Presentation is loading. Please wait.

Presentation is loading. Please wait.

Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro

Published byBarnard Fitzgerald Modified over 6 years ago

Similar presentations

Presentation on theme: "Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro"— Presentation transcript:

1 Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro
Joseph Louis Gay-Lussac

2 The Combined Gas Law The combined gas law expresses the relationship between pressure, volume and temperature of a fixed amount of gas.

3 Boyle’s Law Pressure is inversely proportional to volume when temperature is held constant.

4 Charles’s Law The volume of a gas is directly proportional to temperature, and extrapolates to zero at zero Kelvin. (P = constant) Temperature MUST be in KELVINS!

5 Gay Lussac’s Law The pressure and temperature of a gas are
directly related, provided that the volume remains constant. Temperature MUST be in KELVINS!

6 Avogadro’s Law For a gas at constant temperature and pressure, the volume is directly proportional to the number of moles of gas (at low pressures). V = an a = proportionality constant V = volume of the gas n = number of moles of gas

7 PV = nRT Ideal Gas Law P = pressure in atm V = volume in liters
n = moles R = proportionality constant = L atm/ mol·K T = temperature in Kelvins Holds closely at P < 1 atm

8 Real Gases ­ ­ Pideal Videal
At high pressure (smaller volume) and low temperature (attractive forces become important) you must adjust for non-ideal gas behavior using van der Waal’s equation. corrected pressure corrected volume Pideal Videal

9 Gas Density … so at STP…

10 Density and the Ideal Gas Law
Combining the formula for density with the Ideal Gas law, substituting and rearranging algebraically: M = Molar Mass P = Pressure R = Gas Constant T = Temperature in Kelvins

11 Gas Stoichiometry #1 If reactants and products are at the same conditions of temperature and pressure, then mole ratios of gases are also volume ratios. 3 H2(g) N2(g)  NH3(g) 3 moles H mole N  moles NH3 3 liters H liter N  liters NH3

12 Gas Stoichiometry #2 3 H2(g) + N2(g)  2NH3(g)
How many liters of ammonia can be produced when 12 liters of hydrogen react with an excess of nitrogen? 3 H2(g) + N2(g)  2NH3(g) 12 L H2 2 L NH3 = L NH3 8.0 3 L H2

13 Gas Stoichiometry #3 How many liters of oxygen gas, at STP, can be collected from the complete decomposition of 50.0 grams of potassium chlorate? 2 KClO3(s)  2 KCl(s) + 3 O2(g) 50.0 g KClO3 1 mol KClO3 3 mol O2 22.4 L O2 g KClO3 2 mol KClO3 1 mol O2 = 13.7 L O2

14 Gas Stoichiometry #4 How many liters of oxygen gas, at 37.0C and atmospheres, can be collected from the complete decomposition of 50.0 grams of potassium chlorate? 2 KClO3(s)  2 KCl(s) + 3 O2(g) 50.0 g KClO3 1 mol KClO3 3 mol O2 0.612 = mol O2 g KClO3 2 mol KClO3 = 16.7 L

15 Dalton’s Law of Partial Pressures
For a mixture of gases in a container, PTotal = P1 + P2 + P This is particularly useful in calculating the pressure of gases collected over water.

Download ppt "Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro"

Similar presentations

Gases.

Gases.
Unit 8 Gases.

Unit 8 Gases.
Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro

Gas Laws Robert Boyle Jacques Charles Amadeo Avogadro
Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
TOPICS 1.Intermolecular Forces 2.Properties of Gases 3.Pressure 4.Gas Laws – Boyle, Charles, Lussac 5.Ideal Gas Law 6.Gas Stoichiometry 7.Partial Pressure.

TOPICS 1.Intermolecular Forces 2.Properties of Gases 3.Pressure 4.Gas Laws – Boyle, Charles, Lussac 5.Ideal Gas Law 6.Gas Stoichiometry 7.Partial Pressure.
Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.

Not so long ago, in a chemistry lab far far away… May the FORCE/area be with you.
GASES Chapter 5. A Gas -Uniformly fills any container. -Mixes completely with any other gas -Exerts pressure on its surroundings.

GASES Chapter 5. A Gas -Uniformly fills any container. -Mixes completely with any other gas -Exerts pressure on its surroundings.
Molecular Composition of Gases

Molecular Composition of Gases
Unit 5: Gases and Gas Laws. Kinetic Molecular Theory  Particles of matter are ALWAYS in motion  Volume of individual particles is  zero.  Collisions.

Unit 5: Gases and Gas Laws. Kinetic Molecular Theory  Particles of matter are ALWAYS in motion  Volume of individual particles is  zero.  Collisions.
A Gas -Uniformly fills any container. -Mixes completely with any other gas -Exerts pressure on its surroundings.

A Gas -Uniformly fills any container. -Mixes completely with any other gas -Exerts pressure on its surroundings.
Stoichiometry The study of quantities of materials consumed and produced in chemical reactions.

Stoichiometry The study of quantities of materials consumed and produced in chemical reactions.
Section 13.2 Using Gas Laws to Solve Problems. Section 13.2 Using Gas Laws to Solve Problems 1.To understand the ideal gas law and use it in calculations.

Section 13.2 Using Gas Laws to Solve Problems. Section 13.2 Using Gas Laws to Solve Problems 1.To understand the ideal gas law and use it in calculations.
1.Use the Ideal Gas Law to solve a gas stoichiometry problem.

1.Use the Ideal Gas Law to solve a gas stoichiometry problem.
Gas Laws Joseph Louis Gay-LussacAmadeo Avogadro Robert BoyleJacques Charles.

Gas Laws Joseph Louis Gay-LussacAmadeo Avogadro Robert BoyleJacques Charles.
Molecular Composition of Gases

Molecular Composition of Gases
Gases All molecules move to some extent. –Vibrational –Rotational –Translational *

Gases All molecules move to some extent. –Vibrational –Rotational –Translational *
Gases. Ideal Gases Ideal gases are imaginary gases that perfectly fit all of the assumptions of the kinetic molecular theory.  Gases consist of tiny.

Gases. Ideal Gases Ideal gases are imaginary gases that perfectly fit all of the assumptions of the kinetic molecular theory.  Gases consist of tiny.

Similar presentations

Ads by Google