Presentation is loading. Please wait.

Presentation is loading. Please wait.

Mixtures of Gases, Partial Pressure, Gases in Chemical Reactions & KMT

Published byMaximilian Melton Modified over 6 years ago

Similar presentations

Presentation on theme: "Mixtures of Gases, Partial Pressure, Gases in Chemical Reactions & KMT"— Presentation transcript:

1 5.6-5.7 Mixtures of Gases, Partial Pressure, Gases in Chemical Reactions & KMT

2 Partial Pressures of Gases in Mixtures
Each gas, in a mixture of gases, exert a specific amount of pressure. This pressure can be calculated using the ideal gas law: RT RT RT Pa = na ; Pb = nb ; Pc = nc V V V If the total name pressure of a mixture is known, as well as a few partial pressures, Daltons Law of Partial Pressures could be used: Ptotal = Pa + Pb + Pc … na Partial Pressure can also be calculated using the mole fraction: Xa = ntotal Pa = XaPtotal

3 Let’s Try a Sample Problem
A sample of hydrogen gas is mixed with water vapor. The mixture has a total pressure of 755 torr and the water vapor has a partial pressure of 24 torr. What amount (in moles) of hydrogen gas is contained in 1.55 L of this mixture at 298 K? Ptotal = PH2 + PH2O = 755 torr = PH torr PH2= 731 torr nRT PV P = n = V RT (731 torr)(1.55 L) n = = 6.10X10-2 mol H2 (62.36 L torr / mol K)(298 K)

4 Let’s Try Another A deep sea diver breathes a heliox mixture with an oxygen mole fraction of What must the total pressure be for the partial pressure of oxygen to be 0.21 atm? PO2 = XO2 (Ptotal) PO2 O.21 atm Ptotal = = XO Ptotal = 4.2 atm

5 Gases in Chemical Reactions
In the following reaction, 4.58 L of O2 was formed at P = 745 mmHg and T = 308 K. How many grams of Ag2O decomposed? 2Ag2O(s)  4 Ag(s) + O2(g) PV (745 mmHg)(4.58 L) n = = = mol O2 RT (62.36 L torr/mol K)(308 K) 2 mol Ag2O g Ag2O mol O2 X X = 82.5 g Ag2O 1 mol O2 1 mol Ag2O

6 Kinetic Molecular Theory (KMT)
KMT: A gas is modeled as a collection of particles in constant motion. These particles could be atoms or molecules depending on the gas. Gas particles move in straight line motions. The size of the a particle (volume) is negligibly small. The average kinetic energy (KE) of a particle is proportional to the temperature in kelvins. This means that two gases, under the same temperature conditions, will have the same kinetic energy, regardless of the size of the gas particles. This occurs because lighter particles travel faster (on average) than heavier ones. KE per molecules = ½mv2  on your reference table! Collisions between particles are completely elastic.

7 Walk Me Through This Depiction
Draw a depiction, as described by kinetic molecular theory, of a gas sample containing equal amounts of argon and xenon. Use red dots to represent argon atoms and blue dots to represent xenon atoms (In your notebooks, you could use chemical symbols in circles rather than colors). Give each atom a “tail” to represent its velocity relative to the others in the mixture. Also, under which temperature and pressure conditions are real gases most like ideal gases? High temperature and low pressure. Ideal gases are said to have no attraction between particles, but we know that real gases are attracted to each other by intermolecular forces.

8 Root Mean Square If it were possible to find the velocity of each individual molecule of each gas in a gas sample, than it would be possible to calculate the average velocity of each gas. To calculate this velocity, the rms formula is used: Urms = 3𝑅𝑇 _____________ 𝑀 (where M = molar mass in kg/mol) (and R= J / mol K) ( a joule = kg m2/s2) All this is saying is that molecules that are less massive will be moving faster, under the same temperature conditions.

9 Let’s Try a Practice Problem
Calculate the root mean square velocity of the gaseous xenon atoms at 25oC? Urms = 3𝑅𝑇 _____________ 𝑀 K = = 298 K R = J / mol K ( a joule = kg m2/s2) M = kg / mol Urms = 3(8.314)(298) _____________ 1.31𝑋10−1 = 238 m/s

10 Another Depiction Problem
Three gases, taking up the same volume of space will be drawn on the board. Gas sample one has 7 small gas particles in a given area, gas sample two, has 7 large particles in a given area, and gas sample three has 10 small gas particles in the same size area. Assume that the mass of each particle is proportional to its size and that all gases are at the same temperature. Which sample of an ideal gas has the greatest pressure, and why? Gas sample three has the greatest pressure because less massive particles will move at a greater velocity, and if there are more particles there will be more collisions with each other, as well as will the walls of the container. These collisions in the given area result in a force that we call pressure.

11 pg #’s 62, 66, 70, 72, 82, 90 Read pgs

Download ppt "Mixtures of Gases, Partial Pressure, Gases in Chemical Reactions & KMT"

Similar presentations

The Gaseous State Chapter 12 Dr. Victor Vilchiz.

The Gaseous State Chapter 12 Dr. Victor Vilchiz.
Chapter 11 Gases.

Chapter 11 Gases.
Chapter 10; Gases. Elements that exist as gases at 25 0 C and 1 atmosphere.

Chapter 10; Gases. Elements that exist as gases at 25 0 C and 1 atmosphere.
Unit IX: Gases… Part II Chapter 11… think we can cover gases in one day? Obviously not… since this is day 2… but let’s plug away at it!

Unit IX: Gases… Part II Chapter 11… think we can cover gases in one day? Obviously not… since this is day 2… but let’s plug away at it!
Ch. 10 Gases. Properties Expand to fill their container Highly compressible Molecules are far apart.

Ch. 10 Gases. Properties Expand to fill their container Highly compressible Molecules are far apart.
Christian Madu, Ph.D. Collin College Lecture Presentation Chapter 5-2 Gases.

Christian Madu, Ph.D. Collin College Lecture Presentation Chapter 5-2 Gases.
Ideal Gas Law PV = nRT re-arrange n V = P RT n = molar mass (g/mol) mol gas= mass gas (g) mass of sample V x molar mass = P RT = density mass V density.

Ideal Gas Law PV = nRT re-arrange n V = P RT n = molar mass (g/mol) mol gas= mass gas (g) mass of sample V x molar mass = P RT = density mass V density.
Chapter 5 Gases. Reactions Involving Gases in reactions of gases, the amount of a gas is often given as a volume the ideal gas law allows us to convert.

Chapter 5 Gases. Reactions Involving Gases in reactions of gases, the amount of a gas is often given as a volume the ideal gas law allows us to convert.
Wednesday, October 7 th  Please take out your 10.6-10.7 notes!  A gas mixture with a total pressure of 745 mmHg contains each of the following gases.

Wednesday, October 7 th  Please take out your notes!  A gas mixture with a total pressure of 745 mmHg contains each of the following gases.
CHAPTER 10: GASES AP Chemistry. Measurements of Gases A. Volume, V 1. Definition: The amount of space an object or substance occupies 2. Common units:

CHAPTER 10: GASES AP Chemistry. Measurements of Gases A. Volume, V 1. Definition: The amount of space an object or substance occupies 2. Common units:
Gas Laws. Properties of Gases Particles far apart Particles move freely Indefinite shape Indefinite volume Easily compressed Motion of particles is constant.

Gas Laws. Properties of Gases Particles far apart Particles move freely Indefinite shape Indefinite volume Easily compressed Motion of particles is constant.
The Gaseous State 5.1 Gas Pressure and Measurement

The Gaseous State 5.1 Gas Pressure and Measurement
The Gas Laws.

The Gas Laws.
Chapter 14 Gas Behavior.

Chapter 14 Gas Behavior.
Unit 6 Gas Laws.

Unit 6 Gas Laws.
CHAPTER 10 – Gases Lecture 1 – KMT, Graham’s & Dalton’s Law

CHAPTER 10 – Gases Lecture 1 – KMT, Graham’s & Dalton’s Law
Gas Mixtures--Partial Pressure

Gas Mixtures--Partial Pressure
Gas Laws.

Gas Laws.
Topic 9 Gases Densities of Gases © 2009, Prentice-Hall, Inc.

Topic 9 Gases Densities of Gases © 2009, Prentice-Hall, Inc.
The Gaseous State of Matter

The Gaseous State of Matter

Similar presentations

Ads by Google