Presentation is loading. Please wait.

Presentation is loading. Please wait.

Gases respond to changes in pressure, temperature, and volume in predictable ways. Section 3: Behavior of Gases K What I Know W What I Want to Find Out.

Published byJoel George Modified over 9 years ago

Similar presentations

Presentation on theme: "Gases respond to changes in pressure, temperature, and volume in predictable ways. Section 3: Behavior of Gases K What I Know W What I Want to Find Out."— Presentation transcript:

1 Gases respond to changes in pressure, temperature, and volume in predictable ways. Section 3: Behavior of Gases K What I Know W What I Want to Find Out L What I Learned

2 2(E) Communicate valid conclusions. 3(F) Research and describe the history of physics and chemistry and contributions of scientists. Behavior of Gases Copyright © McGraw-Hill Education

3 Essential Questions How does a gas exert pressure on its container? How is a gas affected when pressure, temperature, or volume change? Behavior of Gases Copyright © McGraw-Hill Education

4 Review temperature New Boyle’s law Charles’s law Behavior of Gases Copyright © McGraw-Hill Education Vocabulary

5 Boyle’s Law–Volume and Pressure What happens to the gas pressure if you decrease the size of the container? If you squeeze gas into a smaller space, its particles will strike the walls more often—giving an increased pressure. The opposite is true, too. Robert Boyle (1627-1691), a British scientist, described this property of gases. According to Boyle’s law, if you decrease the volume of a container of gas and hold the temperature constant, the pressure of the gas will increase. An increase in the volume of the container causes the pressure to drop, if the temperature remains constant. Behavior of Gases Copyright © McGraw-Hill Education

6 Volume and pressure Boyle’s law states that as pressure is decreased the volume increases. The opposite also is true, as shown by the graph. As the pressure is increased, the volume will decrease. Behavior of Gases Copyright © McGraw-Hill Education

7 An equation for Boyle’s law When Boyle’s law is applied to a real life situation, we find that the pressure multiplied by the volume is always equal to a constant if the temperature is constant. You can use the equations P i V i = constant = P f V f to express this mathematically, or more simply P i V i = P f V f. This shows us that the product of the initial pressure and volume—designated with the subscript i—is equal to the product of the final pressure and volume— designated with the subscript f. Behavior of Gases Copyright © McGraw-Hill Education

8 Behavior of Gases Copyright © McGraw-Hill Education BOYLE’S LAW EVALUATE THE ANSWER You can do a quick estimate to check your answer. The pressure was slightly more than halved. Therefore, the volume should slightly more than double. The final volume of 235 L is slightly more than twice the initial volume of 100.0 L. Therefore, the answer seems reasonable. Use with Example Problem 3. Problem A weather balloon has a volume of 100.0 L when it is released from sea level, where the pressure is 101 kPa. What will be the balloon’s volume when it reaches an altitude where the pressure is 43.0 kPa? Response ANALYZE THE PROBLEM KNOWN initial pressure: P i = 101 kPa initial volume: V i = 100.0 L final pressure: P f = 43.0 kPa UNKNOWN final volume: V f

9 Charles’s Law–Temperature and Volume Jacques Charles (1746-1823) was a French scientist who studied gases. According to Charles’s law, the volume of a gas increases with increasing temperature, as long as pressure does not change. As with Boyle’s law, the reverse is true, also. Behavior of Gases Copyright © McGraw-Hill Education

10 Volume v. Kelvin Temperature Behavior of Gases Copyright © McGraw-Hill Education

11 The kinetic theory and Charles’s law Charles’s law can be explained using the kinetic theory of matter. As a gas is heated, its particles move faster and faster and its temperature increases. Because the gas particles move faster, they begin to strike the walls of their container more often and with more force. Behavior of Gases Copyright © McGraw-Hill Education

12 An equation for Charles’s law The formula that relates the variables of temperature to volume shows a direct relationship when temperature is given in Kelvin. When using Charles’s law, the pressure must be kept constant. Behavior of Gases Copyright © McGraw-Hill Education

13 Behavior of Gases Copyright © McGraw-Hill Education USE CHARLES’S LAW EVALUATE THE ANSWER A good way to check your answer here is through experiment! If you place a balloon in a refrigerator, you will notice that the balloon shrinks, but not very much. This is consistent with our answer above. Use with Example Problem 4. Problem A 2.0-L balloon at room temperature (20.0°C) is placed in a refrigerator at 3.0°C. What is the volume of the balloon after it cools in the refrigerator? Response ANALYZE THE PROBLEM KNOWN initial volume: V i = 2.0 L initial temperature: T i = 20°C = 20.0°C + 273 = 293 K final temperature: T f = 3.0°C = 3.0°C + 273 = 276 K UNKNOWN final volume: V f

14 Behavior of Gases Copyright © McGraw-Hill Education Review Essential Questions How does a gas exert pressure on its container? How is a gas affected when pressure, temperature, or volume change? Vocabulary Boyle’s law Charles’s law

Download ppt "Gases respond to changes in pressure, temperature, and volume in predictable ways. Section 3: Behavior of Gases K What I Know W What I Want to Find Out."

Similar presentations

Gas Laws.

Gas Laws.
Chap 12.2 Gas laws.

Chap 12.2 Gas laws.
Unit 5: Gases – More Gas Laws: Charles’s Law and Boyle’s Law

Unit 5: Gases – More Gas Laws: Charles’s Law and Boyle’s Law
Gas Laws.

Gas Laws.
P RE V IEW T O GAS LAWS. BOYLE’S LAW How are the Pressure and Volume of a gas related? COPYRIGHT © PEARSON EDUCATION, INC., OR ITS AFFILIATES. ALL RIGHTS.

P RE V IEW T O GAS LAWS. BOYLE’S LAW How are the Pressure and Volume of a gas related? COPYRIGHT © PEARSON EDUCATION, INC., OR ITS AFFILIATES. ALL RIGHTS.
Behavior of Gases. Gas particles are in constant motion Collisions of these particles in the air causes pressure Pressure = force per unit of area or.

Behavior of Gases. Gas particles are in constant motion Collisions of these particles in the air causes pressure Pressure = force per unit of area or.
14.3 Essential Questions How does a gas exert pressure on its container? How is a gas affected when pressure, temperature, or volume change? Copyright.

14.3 Essential Questions How does a gas exert pressure on its container? How is a gas affected when pressure, temperature, or volume change? Copyright.
Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Chapter 14 The Behavior of Gases 14.1 Properties of Gases 14.2 The Gas Laws.

Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Chapter 14 The Behavior of Gases 14.1 Properties of Gases 14.2 The Gas Laws.
Explanation Gas pressure is caused by collisions of gas molecules on the wall of the container. The molecule collide with one other , with the walls of.

Explanation Gas pressure is caused by collisions of gas molecules on the wall of the container. The molecule collide with one other , with the walls of.
3.2: The Gas Laws.

3.2: The Gas Laws.
Chapter 11 Preview Objectives

Chapter 11 Preview Objectives
Pressure and Force Pressure (P) is defined as the force per unit area on a surface. Gas pressure is caused by collisions of the gas molecules with each.

Pressure and Force Pressure (P) is defined as the force per unit area on a surface. Gas pressure is caused by collisions of the gas molecules with each.
General Properties of Gases There is a lot of “free” space in a gas. Gases can be expanded infinitely. Gases fill containers uniformly and completely.

General Properties of Gases There is a lot of “free” space in a gas. Gases can be expanded infinitely. Gases fill containers uniformly and completely.
The Gas Laws Section 3.2.  What happens to your lungs when you take a deep breath?

The Gas Laws Section 3.2.  What happens to your lungs when you take a deep breath?
Aim: What are the properties of Gases?. Compressibility Compressibility is measure of how much volume decreases under increased pressure. Gases are easily.

Aim: What are the properties of Gases?. Compressibility Compressibility is measure of how much volume decreases under increased pressure. Gases are easily.
When you inhale, the volume of your chest cavity increases, and air moves into your lungs. When you exhale, the volume of your chest cavity decreases,

When you inhale, the volume of your chest cavity increases, and air moves into your lungs. When you exhale, the volume of your chest cavity decreases,
Chapter 16 Section 3. Pressure What did we learn about gas particles from the kinetic theory? –They are constantly moving and colliding with anything.

Chapter 16 Section 3. Pressure What did we learn about gas particles from the kinetic theory? –They are constantly moving and colliding with anything.
Chapter 14 The Behavior of Gases 14.2 The Gas Laws

Chapter 14 The Behavior of Gases 14.2 The Gas Laws
Chapter 3 Section 3 Notes.

Chapter 3 Section 3 Notes.
Behavior of Gases.

Behavior of Gases.

Similar presentations

Ads by Google