusion than a heavier gas at the same T. Rate of effusion 5-51 1 √M
  • 52. Graham’s Law of Effusion • In 1846, Thomas Graham concluded that the rate of effusion of a gas is inversely proportional to the square root of its molar mass. • Rate gas A / Rate Gas B = the square root of mass of Gas B / mass of Gas A. 5-52
  • 53. Thomas Graham • Chemist • 5-53 (December 21, 1805 -September 16,1869) was born in Glasgow, Scotland. He became a student at the University of Glasgow in 1819. There he developed a strong interest in chemistry. He later became a professor of chemistry at numerous colleges. He is known for developing Graham’s law and his work with dialysis. • Developed Dialysis
  • 54. Figure 5.21 5-54 Effusion. Lighter (black) particles effuse faster than heavier (red) particles.
  • 55. Sample Problem 5.13 Applying Graham’s Law of Effusion PROBLEM: A mixture of helium (He) and methane (CH4) is placed in an effusion apparatus. Calculate the ratio of their effusion rates. PLAN: The effusion rate is inversely proportional √M for each gas, so we find the molar mass for each substance using its formula and take the square root. The ratio of the effusion rates is the inverse of the ratio of these square roots. SOLUTION: rate rate 5-55 M of CH4 = 16.04 g/mol He CH4 = √ 4.003 16.04 M of He = 4.003 g/mol = 2.002
  • 56. Sample Effusion Problems • Calculate the ratio of effusion rates of He and CH4. • What is the ratio of the effusion rates between H2 and UF6? • What is the ratio of the effusion rates between O2 and Kr? 5-56
  • 57. 5-57
  • 58. 5-58
  • 59. Effusion Problems – Unknown Molar Mass • A sample of an unknown gas effuses in 11.1 min. An equal volume of H2 in the same apparatus at the same temperature and pressure effuses in 2.42 min. • What is the molar mass of the unknown gas? 5-59
  • 60. 5-60
  • 61. 5-61
  • 62. 5-62