The Behavior of Gases Chapter 14

1. Concepts to consider The Behavior of GasesChapter 14

2. Kinetic Theory • Gases consist of hard spherical particles • Particles have insignificant volume • Large distance between particles • No attractive or repulsive forces between particles • Constant, random motion with elastic collisions

3. Variables and Equations • 4 variables are pressure (P) in kilopascals, temperature (T) in kelvins, volume (V) in liters, and number of moles (n). • Help to understand everyday applications such as airbags, scuba-diving equipment, and hot-air balloons.

4. Compressibility • Why are gases compressed more easily than liquids or solids? • How does the overall volume of the particles in a gas compare to the overall volume of the gas? • How does an airbag work?

5. Amount of a Gas • What happens to the pressure if you double the amount of particles in a rigid container? • How does an aerosol can work?

6. Volume • If you double the volume of a rigid container, what can be said about the pressure? • What about if you halve the volume?

7. Temperature • When you increase the temperature of gas molecules in a container, what happens to the pressure? • when molecules gain more KE and move faster, what happens to pressure? • If you leave a bag of potato chips in the sun, why will the bag start to bulge?

8. Gas Laws • Boyle’s Law • Charles’ Law • Gay-Lussac’s Law • Combined Gas Law • Ideal Gas Law • Dalton’s Law • Graham’s Law

9. Boyle’s Law • As volume increases, pressure _________. • Therefore, volume and pressure are inversely related • We can show this by P1V1 = P2V2

10. Charles’ Law • As temperature increases, volume _________. • Therefore temperature and volume are directly related. • We can show this V1/T1 = V2/T2

11. Gay-Lussac’s Law • As the pressure of an enclosed gas increases, the temperature __________. • Therefore temperature and pressure are directly related. • We can show this by P1/T1 = P2/T2

12. The Combined Gas Law • We can combine the previous three laws into one law that involves P, T and V. • The combined gas law is written as P1V1 = P2V2 T1 T2

13. The Ideal Gas Law • To calculate the number of moles of a contained gas, we use the variable ‘n’ • The ideal gas law is PV = nRT • R is known as the ideal gas constant • R = 8.31 (if pressure is in kPa) R = 0.0821 (if pressure is in atm)

14. Ideal Gas Law • PV = nRT • What are the units on R? • Can we derive the value for R? • Remember that at STP, T = 273 K, P = 101.3 kPa, n = 1 mol, V = 22.4 L

15. Ideal vs. Real • Real gases differ most from an ideal gas at low temperatures and high pressures • Remember, in reality, there are attractive forces between molecules

16. Dalton’s Law • Also known as the law of partial pressures: In a mixture of gases, the total pressure is the sum of the partial pressures of the gases • Simply, Ptotal = P1 + P2 + P3 + … Pn • Why would a climber at the top of Mt. Everest care about Dalton’s Law?

17. Graham’s Law • Gases with a lower molar mass will diffuse faster than gases with a larger mass • It makes sense that a lighter object will have to move faster to have the same energy as a larger object moving slowly • We can show this law as:

18. How to Solve Problems Here is a sample problem: 5 moles of gas is heated to 400K in a 2.5 L container. What is the pressure of the gas? • Identify and write down variables. n = 5, T = 400K, V = 3.5 L