1 / 50

Chapter 4 Moisture and Atmospheric Stability

Chapter 4 Moisture and Atmospheric Stability. This chapter covers: Water states of matter heat capacity and latent heat Humidity and dew point Adiabatic temperature changes in the atmosphere Atmospheric stability. The Hydrologic Cycle. States of Matter: Solid, Liquid and Vapor.

starbuck
Download Presentation

Chapter 4 Moisture and Atmospheric Stability

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. Chapter 4Moisture and Atmospheric Stability This chapter covers: Water states of matter heat capacity and latent heat Humidity and dew point Adiabatic temperature changes in the atmosphere Atmospheric stability

  2. The Hydrologic Cycle

  3. States of Matter: Solid, Liquid and Vapor

  4. Gas (Vapor) • widely spaced molecules • no bonding between molecules • molecules move at high speeds • very compressible

  5. Liquid • Closely spaced molecules • Moderate bonding between molecules • molecules move at medium speeds • Slightly compressible

  6. Solid (i.e., ice) • closely spaced molecules • Strong, rigid bonding between molecules • No molecule movement – only vibrations • Fairly incompressible

  7. Solid Water: Ice

  8. Liquid Water

  9. Water Vapor

  10. Heat Capacity and Latent Heat of Water

  11. Saturation • Condition in which the air is holding the maximum amount of water vapor possible • Amount of water vapor present at saturation depends on • Temperature; more vapor at higher temp. Very strong effect • Pressure; more vapor at higher pressure.

  12. Absolute Humidity • Amount of water vapor present in air • Given as grams water vapor per cubic meter of air • Value is affected by air pressure

  13. Mixing Ratio • Amount of water vapor present in air, but more useful than absolute humidity • Given as grams water vapor per kilogram of air • Typically ranges from 0 to 4% • Value is not affected by air pressure

  14. Saturation • Air is limited in how much water vapor it can hold without water droplets forming • Saturation is the point at which air can’t hold more water vapor • Mixing ratio at saturation depends on temperature, and somewhat on pressure

  15. Contrail: engine exhaust contains water vapor, exhaust cools, becomes saturated with water vapor and condensation occurs

  16. Contrail: engine exhaust contains water vapor, exhaust cools, becomes saturated with water vapor and condensation occurs

  17. Saturation Mixing-Ratio:How much water vapor can be present in air at different temperatures

  18. Relative Humiditythe humidity we feel Amount of water vapor in air relative to maximum possible amount (saturation mixing ratio) Example Temperature: 20oC Saturation mixing ratio=14g vapor per 1 kg air Actual vapor content = 7 g per 1 kg air Relative humidity = 7 g / 14 g x 100% = 50%

  19. Dew Point • Temperature to which air must be cooled to become saturated • Assumes no change in mixing ratio • Relative humidity is 100% in air that’s at its dew point • Stating air’s dew point is essentially the same as stating its mixing ratio

  20. Air’s saturation mixing ratio and relative humidity change with temperature

  21. Which has larger mixing ratio? Which has higher relative humidity? Death Valley Antarctica

  22. Hotter: Higher mixing ratio, Lower relative humidity Colder: Lower mixing ratio Higher relative humidity

  23. Relative Humidity, Mixing Ratio and Air Temperature • Hotter air can hold much more water vapor than cold air • Hotter air can have more vapor in it than cold air, yet have lower relative humidity

  24. Relative Humidity Changes with Temperature Daily Temperature Relative Humidity

  25. Air Temp, Dew Pt. & Relative Humidity in Heber

  26. Dew Point Temperatures

  27. Adiabatic Temperature Changes • Air cools when it expands, warms when its compressed • Rising air expands and cools • Sinking air is compressed and warms • Adiabatic refers to temperature changes w/o heat transfer Very important!

  28. Adiabatic Temperature Changes

  29. Dry & Wet Adiabatic Rates • Saturated air cools less as it rises because condensation of water releases heat • Dry adiabatic rate = 10oC / 1000m = 5.5oF / 1000 feet • Wet adiabatic rate = 5 to 9oC / 1000m (2.75 to 5oF/1000ft)

  30. Dry & Wet Adiabatic Rates

  31. Lifting Condensation Level • As air rises, it expands and cools • Level (altitude) at which it is cooled to its dew point is thelifting condensation level • Clouds form above this level if air is rising

  32. Causes of Lifting • Orographic – wind blows over mountains • Frontal wedging – warm air forced over colder air • Convergence – winds blowing together • Convection – solar heating creates hot air that rises

  33. Orographic Lifting Important along Wasatch Front, much of Western U.S.

  34. Frontal Wedging “Storm Fronts”

  35. Convergence

  36. Convection

  37. sinking air warms at dry adiabatic rate Rising air cools at wet adiabatic rate Cause of Rain Shadow Desert

  38. Atmospheric Stability • Stable Air = Air that tends to not rise • Unstable Air = Air that tends to keep rising (regardless of orographics, fronts, etc.) • Importance – rising air cools, makes clouds, precipitation, even tornados

  39. What Controls Stability • Depends on adiabatic cooling rate (dry and wet) vs. Environmental Lapse Rate • Environmental Lapse Rate = the actual, existing decrease in air temperature with altitude

  40. Atmospheric Stability, cont. • Three types of stability: • Absolute stability • Absolute instability • Conditional instability

  41. Absolute Stability • Environmental Lapse rate is less than wet adiabatic rate • As air rises, it cools so much (even if its saturated) that it becomes cooler than surrounding air so it stops rising

  42. Absolute stability

  43. Absolute instability • Environmental lapse rate is greater than dry adiabatic rate • As air rises, despite cooling at dry adiabatic rate, it becomes progressively warmer than surrounding air and rises faster

  44. Absolute instability Absolute Instability

  45. Conditional Instability • Environmental Lapse rate is greater than wet adiabatic rate, less than dry adiabatic rate • As air rises, if it is unsaturated it tends to not rise, but once its saturated it keeps rising

  46. Conditional Instability Conditional Stability

  47. NWS Storm Prediction Center • Focuses on dangerous thunderstorms • Produces estimates of convective stability for locations across the country twice daily • Main website: http://www.spc.noaa.gov • Soundings (weather balloon data which provide information on environmental lapse rate and more) with stability analysis (somewhat advanced scientifically): http://www.spc.noaa.gov/exper/soundings/

  48. Chapter 4 END

More Related