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Introduction to Cloud Dynamics

Introduction to Cloud Dynamics. We are now going to concentrate on clouds that form as a result of air flows that are tied to the clouds themselves, i.e. instabilities that lead to the formation of clouds These instabilities will result from atmospheric variations of: Temperature Humidity

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Introduction to Cloud Dynamics

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  1. Introduction to Cloud Dynamics • We are now going to concentrate on clouds that form as a result of air flows that are tied to the clouds themselves, i.e. instabilities that lead to the formation of clouds • These instabilities will result from atmospheric variations of: • Temperature • Humidity • Wind and wind shear

  2. Introduction to Cloud Dynamics • Clouds (condensation) forms when humidity reaches saturation by: • Air cooling to saturation • Expansion cooling (rising motion) • Radiation cooling • Conduction cooling • Mixing of cold and warm moist air creating saturation • Your breath on a cold day • Warm water in contact with colder air (steam fog) • Warm droplets in contact with cold air (frontal fog)

  3. Fogs • Fog is a cloud in contact with the ground • Because they are in contact with the surface, only upslope fogs have significant vertical motion and large liquid water contents that result • Fog types mirror the major formation mechanisms for clouds

  4. Fog Types • Upslope Fog • Radiation Fog • Ground fog – radiational cooling of the surface cools the air above to saturation by conduction and mixing • High inversion fog – discontinuity in vapor across an inversion leads to large radiation divergence, cooling the air to saturation • Frontal Fog • Warm droplets falling into a cold air mass create mixing between warm moist and cold air leading to saturation

  5. Fog Types • Advection Fog • Steam fog (“Arctic sea smoke”) warm moist air in contact with relatively warm water mixes with cold air above producing saturation and condensation • Sea Fog – advection of warm moist air over a cold sea surface leads to mixing of warm moist and conduction cooled air producing saturation and fog • Advection of warm moist air over cold land surface leads to mixing of warm moist and conduction cooled air producing saturation and fog (e.g. warm air advection over a snow cover) • Land and sea breeze fog • Tropical air fog • Ice fog • Snow fog

  6. Role of Dew • Cooling of the surface causes moisture of the air in contact with the surface to be deposited as dew • This causes a net downward transport of moisture into the ground and the formation of a “dew point inversion” • The dew point inversion may inhibit fog formation • However, once the sun rises and the surface warms, the dew acts as a reservoir of water to allow fog to persist for several hours.

  7. Role of Droplet Settling • Small liquid droplets settle very slowly • Settling depletes liquid water content at top of fog and increases it below • This weakens radiative divergence at the top • Hence low CCN contents produce more settling (larger droplets) and lower water contents

  8. Radiation Fog • Radiation cools the surface, surface air cools by conduction • Radiation divergence across top of moist layer cools the air above, destabilizing air above • Static instability at layer top causes turbulence to overturn air, mixing cold air from below, forming saturation • Once cloud layer forms, radiational cooling at top of fog layer is greatly enhanced, further increasing overturning and increasing fog water content

  9. Valley Fog • Nocturnal radiation cooling along side walls produces sinking motion along sidewalls • Dew deposition at the surface creates a dew point inversion at the surface • Converging cold and somewhat dry air flows over the valley force upward motion and deepen the inversion • About 3 h before fog formation, mountain wind forms, providing continuity for the downslope flow, but restricting upward motion in valley center.

  10. Valley Fog (Cont'd) • Cooling is then capped to low and mid levels of the valley by the strengthening inversion • Radiation cooling at the top of the inversion layer leads to the formation of a thin cloud layer • The thin cloud layer enhances radiation divergence and deepens to the surface

  11. Marine Fog • Differs from Radiation fog: • Radiation does not rapidly affect surface temperature • Less CCN- more drizzle (Giant salt nuclei) • Moisture flux up • Heat flux down • Results of model experiments show: • Case 1: upward moisture flux, downward heat flux, i.e. cold water/warm air promotes fog • Case 2: upward heat and moisture flux, i.e. fog if air above is cold and moist

  12. Fog Produced ByMarine Stratus Lowering • Radiational cooling lowers base of stratus cloud:

  13. Fog Streets

  14. Marine Stratocumulus • Exist over Large spans of the eastern Pacific, eastern Atlantic and western Indian Oceans • These are upwelling regions of cool water so air naturally near saturation in marine PBL • These are also regions of large scale subsidence aloft

  15. Dynamics of Marine Stratocumulus • Subsidence Drying Aloft • Moistening from the cool ocean surface • Radiation divergence at top of marine PBL • Entrainment of low theta-e but high theta air from above PBL inversion

  16. Other Factors: • Drizzle: Weakens radiation divergence • Shear: enhances entrainment

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