1 / 70

Lecture 2

Lecture 2. Ideal Gas Law. Stull: pg 4-9, Wallace & Hobbs: 63-67. Atmospheric Pressure. Atmospheric pressure change is approximately exponential with height, z. If temperature were uniform with height (it’s not) then:. a= 0.0342 K/m, Po = scaled pressure = 101.325 kPa.

shaunna
Télécharger la présentation

Lecture 2

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Lecture 2 Ideal Gas Law Stull: pg 4-9, Wallace & Hobbs: 63-67

  2. Atmospheric Pressure Atmospheric pressure change is approximately exponential with height, z. If temperature were uniform with height (it’s not) then: a= 0.0342 K/m, Po = scaled pressure = 101.325 kPa Hp = 7.29 Km = scale height for pressure, it is the e-folding distance for pressure curve.

  3. Atmospheric Pressure Because pressure decreases with height monotonically (one direction), P can be used as a surrogate for a measure of altitude (Fig. 1.4, Stull). (Example in Stull, pg. 6)

  4. Density • Density is defined as mass per unit volume. • Density increases as the number and molecular weight of molecules in a volume increase. • Average density at sea level = 1.255 kg m-3 (Table 1.2, Stull)

  5. Density Because gases such as air are compressible, air density can vary over a wide range. Density decreases roughly exponentially with height in an atmosphere of uniform temperature. ρo = 1.225 kg/m3, scale height, Hp = 8.55 km.

  6. Temperature When a group of molecules (microscopic) move in the same direction, motion is called wind (macroscopic). When they move in random directions, motion is associated with temperature. Higher temperatures, T are associated with greater average molecular speeds, v. a = 4 ·10-5 k m-2s2, scale height, mw= molecular weight of most gases.

  7. Temperature Absolute units such as K (Kelvin) must be used for temperature in all thermodynamic and radiative laws! Standard average sea-level temperature is: T= 15°C = 288 K = 59 °F

  8. Virtual Temperature For moist air, the gas constant changes because water vapor is less dense than dry air. To simplify things, a virtual temperature, Tv can be defined to include the effects of water vapor on density: where w is the water vapor mixing ratio (g water vapor / kg dry air) and all temperatures are in K. Moist air of temperature T behaves as dry air of temperature Tv.

  9. Equation of State Because pressure is caused by the movement of molecules, we might expect the pressure P to be greater where there are more molecules (i.e., greater density ρ), and where they are moving faster (i.e., greater temperature T). The relationship between pressure, density, and temperature is called the Equation of State. For dry air the gases in the atmosphere have a simple equation of state known as the ideal gas law.

  10. Ideal Gases • Molecules have zero volume • No intermolecular forces • Elastic collisions with walls of container • Works well for the Earth’s atmosphere

  11. Molar Form

  12. Variables • Pressure (p) • Volume (V) • Temperature (T) • Number of moles (n)

  13. Ideal Gas Law Exercise: Determine units of R*

  14. Universal Gas Constant R* = 8.314 Jmol-1K-1

  15. Ideal Gas Law: Molar Form Memorize this!

  16. Sealed Container cylinder Gas n fixed

  17. Massless, Frictionless Piston piston Gas

  18. Weights can be added or removed to change pressure Equilibrium  internal pressure = external pressure Gas

  19. Keep T fixed, Vary p i.e., pressure and volume are inversely proportional (Boyle’s Law)

  20. Increase Pressure

  21. Increase Pressure

  22. Increase Pressure Ideal gas law  V decreases

  23. Increase Pressure Ideal gas law  V decreases

  24. Increase Pressure Ideal gas law  V decreases

  25. Decrease Pressure

  26. Decrease Pressure

  27. Decrease Pressure Ideal gas law  V increases

  28. Decrease Pressure Ideal gas law  V increases

  29. Decrease Pressure Ideal gas law  V increases

  30. Keep p fixed, Vary T i.e., volume is directly proportional to temperature

  31. Increase T Ideal gas law  V increases Apply Heat

  32. Increase T Ideal gas law  V increases Apply Heat

  33. Increase T Ideal gas law  V increases Apply Heat

  34. Decrease T Ideal gas law  V decreases Apply Cooling

  35. Decrease T Ideal gas law  V decreases Apply Cooling

  36. Decrease T Ideal gas law  V decreases Apply Cooling

  37. Fix V i.e., p is directly proportional to T

  38. Increase T Ideal gas law  p increases Piston doesn’t move (internal pressure  external pressure) Pressure builds up Apply Heat

  39. Exercise • n = 1.00 mol • V = 1.00 m3 • T = 300 K • Calculate p (in Pa)

  40. Solution

  41. Partial Pressure • Consider a mixture of k gases • Volume, V; temperature, T; pressure, p; # moles = n • ni = # moles of gas i • n1 + n2 +  + nk = n • Partial pressure, pi:

  42. Dalton’s Law

  43. Proof

  44. Ratios Ratio of partial pressure to total pressure = mole fraction

  45. Partial Volume

  46. Volume Ratios Explains why mole fractions are also called volume fractions.

  47. Ideal Gas Law – Mass Version • Start with molar version (1) Let m = mass Let M = molecular weight

  48. Mass & Moles  (2)

  49. Substitute (2) into (1)

More Related