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The gas laws

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Title: The gas laws

1
The gas laws

Chapter 5 of AP chemistry

2
Gasses

We are surrounded by gasses.
We would die if we were released into space where
there is no gas pressure
Because much of early chemistry involved
observations of gas behavior, there are many
different units of pressure

3
Early measurements of pressure

Pressure was first measured with a meter long
tube filled with mercury.
This was the first barometer.
Ill explain how it works.

4
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5
Units of pressure

The standard unit of pressure here in the States
is the atmosphere (atm)
1 atm 760 mm Hg
760 torr
101,325 Pa (Pascal)
14.7 PSI (pound per square inch)
1.01325 bar

6
Boyles law

Boyle found that the pressure and the volume of a
gas are inversely proportional.
This makes perfect sense. If you crush a plastic
bottle with the top on, what happens to the
pressure in the bottle?
Lets look at the graph.

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8
The equation

PVK
This law states that the product of pressure and
volume will be a constant value
This leads to a more useful equation
P1V1KP2V2
OR
P1V1P2V2

9
Charless law

Jacques Charles determined that the temperature
and the volume of a gas had a directly
proportional relationship.
Again this makes sense. When you heat up a gas
the particles move faster and they expand their
container (if they can).
Well look at a graph.

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11
Absolute Zero

Charles did his work in the late 1700s, well
before modern refrigeration.
He did note that all his separate gasses shared a
common x-intercept on the graph
That x-intercept represented the temperature at
which all substances would occupy zero volume,
absolute zero.

12
Absolute Zero -273.15 C
13
Kelvins

Whenever temperature is present in gas law
calculations it should be expressed in Kelvins.
C 273 K
IMPORTANT When your temperature increases from
25 C to 50 C it DID NOT double!!!!!!!!!!!!!!!!!!
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!

14
25 C to 50 C

25 C 273 25 298 K
50 C 273 50 323 K
298 K to 323 K is not a doubling of temperature.
NEVER EVER use C in gas law problems unless
youre looking up vapor pressure or something
else on a chart.

15
The equation

The useful equation from Charless law is
This equation can be combined with Boyles law to
form the combined gas law

16
The combined gas law

So far we have two equations

These two can be combined to form the combined
gas law

17
Example problems

A helium-filled balloon has a volume of 50.0 L at
25 C and 1.08 atm. What volume will it have at
0.885 atm and 10.0 C?
A hydrogen-filled zeppelin used on bombing
missions in WW I had a volume of 4550 m3 at 25 C
and 1.00 atm. What volume will it have if it
flies into a low pressure zone with a pressure of
0.95 atm and 20.0 C?

18
Example problems

A 500 mL water bottle filled with air at 25 C is
at a pressure of 0.877 atm. What pressure would
result if the volume is reduced to 300 mL and the
temperature is raised to 37 C?
A balloon filled with nitrogen gas is placed in a
freezer at 0 C, and 1 atm. The balloon has a
volume of 255 mL in the freezer. Once it is
removed from the freezer it is placed in warm
water where it warms to the temperature of the
water and it expands to a volume of 400 mL, and
as a result, the pressure on the balloon is also
increased to 2.5 atm? What is the final
temperature of the balloon? Whats wrong with
this problem?

19
Avogadros law

Avagadro found that for a gas at constant
temperature and pressure, the volume is directly
proportional to the number of moles of gas.
This is written as

Where V is volume and n is the number of moles,
and K is a constant.

20
Ramifications

It may seem strange but all gasses occupy the
same volume if they are under the same pressure
and temperature.
UF6 has a molar mass of over 300 g/mol yet a mole
of it occupies the same volume as a mole of H2
which has a molar mass of just over 2 g/mol.
Well get into how later.

21
Example

Suppose we have a 12.2-L sample containing 0.50
mol oxygen gas (O2) at a pressure of 1 atm and a
temperature of 25 C. If all this O2 were
converted to ozone (O3) at the same temperature
and pressure, what would be the volume of the
ozone?

22
Solution
Given V1 12.2 L, 0.5 mol O2 Want V2 Need Mol
O3 Will use

1) Write the equation

2) Determine moles of O3 produced
3) Solve Avogadros law
23
Example problem

If 1 mole of water vapor occupies 30.0 liters at
a given pressure and temperature, what volume
would be occupied by a mole of water if it were
decomposed into hydrogen and oxygen gas?
What are you Given? What do you want? What do you
need? What will you use?

24
The ideal gas law

PVnRT Do you remember me???
Well look at the laws that weve studied so far

R is the gas constant
25
PVnRT

This is the catch all gas law. This law
incorporates all the other gas laws into one nice
neat equation.
This law should be applies when mass, or number
of moles of gas is mentioned.
As always, there are easy problems and there are
hard problems
PS Were always going to put pressure in atm
from now on.

26
Easy problems

A 5.00 mole sample of argon is put in a steel
tank with a volume of 100. L. Once the gas fills
the container the temperature is found to be 25
ºC. If the container is opened, would air from
the outside world be sucked in or pushed out?
How many moles would be sucked in or pushed out?

27
Easy problems

Givens
n 5.00 mole
V 100. L
T 25 ºC
R 0.08206
P ???
If the P lt 1 atm, are is sucked in, if P gt then
argon is pushed out.

28
Plug and chug

Givens
n 5.00 mole
V 100. L
T 25 ºC?298K
R 0.08206
P ???

When the container argon will be pushed out of
the container so as to equalize the pressure.

29
A little harder problem

How much argon will be pushed out?
Lets think about this. What will happen to the
pressure in the tank once the tank is opened to
the outside world?
It will equalize with the pressure outside the
tank.
How will it accomplish this?
It will release some of the gas (moles)

30
Set up

P2 1.00 atm
V2 100. L
T2 298K
R 0.08206
n2 ???

P1 1.22 atm
V1 100. L
T1 298K
R 0.08206
n1 5.00

A lot of stuff cancels.

31
Plug and chug

You started with 5.00 mol and ended with 4.10
mol.
You she 0.90 mol of argon. You can convert that
to grams if youre asked to

32
Alternatively

You could also simply apply the ideal gas law to
the new container
Givens
P1.00atm
V100. L
T298 K
R0.08206
n???

33
? ? Gas Stoichiometry ? ?

What can we now calculate using the ideal gas
law?
Now we can do stoichiometry

MOLES!!!
34
Sample problem

Two chambers are mixed. The first occupies a
volume of 25.0 L and contains ethane gas (C2H6)
under 2.00 atm of pressure and a temperature of
20.0 ºC.
The second chamber is three times as large as the
first and contains oxygen at STP (standard
temperature and pressure, 0 ºC, and 1 atm know
this).
The gases are mixed, a spark is lit, the whole
thing explodes in a massive combustion reaction,
but the container is undamaged. The container is
cooled to 0 ºC. What is the pressure in the
container?
Write and balance the equation, find moles of
each reactant, determine the limiting reagent and
calculate the moles of CO2 produced. You have T,
V, and n. Solve for P

35
A note on chemical reactions

Decomposition of carbonates
The carbonate ion (CO32-) forms ionic bonds with
many metals.
When these metals are heated the carbonate ion
breaks down into the metal oxide and carbon
dioxied gas.
Heres the example of copper (II) carbonate

36
Well work a problem

A carbonate has an unknown metal cation. You
find that upon thermal decomposition of 57.3705g
of the carbonate 10.25 L of carbon dioxide can be
collected at STP.
What mass of metal oxide would be left behind?

First convert L of CO2 to moles
Next find the mass of CO2 and subtract it from
the original mass of the carbonate. Done!

38
Lets make it harder

As you will soon see in lab, a metal oxide can be
liberated from its oxygen by heat in an
atmosphere of hydrogen or methane gas.
If upon liberation of the oxygen in a hydrogen
atmosphere 8.244g of water are produced. If I
tell you that the oxygen and the metal exist in a
11 ratio, what metal do you have?

First you must find the mass of oxygen lost. For
that you need moles of oxygen.

You now know the mass of the oxide and the mass
of oxygen. So you can solve for the mass of the
metal.
37.24g(mass of MO) -7.32g (mass of oxygen)
Mass of metal in oxide 29.92g

40
The end at last

If you know the mass of the metal and you know
that the metal and oxygen exist in a 11 ratio in
the oxide you have all you need.

We know that the metal and water will be produced
in equal molar quantities. Thus we know the mass
and the mole of metal. So we solve for the molar
mass.

41
Molar mass of a gas

If you know the density of a gas you can find its
molar mass.
Recall Dmass/V
Also recall PVnRt
Forget not MMmass/n
See pg 205 for more

42
This is a useful trick

A gas is found to have a density of 2.68 g/L at a
temperature of 27 ºC under 1.50 atm of pressure.
Whats its molar mass?

43
Daltons law of partial pressures

This law states that the total pressure is equal
to the sum of all its parts. This may seem
obvious but, it is very useful.
The equation is below

44
More Dalton

Well look at a former students work.
He did a good job.

45
Those are basic problems

The problems get harder. Here you go.
Aluminum will react with hydrochloric acid to
produce aluminum chloride and hydrogen gas. If
the reaction takes place at a temperature is 20.0
ºC and a pressure is 752 torr, what mass of
aluminum would be required to produce 20.00 L of
gas if collected by water dispacement.
Vapor pressure of water at 20.0 ºC is 17.54 torr.