Chapter 5 – Gases. In Chapter 5 we will explore the relationship between several properties of gases: Pressure: Pascals (Pa) Volume: m 3 or liters Amount:

Slides:

Advertisements

Similar presentations

Gases: Their Properties and Behavior

Advertisements

GASES! AP Chapter 10. Characteristics of Gases Substances that are gases at room temperature tend to be molecular substances with low molecular masses.

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

Gases Chapter 5 Web-site:

The Gaseous State 5.1 Gas Pressure and Measurement 5.2 Empirical Gas Laws 5.3 The Ideal Gas Law 5.4 Stoichiometry and Gas Volumes.

The Gaseous State. Copyright © Houghton Mifflin Company.All rights reserved. Presentation of Lecture Outlines, 5–2 Gas Laws In the first part of this.

The Gaseous State Chapter 12 Dr. Victor Vilchiz.

The Gaseous State Chapter 5.

Chapter 11 Gases Copyright McGraw-Hill

Reading for Tuesday: Chapter Reading for Tuesday: Chapter Homework 11.1 – Due Tuesday 4/14/15 Homework 11.1 – Due Tuesday 4/14/15 Chapter.

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Gases Chapter 5 Become familiar with the definition and measurement of gas pressure.

Chapter 5 Gases John A. Schreifels Chemistry 211.

Ch Gases Properties: Gases are highly compressible and expand to occupy the full volume of their containers. Gases always form homogeneous mixtures.

NOTES: 14.4 – Dalton’s Law & Graham’s Law

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Gases.

Gases Chapter 5 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

Gases. Characteristics of Gases Unlike liquids and solids, they – Expand to fill their containers. – Are highly compressible. – Have extremely low densities.

Gases Made up of particles that have (relatively) large amounts of ________ No definite _______ or___________ Due to a large amount of empty space, gases.

Chapter 13: Gases. What Are Gases? Gases have mass Gases have mass.

Daniel L. Reger Scott R. Goode David W. Ball Chapter 6 The Gaseous State.

Chemistry AP/IB Dr. Cortes

Gases Chapter 12 pp General properties & kinetic theory Gases are made up of particles that have (relatively) large amounts of energy. A gas.

Gases Notes A. Physical Properties: 1.Gases have mass. The density is much smaller than solids or liquids, but they have mass. (A full balloon weighs.

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

GASES Chapter 10. Example: Air 78% nitrogen 21% oxygen Molecules only take up about 0.1% of total volume (the rest is empty space)  extremely low density.

Quinnipiac University

Gases Courtesy of nearingzero.net.

Chapter 5: Gases Renee Y. Becker Valencia Community College CHM

Lecture Notes Alan D. Earhart Southeast Community College Lincoln, NE Chapter 9 Gases: Their Properties and Behavior John E. McMurry Robert C. Fay CHEMISTRY.

Gases and Kinetic Molecular Theory

Chapter 13: Gases. What Are Gases? Gases have mass Gases have mass Much less compared to liquids and solids Much less compared to liquids and solids.

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

Chapter 9: Gases: Their Properties and Behavior

Chapter 10 Gases Chemistry, The Central Science, 10th edition

Gases Chapter 10 Gases. Gases Characteristics of Gases Unlike liquids and solids, they  Expand to fill their containers.  Are highly compressible. 

1 Chapter 5 The Gas Laws. 2 Pressure Force per unit area. Force per unit area. Gas molecules fill container. Gas molecules fill container. Molecules move.

Gases. Elements that exist as gases at 25 0 C and 1 atmosphere.

Gases Chapter 10 Gases. Gases Characteristics of Gases Unlike liquids and solids, they  _______________ to fill their containers.  Are highly _______________.

Chapters 10 and 11: Gases Chemistry Mrs. Herrmann.

Chapter 121 Gases. 2 Characteristics of Gases -Expand to fill a volume (expandability) -Compressible -Readily forms homogeneous mixtures with other gases.

Chapter 09Slide 1 Gases: Their Properties & Behavior 9.

Ch. 10 Gases. Properties Expand to fill their container Highly compressible Molecules are far apart.

Gases Chapter 5. Elements that exist as gases at 25 0 C and 1 atmosphere 5.1.

Mullis1 Characteristics of Gases ► Vapor = term for gases of substances that are often liquids/solids under ordinary conditions ► Unique gas properties.

A 3.00-L bulb containing neon gas at 3.85 atm is connected to an evacuated 5.00-L flask. The valve connecting the flasks is opened, and the pressure is.

Gases Unit 6. Kinetic Molecular Theory  Kinetic energy is the energy an object has due to its motion.  Faster object moves = higher kinetic energy 

1 The Gaseous State. 2 Gas Laws  In the first part of this chapter we will examine the quantitative relationships, or empirical laws, governing gases.

1 Chapter 10 Gases Forestville Central School. 2 Properties of Gases Properties of Gases: 1. Gases have an indefinite shape. 2. Gases can expand. 3. Gases.

Gases © 2009, Prentice-Hall, Inc. Characteristics of Gases Unlike liquids and solids, gases –expand to fill their containers; –are highly compressible;

Gases: Chapter – Characteristics of Gases Physical properties of gases are all similar. Composed mainly of nonmetallic elements with simple formulas.

Gases Pressure Boyle’s Law Charles’ Law Gay-Lussac’s Law

Quinnipiac University

University of Nebraska-Lincoln

Elements that exist as gases at 25 0 C and 1 atmosphere 5.1.

Gas Team Review Game. ?1 List all 5 parts of the Kinetic Molecular Theory. List all 5 parts of the Kinetic Molecular Theory.

CHAPTER 5 GASES. Characteristics of Gases Unlike liquids and solids, gases – expand to fill their containers; – are highly compressible; – have extremely.

Gases AP Chemistry Mr. G. All matter follows the KMT: Kinetic Molecular Theory KMT- the tiny particles in all forms of matter are in constant motion.

Prentice Hall © 2003Chapter 10 Chapter 10 Gases CHEMISTRY The Central Science 9th Edition.

Gases Boyle’s Law. As the volume of a gas increases, the pressure decreases. –Temperature remains constant.

Quinnipiac University

Quinnipiac University

Chapter 5 The Gas Laws.

Quinnipiac University

Quinnipiac University

Lecture Presentation Chapter 10 Gases.

Quinnipiac University

Presentation transcript:

Chapter 5 – Gases

In Chapter 5 we will explore the relationship between several properties of gases: Pressure: Pascals (Pa) Volume: m 3 or liters Amount: moles Temperature: Kelvin

Pressure Measurements

A barometer a near perfect vacuum 760 mm Hg = 1 atm

Pressure Measurements A manometer

Ideal Gasses For an ideal gas (all gasses for now): PV = nRT An ideal gas: we assume that the gas molecules occupy zero volume and have no interaction with each other (except elastic collisions). These assumptions are good approximations under most conditions for all common gases.

A 3.00-L bulb containing neon gas at 3.85 atm is connected to an evacuated 5.00-L flask. The valve connecting the flasks is opened, and the pressure is allowed to equilibrate. If the temperature remains constant, what is the final pressure in the system?

How many molecules are present in a sample of hydrogen gas having a volume of 8.56 L at 0ºC and 1.5 atm pressure?

What volume of oxygen (at standard temperature and pressure - STP) is needed to fully oxidize (rust) a cube of solid iron that measures 10 cm on each side?

At 1.50 atm pressure and 27ºC, a gas is found to have a density of 1.95 g/L. What is the molar mass of the gas?

Each component of a gas mixture exerts a pressure that it would exert if it were in the container alone. Partial pressure

The atmospheric pressure is 743 mm Hg. If the partial pressure of oxygen is 156 Torr, what is the mol fraction of oxygen in air?

A mixture of 1.00 g of H 2 and 1.00 g of He is placed in a 1.00 L container at standard temperature and pressure (STP). What is the total pressure of the gas?

Gas Collection Over Water

P total = P gas + P H 2 O Gas Collection Over Water

A sample of nitrogen (N 2 ) is present in a container with liquid water present. The sample has a total pressure of 763 mmHg at 27°C. The vapor pressure of water at 27°C is 26.7 mmHg. What is the density of the gas mixture?

A mixture of CH 4 at atm and O 2 at atm is present in a 3.00 L container at 28°C. The mixture is ignited by a spark and reacts according to the equation below. What is the total pressure in the container, now at 44°C, after the reaction is complete? The vapor pressure of water at 44°C is mmHg.

A gaseous mixture consists of 50.0% O 2, 25.0% N 2, and 25.0% Cl 2, by weight. At standard temperature and pressure, What is the partial pressure of Cl 2 ?

Kinetic Molecular Theory Particles are point masses in constant, random, straight line motion. Particles are separated by great distances. Collisions are rapid and elastic. No force between particles. Total energy remains constant.

Pressure and Molecular Speed u m is the modal speed u av is the simple average u rms

Distribution of Molecular Speeds

Gas Properties Diffusion Effusion

Graham’s Law Only for gases at low pressure (natural escape, not a jet). Tiny orifice (no collisions) Does not apply to diffusion. Ratio used can be: –Rate of effusion (as above) –Molecular speeds –Effusion times –Distances traveled by molecules –Amounts of gas effused.

Rank the following gasses in order of increasing rate of effusion: N 2, O 2, Cl 2, Ar

An equimolar mixture of nitrogen and carbon dioxide in a container are allowed to effuse through a hole. After a certain period of time, 0.5 mol of N 2 has escaped the container. How much carbon dioxide has escaped?

Kinetic Molecular Theory Particles are point masses in constant, random, straight line motion. Particles are separated by great distances. Collisions are rapid and elastic. No force between particles. Total energy remains constant.

Real Gases PV/nRT = 1 for an ideal gas Deviations occur for real gases: If PV/nRT > 1, then molecular volume is significant. If PV/nRT < 1, then intermolecular forces of attraction are significant.

IdealCl 2 N2N2 CO 2 H2H2 He 22.41L22.40L 22.06L 22.42L 22.31L 22.41L Real Gases at STP

The van der Waals Equation These effects are usually only seen at high pressure (gasses behave as ideal at low pressure)

Real Gases

A sample of 1.00 mol O 2 is in a 100 mL container at 27°C. Assuming that the van der Waals equation is a better representation of a real gas under the conditions of this problem, how much does the ideal-gas equation overestimate the pressure compared to the van der Waals equation? For oxygen, a = L 2 -atm/mol 2 and b = L/mol