Notes gas laws
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Transcript of Notes gas laws
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Warm up
What is pressure?– How does it interact with the states of matter?
How does it affect our lives?– Give some examples of pressure from our every
day life.
Homework tonight. – 13-1 Practice problems 1-7
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Introduction
Inflate a balloon and tie off the end. Use a string to measure the
circumference of the balloon. Take turns constantly submerging the
balloon in the water for approximately 15 minutes
Measure the circumference again Compare the two measurements
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Gas Laws
Charles, Boyle, Gay-Lussac, Combined and The Ideal Gas Law
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The Nature of a Gas:
have mass easy to compress have low densities fill containers completely diffuse quickly (move through each) exert pressure (depends on temperature)
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Kinetic-Molecular Theory (KMT) describes the behavior of gases
A gas consists of very small particles The distances between gas particles are
relatively large. Gas particles are in constant, random motion. Collisions between gas particles are perfectly
elastic. Average KE of particles depends only on the
temperature of the gas. There is no attractive force between particles
of a gas.
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Variables That Effect Gases Moles (n) – the amount of gas. Volume (V) – the size of the container that
holds the gas in liters (L). Temperature (T) – the speed or kinetic energy
of the particles in kelvin (oC +273) Pressure (P) – The outward push of gas
particles on their container in atmospheres (atm) or millimeters of mercury (mm Hg) or pounds per square inch (psi)
*Think of pressure as the number of collisions between gas particles and their container.
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if P increases, V decreases If P decreases, V increases
If T increases, V increases if T decreases, V decreases
If P increases, T increases if P decreases, T decreases
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STP – Standard Temperature Pressure
The behavior of a gas depends on its temperature and the pressure at which the gas is held.
So far we have only dealt with gases at STP. Standard Temperature and Pressure.
• 273 kelvins and 1 atm.
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The Gas Laws
Boyle’s Law Charles’s Law Gay-Lussac’s Law The Combined Gas Law The Ideal Gas Law
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Boyle’s Law The Pressure-Volume Relationship The pressure and volume of a sample
of gas at constant temperature are inversely proportional to each other.
(As one goes up, the other goes down) P1V1 =P2V2
If 3 of the variables are known, the fourth can be calculated.
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Boyle’s Law
The gas in a 20.0mL container has a pressure of 2.77atm. When the gas is transferred to a 34.0mL container at the same temperature, what is the new pressure of the gas.
P1V1 =P2V2
2
112
VVP
P mLatmmL
P0.34
)77.2(0.202
atmP 63.12
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Boyle’s Law So, does it make sense? If a set amount of gas is transferred into
a larger container, would the pressure go up or down?
Would there be more collisions, or fewer collisions with the container holding the gas?
More volume (space) means fewer collisions with the container, therefore pressure goes down. (From 2.77 atm to 1.63 atm)
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Charles’s Law
The temperature-volume relationship At constant pressure, the volume of a
fixed amount of gas is directly proportional to its absolute temperature.
2
2
1
1
TV
TV
If 3 of the variables are known, the fourth can be calculated.
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Charles’s Law
What will be the volume of a gas sample at 355K if its volume at 273K is 8.57L?
2
2
1
1
TV
TV
1
212
TTV
V
kelvinkelvinL
V273
)355(57.82
LV 1.112
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Charles’s Law Does it make sense? If the temperature of a given quantity of
gas is increased, what will happen to the volume it occupies? (In an elastic container?)
Gas particles moving faster would have more collisions with the container and exert more force to enlarge the volume of the elastic container.
In this case, from 8.57L to 11.1L.
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Gay-Lussac’s Law
The Temperature-Pressure Relationship If a volume of a sample of gas remains
constant, the temperature of a fixed amount of gas is directly proportional to its pressure.
2
2
1
1
TP
TP
If you know 3 of the variables, you can calculate the 4th.
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Gay-Lussac’s Law
The gas left in a used aerosol can is at a pressure of 2.03atm at 25oC. If this can is thrown onto a fire, what is the pressure of the gas when its temperature reaches 928oC?
2
2
1
1
TP
TP
1
212
TTP
P
KKatm
P298
)1201(03.22
atmP 18.82
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Gay-Lussac’s Law
Does it make sense? If the temperature of a fixed amount of
gas goes up, the particles will have more collisions. More collisions means the pressure will increase.
In this case, when the temp went up the pressure increased from 2.03atm to 8.18atm.
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The Combined Gas Law
If more than one variable changes, a different equation is needed to analyze the behavior of the gas.
2
22
1
11
TVP
TVP
5 of the variables must be known to calculate the 6th.
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The Combined Gas Law
The volume of a gas-filled balloon is 30.0L at 40oC and 1.75atm of pressure. What volume will the balloon have at standard temperature and pressure?
2
22
1
11
TVP
TVP
12
2112
TPTPVV
)313(00.1)273)(75.1(0.30
2KatmKatmLV
LV 8.452
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The Combined Gas Law Does it make sense? You have a fixed volume of gas. The
temperature decreases which would cause fewer collisions and the pressure decreases which causes fewer collisions as well. What can you do to volume to make the pressure decrease???
Increase it. More space means fewer collisions.
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The Ideal Gas Law Describes the physical behavior of an
ideal gas in terms of the pressure, volume, temperature and the number of moles of gas.
Ideal – a gas as it is described by the kinetic-molecular theory postulates.
All gases are REAL gases… which behave like ideal gases only under most ordinary conditions.
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The Ideal Gas Law
Only at very low temperatures and very high pressures do real gases show significant non-ideal behavior.
We will assume that gases are close to ideal and that the ideal gas equation applies.
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Ideal Gas Equation
PV=nRT P-pressure V-volume n-number of moles of gas R-ideal gas constant (universal gas constant)
0.0821 atm.L/mol.K
or 62.396 torr.L/mol.K T-temperature
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Ideal Gas Equation
What is the volume occupied by 9.45g of C2H2 at STP?
nRTPV
PnRT
V
First, calculate amountof gas in moles.
22
2222 03788.26
145.9 HgC
HmolCHgCn
223629328.0 HmolCn
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Ideal Gas Law
LV 1345217.8
LV 13.8
PnRT
V
atmkKmolLatmmol
V00.1
273)/0821.0(3629328.0
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Ideal Gas Law
How many moles of a gas at 100oC does it take to fill a 1.00L flask to a pressure of 1.5atm?
RTPV
n
nRTPV
)373(/0821.0)00.1(5.1
kKmolLatmLatm
n
moln 0490.0
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Lifting Power of Gases
For a gas to be used to inflate lighter-than-air craft like balloons and blimps, the gas must have a density lower than air.
The lower the density, the greater the lifting power.
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Lifting Power of Gases
The density of a gas depends on its pressure, temperature and molar mass.
Each of these variables is part of the ideal gas law.
Therefore, we should be able to adjust each of these variables to give low density.
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Lifting Power of Gases
However, if the pressure of the gas within a balloon or blimp were significantly less than the atmospheric pressure, the balloon or blimp would be crushed.
Therefore, only two factors can be manipulated to lower the density of a gas: molar mass and temperature
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Molar Mass
Gases with low density can be corrosive, combustible, flammable or chemically active in some way. These gases would make poor choices to fill blimps and balloons.
Helium, due to its small molar mass and chemical inactivity is the primary choice for balloons and blimps.
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Temperature Helium is relatively rare and very
expensive, so hot air is often preferable. As the temperature of a gas is
increased, the particles increase the number of collisions and increase the pressure inside the balloon. The volume of the balloon increases and becomes less dense and rises.
Hot air does not have the same lifting power as helium, but it is much cheaper.
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Gas Effusion The movement of atoms or molecules
through a hole so tiny that they do not stream through but instead pass through one particle at a time.
Explains why helium balloons deflate slowly over a period of a few hours.
The lower the mass of the gas, the greater the speed of its particles.
Hydrogen effuses faster than helium. Helium effuses faster than oxygen.
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New instructions
Hypothesize a graph to represent– P vs. V– V vs. T– T vs. P