Unit 10 Gases
Kinetic – Molecular Theory
• In order to understand gases you must understand the Kinetic Molecular Theory.
• The KMT assumes the following concepts about an ideal gas:
Kinetic- Molecular Theory
The kinetic-molecular theory explains the behavior of particles of matter. It has these five points:1. All matter is made of small particles (atoms
and molecules) that do have mass.2. For gases, distances between particles are
very large. (1,000x solids and liquids)
Kinetic-Molecular Theory
4. All collisions between particles are perfectly elastic. This means that there is no loss of energy OR in other words, the amount of total energy before the collision and after are equal.
5. The temperature of a substances is determined by the average kinetic energy of the particles.
Why? Important to understanding the properties of gases later
Kinetic-Molecular Theory
• We also typically assume for gases that 1) particles have no attractive forces between one another and 2) the volume of the particles is insignificant compared to the volume of gas.
Characteristics of Gases
• Gases expand to fill any container.– random motion, no attraction
• Gases are fluids (like liquids).– no attraction
• Gases have very low densities.– no volume = lots of empty space
Pressure
• Applies to fluids i.e. liquids and gases
• Because of their nature they exert pressure in all directions
• Gas pressure is the result of gas particles colliding with the walls of their container
Measuring Gas Pressure
• Barometer– measures atmospheric pressure
Mercury Barometer
Aneroid Barometer
Measuring Gas Pressure• Manometer
• measures contained gas pressure
U-tube Manometer Bourdon-tube gauge
Units of Pressure
• Atmospheres (atm)
• Millimeters Mercury (mmHg)
• Torr (Torr) Note: Torr is the same as mmHg
• kiloPascals (kPa)
• 760. mmHg(Torr) = 1.00 atm = 101.3 kPa
Conversion Practice
Convert each of the following into the other two pressure units.
A. 100. atm
B. 50.kPa
C. 200. mmHg
Temperature• Temperature is the average kinetic energy of the particles in a material.
• If temperature is the average kinetic energy of particles and kinetic energy is due to the particle motion, then there should be a temperature where all motion of particles stops. The temperature where all particle motion has stopped is called absolute zero. Absolute zero is at –273 oC.
Temperature
• We use absolute zero for the basis of a new temperature scale called the Kelvin (K) scale. In this scale the size of each degree is the same as the size of a Celsius degree.
• So if we know -273oC = 0 K and each degree is the same size, conversions are easy!
• K = oC + 273 oC = K - 273
So Why Use Kelvin?
• Note: We can never have a negative Kelvin temperature. (Ex. –5 K) Also, notice that we no longer use the degree symbol in the Kelvin scale. This is because " o " means the number is on a relative scale. The Kelvin is an absolute scale.
Conversion Practice
• Convert the following to the other temperature scale.
• a) 273 oC• b) 273 K • d) 173 oC • e) 542. K • g) 0 K
Gas Laws
• Standard temperature and pressure is abbreviated STP. Standard temperature is 0oC (or 273 K) and standard pressure is 1.00 atm, 760. mmHg, or 101.3 kPa.
• We use cm3, mL, or L to measure volume.
• Avogadro’s Law 1 mole of any gas at STP is 22.4L
Dalton’s Law of Partial Pressure
• Dalton's Law states that at constant volume and temperature, the total pressure exerted by a mixture of gases is equal to the sum of the partial pressures of each gas.
• Ptotal = PT = P1 + P2 + P3 .....
• Ex. What is the total pressure of a mixture of H2, Ne, and Ar if the pressure of the H2 is 41.1 kPa, the pressure of the argon is 37.2 kPa, and the pressure of the neon is 5.1 kPa? 83.4 kPa
Boyle’s Law – Pressure and Volume
• Boyle's Law states that at constant temperature, the pressure of a gas varies inversely with the volume.
• P1V1 = P2V2
• So what’s mean? When you raise pressure, volume decreases and vice versa. When you lower pressure, volume increases and vice versa.
Boyle’s Law – How can I remember?
• When you boil (Boyle) something, you produce a VaPor
• So Boyle’s Law deals with V and P
Problem #5
• If a child’s helium balloon has a volume of 2.45 L at 104 kPa and the child let’s go, when the balloon reaches an altitude where the pressure is 48.2 kPa what will be the volume of the balloon?
• P1V1 = P2V2
• So (2.45 L)(104 kPa) = V2 (48.2 kPa)
• 254.8 L*kPa = V2 (48.2 kPa)
• V2 = 5.2863 L
• After accounting for sig. fig. V2 = 5.29 L
Charles’ Law – Volume and Temperature
• Charles' Law states that at constant pressure, the volume of a gas varies directly with Kelvin temperature. Charles helped to formulate the absolute or Kelvin temperature scale.
• V1 = V2 or T1V2 = T2V1
T1 T2
• * When calculating any gas law problem using temperature, it must be in Kelvin.
Gay – Lussac’s Law – Pressure and Temperature
• According to this law, at constant volume, the pressure of a gas varies directly with Kelvin temperature.
• P1 = P2 T1P2 = T2P1
T1 T2
• How can I remember? It’s not the other two
GIVEN:
P1 = 765 torr
T1 = 23°C = 296K
P2 = 560. torr
T2 = ?
WORK:
P1V1T2 = P2V2T1
Gas Law Problems• A gas’ pressure is 765 torr at 23°C. At what
temperature will the pressure be 560. torr?
P T
(765 torr)T2 = (560. torr)(296K)
T2 = 216.68 K = -56°C
Example: Gay-Lussac’s Law
The gas in an aerosol can is at a pressure of 3.00 atm at 25°C. Directions on the can warn the user not to keep the can in a place where temperature exceeds 52°C. What would the gas pressure be in the can at 52°C?
Combined Gas Law
•Boyle’s, Charles’s and Gay-Lussac’s laws can be combined into a single law.
•The combined gas law states the relationship among pressure, volume, and temperature of a fixed amount of gas
Combined Gas Law
• Boyle's, Charles', and G - L Laws can be combined into one gas law called the Combined Gas Law.
• P1 V1 = P2 V2
T1 T2
• or P1T2V1 = P2T1V2
• How can I remember? It’s the only that combines P, V and T
Example: Combined Gas Law
• A Helium-filled balloon has volume of 50.0 L at 25°C and 1.08 atm. What volume will it have at 0.855 atm and 10.°C?
GIVEN:
V1 = 7.84 cm3
P1 = 71.8 kPa
T1 = 25°C = 298 K
V2 = ?
P2 = 101.325 kPa
T2 = 273 K
WORK:
P1V1T2 = P2V2T1
(71.8 kPa)(7.84 cm3)(273 K)
=(101.325 kPa) V2 (298 K)
V2 = 5.09 cm3
Gas Law Problems• A gas occupies 7.84 cm3 at 71.8 kPa &
25°C. Find its volume at STP.
P T V
GIVEN:
V1 = 473 cm3
T1 = 36°C = 309K
V2 = ?
T2 = 94°C = 367K
WORK:
P1V1T2 = P2V2T1
Gas Law Problems• A gas occupies 473 cm3 at 36°C. Find its
volume at 94°C.
T V
(473 cm3)(367 K)=V2(309 K)
V2 = 562 cm3
GIVEN:
V1 = 100. mL
P1 = 150. kPa
V2 = ?
P2 = 200. kPa
WORK:
P1V1T2 = P2V2T1
Gas Law Problems• A gas occupies 100. mL at 150. kPa. Find its
volume at 200. kPa.
P V
(150.kPa)(100.mL)=(200.kPa)V2
V2 = 75.0 mL
kn
VV
n
Avogadro’s Principle• Equal volumes of gases contain equal
numbers of moles– at constant temp & pressure– true for any gas
PV
TVn
PVnT
Ideal Gas Law
= k
UNIVERSAL GAS CONSTANT
R=0.0821 Latm/molK
= R
Merge the Combined Gas Law with Avogadro’s Principle:
Ideal Gas Law
• The Ideal Gas Law says that for an ideal gas pressure, volume, moles, and Kelvin temperature of particles are all related.
• P V = n R T
• P is the pressure in atmospheres• V is the volume in Liters• n is the number of moles• T is the temperature in Kelvin• R = 0.0821 L . atm mole . K
GIVEN:
P = ? atm
n = 0.412 mol
T = 16°C = 289 K
V = 3.25 L
R = 0.0821Latm/molK
WORK:PV = nRT P=nRT
V
P=(3.25)=(0.412)(0.0821)(289) L mol Latm/molK K _____________________
3.25L
P = 3.01 atm
Ideal Gas Law Problems• Calculate the pressure in atmospheres of 0.412
mol of He at 16°C & occupying 3.25 L.
GIVEN:V = ?
n = 85 g
T = 25°C = 298 K
P = 104.5 KPa=1.03atm
R = 0.0821atm-L/molK
Ideal Gas Law Problems• Find the volume of 85 g of O2 at 25°C and
104.5 kPa.
= 2.7 mol
WORK:
85 g 1 mol = 2.7 mol
32.00 g
PV = nRT(1.03)V=(2.7) (0.0821) (298) atm mol atm-L/molK K
V = 64 L
Ideal Gas LawRemember: • Something is ideal if it conforms perfectly to a set of conditions.•Although ideal gases do not exist, the ideal gas law can be used to describe real gases under normal conditions.
• When does the ideal gas law not apply?
1. Under very high pressures – volume becomes so small that the volume of gas particles become significant.
2. Under very low temperatures – gas no longer have enough kinetic energy to overcome attractive forces
Ideal Gas Law Variations
• We know the molar mass is grams of substance per mole of substance or MM = m/n
• So n = m / MM
• Substituting in we get PV = (m/MM)RT
• Bring MM up to the other side finally gives us: P V MM = m R T
Ideal Gas Law Variations
• We also know the density of a substance is its mass divided by its volume, or D = m/V
• Start with P V MM = m R T
• Divide V over and you get P V = (m/V) R T
• And you end up with: P MM = D R T
A Note About Kinetic Energy
• We’ve said that temperature is related to average kinetic energy and that gases at the same temperature have the same average kinetic energy
• The equation for kintetic energy is: KE = ½ m(v)2
• Bottom line: at the same temperature, gases have the SAME kinetic energy, but DIFFERENT SPEEDS
Diffusion
• Diffusion– Spreading of gas
molecules throughout a container until evenly distributed.
– Movement toward lower concentration
• Effusion– Passing of gas molecules
through a tiny opening in a container
Diffusion of gases
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Effusion of a Gas
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Graham’s Law• Graham’s Law
– Rate of diffusion of a gas is inversely related to the square root of its molar mass.
– The equation shows the ratio of Gas A’s speed to Gas B’s speed.
A
B
B
A
m
m
v
v
• Determine the relative rate of diffusion for krypton and bromine.
1.381
Kr diffuses 1.381 times faster than Br2.
Kr
Br
Br
Kr
m
m
v
v2
2
A
B
B
A
m
m
v
v
g/mol83.80
g/mol159.80
Graham’s Law
The first gas is “Gas A” and the second gas is “Gas B”. Relative rate mean find the ratio “vA/vB”.
• A molecule of oxygen gas has an average speed of 12.3 m/s at a given temp and pressure. What is the average speed of hydrogen molecules at the same conditions?
A
B
B
A
m
m
v
v
2
2
2
2
H
O
O
H
m
m
v
v
g/mol 2.02
g/mol32.00
m/s 12.3
vH 2
Graham’s Law
3.980m/s 12.3
vH 2
m/s49.0 vH 2
Put the gas with the unknown
speed as “Gas A”.