Presentation is loading. Please wait.

Presentation is loading. Please wait.

BOYLE’S LAW CHARLE’S LAW GAY-LUSSAC’S LAW AVOGADRO’S LAW COMBINED GAS LAW BEHAVIOR OF GASES GAS LAWS.

Published byAdele Eaton Modified over 8 years ago

Similar presentations

Presentation on theme: "BOYLE’S LAW CHARLE’S LAW GAY-LUSSAC’S LAW AVOGADRO’S LAW COMBINED GAS LAW BEHAVIOR OF GASES GAS LAWS."— Presentation transcript:

1 BOYLE’S LAW CHARLE’S LAW GAY-LUSSAC’S LAW AVOGADRO’S LAW COMBINED GAS LAW BEHAVIOR OF GASES GAS LAWS

2 DIRECTIONS FOR THESE NOTES USING THE “FACTORS AFFECTING GASES INVESTIGATION” AND “BEHAVIOR OF GASES” HANDOUT TO FOLLOW ALONG HAVE YOUR NOTEBOOK/PAPER IN HAND FOR PARTS NOT FOUND IN THE HANDOUT

3 BEHAVIOR OF GASES We’ve discussed some characteristic of assumptions and characteristics of gases according to the Kinetic Molecular Theory: i. Gases move randomly and rapidly in straight line paths. ii. Collisions between particles and the walls of a container are elastic (they don’t stick) because there are no significant forces of attraction or repulsion. iii. Gases have no significant volume and can take up the shape and volume of a container

4 BEHAVIOR OF GASES Kinetic Molecular Theory can also explain other properties and variables of gases and their relationship to each other. These variables are: 1. AMOUNT OF A GAS (MOLES) 2. PRESSURE 3. VOLUME 4. TEMPERATURE

5 BOYLE’S LAWBOYLE’S LAW: PRESSURE & VOLUME As the pressure of a gas increases, the volume decreases (constant temperature) P 1 V 1 = P 2 V 2

6 BOYLE’S LAW: PRESSURE & VOLUME As the pressure of a gas increases, the volume decreases (constant temperature) A balloon at an initial volume of 25 mL and 1 atm is expanded to 100 mL, what is the final pressure? P 1 = 1 atm V 1 = 25 mL (1 atm) x (25 mL) = ( ??? atm) x (100 mL) V 2 = 100 mL (1atm)x(25mL) / (100mL) = 0.25 atm P 2 = ???? P 1 V 1 = P 2 V 2

7 BOYLE’S LAW: PRESSURE & VOLUME As the pressure of a gas increases, the volume decreases (constant temperature) A balloon at an initial volume of 25 mL and 1 atm is expanded to 100 mL, what is the final pressure? P 1 = 1 atm V 1 = 25 mL (1 atm) x (25 mL) = ( ??? atm) x (100 mL) V 2 = 100 mL (1atm)x(25mL) / (100mL) = 0.25 atm P 2 = ???? P 1 V 1 = P 2 V 2

8 BOYLE’S LAW: PRESSURE & VOLUME As the pressure of a gas increases, the volume decreases (constant temperature) A balloon at an initial volume of 25 mL and 1 atm is expanded to 100 mL, what is the final pressure? P 1 = 1 atm V 1 = 25 mL (1 atm) x (25 mL) = ( ??? atm) x (100 mL) V 2 = 100 mL (1atm)x(25mL) / (100mL) = 0.25 atm P 2 = ???? P 1 V 1 = P 2 V 2

9 BOYLE’S LAW: PRESSURE & VOLUME As the pressure of a gas increases, the volume decreases (constant temperature) A balloon at an initial volume of 25 mL and 1 atm is expanded to 100 mL, what is the final pressure? P 1 = 1 atm V 1 = 25 mL (1 atm) x (25 mL) = ( ??? atm) x (100 mL) V 2 = 100 mL (1atm)x(25mL) / (100mL) = 0.25 atm P 2 = ???? P 1 V 1 = P 2 V 2

10 CHARLE’S LAWCHARLE’S LAW: TEMPERATURE & VOLUME As the temperature of an enclosed gas increases, the volume increases (Constant pressure) NOTE: Absolute Zero is 0 K (  273°C) where the motion of particles ceases (stops)

11 CHARLE’S LAW: TEMPERATURE & VOLUME A balloon at 300 K and 100 mL is heated to 400 K. What is the final volume? SET-UP?

12 GAY-LUSSAC’S LAWGAY-LUSSAC’S LAW: PRESSURE & TEMPERATURE As the temperature of an enclosed gas increases, the pressure increases (Constant Volume)

13 GAY-LUSSAC’S LAW: PRESSURE & TEMPERATURE A balloon at 1 atm and 298 K is compressed to 2 atm. What is the final temperature? Set-up?

14 AVOGADRO’S LAW: VOLUME & MOLES Equal volumes of gases at the same temperature and pressure have equal number of moles (n).

15 COMBINED GAS LAW The combined gas law describes the relationship among the pressure, temperature and volume of an enclosed gas. It allows you to do calculations for situations in which the number of moles of gas is constant.

16 COMBINED GAS LAW A balloon is at initial conditions of 373 K, 1 atm and 100 L is expanded to 200 L and 0.5 atm. What is the final temperature of the balloon?

Download ppt "BOYLE’S LAW CHARLE’S LAW GAY-LUSSAC’S LAW AVOGADRO’S LAW COMBINED GAS LAW BEHAVIOR OF GASES GAS LAWS."

Similar presentations

Gas Laws Chapters 13.1 + 14.

Gas Laws Chapters
The Properties of Gases

The Properties of Gases
Gases.

Gases.
Gases Chapter 14.

Gases Chapter 14.
GASES Chemistry 2011. Properties of Gases Characteristics of Gases Fill their containers completely Have mass Can be compressed Exert pressure Mix rapidly.

GASES Chemistry Properties of Gases Characteristics of Gases Fill their containers completely Have mass Can be compressed Exert pressure Mix rapidly.
Physical Characteristics of Gases The Kinetic Molecular Theory of Matter.

Physical Characteristics of Gases The Kinetic Molecular Theory of Matter.
CHEMISTRY Matter and Change

CHEMISTRY Matter and Change
1 Ch 10.1 Kinetic Theory: 5 assumptions 1.small particles - far apart 2.Movement random, rapid & continuous 3.Collisions are elastic 4.No attractive/repulsive.

1 Ch 10.1 Kinetic Theory: 5 assumptions 1.small particles - far apart 2.Movement random, rapid & continuous 3.Collisions are elastic 4.No attractive/repulsive.
Gas LawsGas Laws  Describes the relationship between variables associated with gases  Volume (V)  Temperature (T)  Pressure (P)  Concentration/amount.

Gas LawsGas Laws  Describes the relationship between variables associated with gases  Volume (V)  Temperature (T)  Pressure (P)  Concentration/amount.
Chapter 13: Gases. What Are Gases? Gases have mass Gases have mass.

Chapter 13: Gases. What Are Gases? Gases have mass Gases have mass.
Chapter 14 – Gases Kinetic Molecular Theory (KMT) Defn – describes the behavior of gases in terms of particle motion Defn – describes the behavior of.

Chapter 14 – Gases Kinetic Molecular Theory (KMT) Defn – describes the behavior of gases in terms of particle motion Defn – describes the behavior of.
Gases Chapter 14. 14.1 The Gas Laws: Kinetic Molecular Theory (Chapter 13): gases typically behave in a way that allows us to make assumptions in order.

Gases Chapter The Gas Laws: Kinetic Molecular Theory (Chapter 13): gases typically behave in a way that allows us to make assumptions in order.
GAS LAWS. Behavior of Gases Gases can expand to fill their container Gases can be compressed –Because of the space between gas particles Compressibility:

GAS LAWS. Behavior of Gases Gases can expand to fill their container Gases can be compressed –Because of the space between gas particles Compressibility:
Gases Kinetic Molecular Theory of Gases. A gas consists of small particles (atoms/molecules) that move randomly with rapid velocities Further Information.

Gases Kinetic Molecular Theory of Gases. A gas consists of small particles (atoms/molecules) that move randomly with rapid velocities Further Information.
Gases Chapter 13.

Gases Chapter 13.
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.
STAAR Ladder to Success Rung 4. Boyle’s Law The pressure and volume of a gas are inversely related – at constant mass & temp P 1 V 1 = P 2 V 2.

STAAR Ladder to Success Rung 4. Boyle’s Law The pressure and volume of a gas are inversely related – at constant mass & temp P 1 V 1 = P 2 V 2.
Gases http://www.mhhe.com/physsci/chemistry/animations/chang_7e_esp/gam2s2_6.swf.

Gases
1 How Do Gases Behave? The behavior of gases can be described by the kinetic molecular theory of ideal gases. Gases consist of submicroscopic particles.

1 How Do Gases Behave? The behavior of gases can be described by the kinetic molecular theory of ideal gases. Gases consist of submicroscopic particles.
The Behavior of Gases. Properties of Gases (Review) No definite shape No definite shape No definite volume No definite volume compressible compressible.

The Behavior of Gases. Properties of Gases (Review) No definite shape No definite shape No definite volume No definite volume compressible compressible.

Similar presentations

Ads by Google