Properties of Gases: Pressure, Volume, and Temperature Laws

1. Chapter 12 Properties Of Gases

2. Pressure Measure of the number of collisions between gas particles and a unit area of the wall of the containerPressure = force / unit area

3. Force/area English system: pounds/in2 (psi) Metric system: Newton/m2 (pascal)

4. Torricelli Barometer h = 760 mm Hg 1 atmosphere pressure

5. 1 atm = 760 torr (mm Hg) = 101.325 kPa = 1.01325 bar =14.70 psi

7. Patm Manometer h Pgas

8. Patm Manometer h Pgas

9. Volume Total space of a container that gases occupy due to the free random motion of the gas molecules

10. Relationship between Volume & Pressure of Gases P-V

11. V P (at constant T)

12. Slope = k V 1/P (at constant T)

13. In mathematical terms: y = mx + b Boyle’s Law

14. Relationship between Volume & Temperature of Gases V-T

15. In mathematical terms: y = mx + b V = mT + b Charles’ Law

16. Where T must be in Kelvin (K) temperature K = 0C + 273

18. Relationship between Pressure & Temperature of Gases P-T

19. In mathematical terms: y = mx + b P = mT + b Gay-Lussac’s Law

20. Relationship between Volume & Moles of Gases V-n

21. In mathematical terms: y = mx + b V = mn + b Avogadro’s Law

22. Avogadro’s Hypothesis At constant temperature and pressure, equal volumes of gases contain equal number of particles

23. Combined Gas Law

24. Ideal & Real Gasses

25. Kinetic Molecular Theory 1. Gases consist of small particles that are far apart in comparison to their own size. These particles are considered to be tiny points occupying a negligible volume compared to that of their container.

26. Kinetic Molecular Theory 2. Molecules are in rapid and random straight-line motion. This motion can be described by well-defined and established laws of motion.

27. Kinetic Molecular Theory 3. The collisions of molecules with the walls of a container or with other molecules are perfectly elastic. That is, no loss of energy occurs.

28. Kinetic Molecular Theory 4. There are no attractive forces between molecules or between molecules and the walls with which they collide.

29. Kinetic Molecular Theory 5. At any particular instant, the molecules in a given sample of gas do not all possess the same amount of energy.

30. Ideal Gas Equation

32. Note that is similar to the Combined Gas Law derived earlier.

33. Variations on Ideal Gas Equation

34. Bromine Variations on Ideal Gas Equation

35. Real Gas Behavior

36. Ideal Gas Equation P V = n R T

37. N2 2.0 CH4 H2 PV nRT 1.0 Ideal gas CO2 0 0 200 400 600 800 1000 P (atm)

38. “correct” for volume of molecules (V - b)

39. also “correct” for attractive forces between molecules

40. van der Waals’ Equation for 1 mole

41. van der Waals’ Equation for n moles

42. from CRC Handbook a*b* He 0.03412 0.02370 Ne 0.2107 0.01709 *when P(atm) & V(L)

43. from CRC Handbook a*b* NH3 4.170 0.03707 H2O 5.464 0.03049 *when P(atm) & V(L)

44. from CRC Handbook a*b* CCl4 20.39 0.1383 C5H12 19.01 0.1460 *when P(atm) & V(L)

45. Cl2 gas has a = 6.49, b = 0.0562 • For 8.0 mol Cl2 in a 4.0 L tank at 27oC. • P (ideal) = nRT/V = 49.3 atm • P (van der Waals) = 29.5 atm

46. T & P conditions where a real gas approximates an ideal gas?

47. 203 K N2 gas 293 K 1.8 1.4 673 K PV nRT Ideal gas 1.0 0.6 0 200 400 600 800 P (atm)

48. T & P conditions where a real gas approximates an ideal gas? high temperature low pressure

49. Gaseous Molecular Movement

50. Partial Pressure pressure exerted by each component in a mixture of gases