Presentation is loading. Please wait.

Presentation is loading. Please wait.

I.Dalton’s Law A.The total pressure of a mixture of gases equals the sum of the pressures each gas would exert independently 1.P total = P 1 + P 2 + …

Published byAnya Borum Modified over 9 years ago

Similar presentations

Presentation on theme: "I.Dalton’s Law A.The total pressure of a mixture of gases equals the sum of the pressures each gas would exert independently 1.P total = P 1 + P 2 + …"— Presentation transcript:

1 I.Dalton’s Law A.The total pressure of a mixture of gases equals the sum of the pressures each gas would exert independently 1.P total = P 1 + P 2 + … 2.Partial pressures is the pressure a gas in a mixture would exert if it were alone in the container 3.Particularly useful for determining the pressure a dry gas collected over water: P total = P wet gas = P gas + P water 4.P water vapor depends on the temperature, look up in table B.Combining Dalton’s Law and Ideal Gases 1.We can assume each gas will behave ideally in the mixture 2.It’s the total number of particles present that is important a.The volume of the individual particle is very small b.The forces among particles are very small

2 C.Problems 1.Example: 46L He and 12L O 2 at 25 o C and 1atm are pumped into a 5.0L tank. What are the partial and total pressures? a.Calculate the number of moles of each gas from the ideal gas law b.Calculate partial pressures of each gas from new conditions c.Add partial pressures: 9.3atm + 2.4atm = P tot = 11.7atm 2.Mole fraction =  1 = moles of molecule 1 divided by moles total

3 3. Example: Find  O2 if P O2 = 156torr in air at P T = 743torr. a.  O2 = P O2 /P T = 156torr/743torr = 0.210 b.21% of the air molecules are oxygen 4. Example: Calculate P N2 if  N2 is 0.7808 when P T = 760torr. P N2 =  N2 x P T = (0.7808)(760torr) = 593torr 5.Example: 0.650L of gas at 22 o C is collected over water in the decomposition reaction of KClO 3. Calculate P O2 in this gas and the amount of KClO 3 in the reaction. P H2O = 21torr at 22 o C. P T = 754 torr a.2KClO 3 (s) -------> 2KCl(s) + 3O 2 (g) b.Find P O2 from Daltons Law: P O2 = P T – P H2O = 754-21 = 733torr c.Use ideal gas law to find moles O 2 d.Calculate moles KClO 3 needed to make this O 2.

4 II.The Kinetic Molecular Theory of Gases A.Empirical Laws 1.Gas Laws we have just studied 2.Describe how gases behave, but don’t explain why they behave that way B.Theory or Model 1.Explains why gases behave as they do 2.Describing an Ideal Gas with the Kinetic Molecular Theory (KMT) a.Gas particles very small compared to distance between them (assume gas molecules have no volume) b.Molecules constantly and rapidly move in a straight line until they bump into each other or the wall (this causes pressure) c.Assume that the gas molecules’ attraction for each other is negligible d.Average kinetic energy is proportional to the temperature (K) 3.Real gas molecules do have volumes, do attract each other C.Test: can the theory predict the experimental observations of PV = nRT? 1.Pressure is inversely proportional to Volume (Boyle’s Law) a.KMT: Decrease in Volume means particles hits wall more often b.This results in an increase in Pressure

5 2.Pressure is directly proportional to Temperature a.KMT: As temperature increases, gas speed increase b.Pressure increases as the collisions with the wall are harder 3.Volume is directly proportional to Temperature (Charles’s Law) a.KMT: As temperature increases, gas speed increase b.If pressure is to remain the same, the volume must increase 4.Volume is directly proportional to number of moles (Avogadro’s Law) a.KMT: As moles increases, more collisions with the walls occur b.If pressure is to remain the same, the volume must increase

6 5.Mixtures of Gases (Dalton’s Law) a.KMT: Identity of the gas molecule doesn’t change (ideal) properties b.Adding another gas increases pressure same as adding first gas D.Ideal Gas Law—Derivation from KMT 1.Physics (N A = Avogadro’s number, m = mass of particle,  = velocity) 2. KMT: average KE is directly proportional to T(K) E.The Meaning of Temperature 1.KMT: average KE is directly proportional to T(K) 2.

7 F.Root Mean Square Velocity 1.Root mean square velocity =  rms 2.Deriving an expression for  rms a. b. c. 3. Example: Calculate  rms for He at 25 o C.

8 4.Range of velocities of a gas sample a.Mean free path = avg. dist. between collisions ~ 1 x 10 -7 m at STP b.Many collisions produce large range of velocities c.500 m/s ~  rms at STP, but velocities are widely ranging d.Temperature greatly effects the distribution (KMT) G.Effusion and Diffusion 1.Effusion = movement of gas into vacuum through a small opening a.Example: Find ratio of effusion rate for H 2 and UF 6. b.Graham’s Law:

9 2.KMT: effusion depends on average velocity of the gas particles 3.Diffusion = mixing of gases a.NH 3 (g) + HCl(g) -------> NH 4 Cl(s) b.Expected speed of mixing would allow estimation of distances: c.Multiple collisions with air gases complicate the model of diffusion d.The ratio of distance traveled is < 1.5; mixing time is several minutes

10 H.Real Gases 1.No gas is ideal, although most are close at low P and high T 2.Where does the KMT fail in describing Real Gases? 3.For an ideal gas, PV/nRT = 1 at all pressures and temperatures 4.Modifying the Ideal Gas Law a.Real gas molecules have volume, which reduces the Volume available b.An empirical constant b for each gas is determined 203 K

11 c.Real gas molecules attract each other, making P obs < P’ d.The higher the concentration of particles, the larger the effect e.The number of interacting pairs depends on (concentration) 2 i.N particles has N-1 partners ii.Divide by 2 to eliminate counting each pair twice f.The correction for V and P combine in van der Waals equation g.a and b are varied until the best fit of observation is found h.Low pressure = large volume, where volume of particles is negligible i.High temperature = fast motion, where attractions are negligible

12 III.Atmospheric Chemistry A.Components: N 2 = 78%, O 2 = 21%, Ar, CO 2, less than 1%, H 2 O is variable B.Smog Production in the lower atmosphere 1.Burning fossil fuels produces NO x = NO and NO 2 2.NO 2 + light -------> NO + O 3.O + O 2 -------> O 3 ------> O 2 + O* (high energy O atom) 4.O* + H 2 O -------> 2OH radicals 5.OH + NO 2 -------> HNO 3 (nitric acid) 6.OH + hydrocarbons -------> photochemical smog 7.Prevalent in urban areas; harmful to respiratory system 8.Combated by public transportation, cleaner burning fuels C.Acid Rain 1.S(in coal) + O 2 -------> SO 2 2.2SO 2 + O 2 -------> SO 3 3.SO 3 + H 2 O -------> H 2 SO 4 (sulfuric acid) 4.Harmful to buildings and organisms 5.Need to remove sulfur from coal (Scrubbing) a.CaCO 3 -------> CaO + CO 2 b.CaO + SO 2 -------> CaSO 3 (solid calcium sulfite)

Download ppt "I.Dalton’s Law A.The total pressure of a mixture of gases equals the sum of the pressures each gas would exert independently 1.P total = P 1 + P 2 + …"

Similar presentations

Chapter 5: GASES Part 2.

Chapter 5: GASES Part 2.
Any Gas….. 4 Uniformly fills any container 4 Mixes completely with any other gas 4 Exerts pressure on its surroundings.

Any Gas….. 4 Uniformly fills any container 4 Mixes completely with any other gas 4 Exerts pressure on its surroundings.
GASES! AP Chapter 10. Characteristics of Gases Substances that are gases at room temperature tend to be molecular substances with low molecular masses.

GASES! AP Chapter 10. Characteristics of Gases Substances that are gases at room temperature tend to be molecular substances with low molecular masses.
Gases Chapter 13 Pg. 372-402 Goal To learn about the behavior of gases both on molecular and macroscopic levels.

Gases Chapter 13 Pg Goal To learn about the behavior of gases both on molecular and macroscopic levels.
A.P. Chemistry Chapter 5 Gases Part 2. Van der Waal’s Equation: (p. 222-224) Due to deviation from ideal behavior, corrections (adjustments) are made.

A.P. Chemistry Chapter 5 Gases Part 2. Van der Waal’s Equation: (p ) Due to deviation from ideal behavior, corrections (adjustments) are made.
Chapter 5: Gases Pressure KMT Gas Laws Effusion and Diffusion

Chapter 5: Gases Pressure KMT Gas Laws Effusion and Diffusion
The Gaseous State Chapter 12 Dr. Victor Vilchiz.

The Gaseous State Chapter 12 Dr. Victor Vilchiz.
The Gaseous State Chapter 5.

The Gaseous State Chapter 5.
Chapter 11 Gases Copyright McGraw-Hill 2009 1.

Chapter 11 Gases Copyright McGraw-Hill
Chapter 10 Gases No…not that kind of gas. Kinetic Molecular Theory of Gases Kinetic Molecular Theory of Gases – Based on the assumption that gas molecules.

Chapter 10 Gases No…not that kind of gas. Kinetic Molecular Theory of Gases Kinetic Molecular Theory of Gases – Based on the assumption that gas molecules.
Mixtures of Gases Dalton's law of partial pressure states: –the total pressure of a mixture of gases is equal to the sum of the partial pressures of the.

Mixtures of Gases Dalton's law of partial pressure states: –the total pressure of a mixture of gases is equal to the sum of the partial pressures of the.
Gases. Dalton’s Law of Partial Pressure Named in honor of English scientist John Dalton. He stated that gases mix homogeneously. He also said that each.

Gases. Dalton’s Law of Partial Pressure Named in honor of English scientist John Dalton. He stated that gases mix homogeneously. He also said that each.
Chapter 5 The Gas Laws. Pressure  Force per unit area.  Gas molecules fill container.  Molecules move around and hit sides.  Collisions are the force.

Chapter 5 The Gas Laws. Pressure  Force per unit area.  Gas molecules fill container.  Molecules move around and hit sides.  Collisions are the force.
Chapter 12 Gas Laws.

Chapter 12 Gas Laws.
Do Now: What is KMT, Kinetic Molecular Theory

Do Now: What is KMT, Kinetic Molecular Theory
Daniel L. Reger Scott R. Goode David W. Ball Chapter 6 The Gaseous State.

Daniel L. Reger Scott R. Goode David W. Ball Chapter 6 The Gaseous State.
Gases Chapter 12 pp. 470-508. General properties & kinetic theory Gases are made up of particles that have (relatively) large amounts of energy. A gas.

Gases Chapter 12 pp General properties & kinetic theory Gases are made up of particles that have (relatively) large amounts of energy. A gas.
1 Chapter 5 The Gas Laws. 2 Pressure n Force per unit area. n Gas molecules fill container. –Molecules move around and hit sides. –Collisions are the.

1 Chapter 5 The Gas Laws. 2 Pressure n Force per unit area. n Gas molecules fill container. –Molecules move around and hit sides. –Collisions are the.
Properties of Gases Important properties of a Gas Quantity n = moles

Properties of Gases Important properties of a Gas Quantity n = moles
Gases- Part 2 Gas Stoichiometry Dalton’s Partial Pressure Kinetic Molecular Theory Effusion and Diffusion Real Gases.

Gases- Part 2 Gas Stoichiometry Dalton’s Partial Pressure Kinetic Molecular Theory Effusion and Diffusion Real Gases.

Similar presentations

Ads by Google