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Earth Science 18.2 Cloud Formation

Earth Science 18.2 Cloud Formation . Cloud Formation . Cloud Formation . Recall that condensation occurs when water vapor changes to a liquid. Condensation may form dew , fog , or clouds. All clouds require saturated air before they can develop .

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Earth Science 18.2 Cloud Formation

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  1. Earth Science 18.2 Cloud Formation Cloud Formation

  2. Cloud Formation • Recall that condensation occurs when water vapor changes to a liquid. • Condensation may form dew, fog, or clouds. • All clouds require saturated air before they can develop. • Saturation occurs eitherwhen enough water vapor is added to air, or more commonly, when air is cooled to it’s dew point.

  3. Cloud Formation • Near Earth’s surface, heat is quickly exchanged between the ground and the air above. • During evening hours, the surface radiates heat away, causing the surface and adjacent air to cool rapidly. • This radiativecooling causes the formation of dewand some types of fog. • In contrast, clouds often form during the warmest part of the day. Clearly, some other process must cool air enough to generate clouds.

  4. Air Compression and Expansion • Using a pump or compressor,you may have noticed that the air hose gets hot where it connects to the pump or compressor. • The hot hose gets that way because of the work you did on the air to compress it. • When air is compressed, the motion of gas molecules increases and the air temperature rises.

  5. Air Compression and Expansion Adiabatic Temperature Changes • Temperature changes that happen even though heat isn’t added or subtracted are called adiabatic temperature changes. • They result when air is compressed (heats up)or allowed to expand (cool down). • Air expansion = Air cools • Air compressed = Air heats • (ie. Letting the air out of a tire or airing it up)

  6. Air Compression and Expansion Expansion and Cooling • As you travel from Earth’s surface upward through the atmosphere, the atmospheric pressure decreases. • This happens because there are fewer and fewer gas molecules. • Any time a volume of air moves upward, it passes through regions of successively lower pressure. • As altitude increases, the air expands and cools.

  7. Air Compression and Expansion Expansion and Cooling • In contrast, descending air encounters higher pressures, compresses and is heated10 degrees Celsius for every 1000 meters it moves downward. • This rate of cooling or heating only works with UNSATURATED AIR and is called the DRY ADIABATIC RATE.

  8. Air Compression and Expansion Expansion and Cooling • If a parcel of air rises high enough, it will eventually cool to it’s dew point and form water vapor. • Here the process of condensationbegins and clouds form. • From this point on as the air rises, the latent heat of condensation stored in the water vapor will be released. • Although the air will continue to cool after condensation begins, the released latent heat works against the adiabatic cooling process and the air cools at a slower rate.

  9. Air Compression and Expansion Expansion and Cooling • This slower rate of cooling caused by the addition of latent heat is called thewet adiabatic rate. • Because the amount of latent heat released depends on the quantity of moisture present in the air, the wet adiabatic rate varies from 5-9 degrees Celsius per 1000 meters.

  10. Air Compression and Expansion Expansion and Cooling • The diagram at right shows the role adiabatic cooling plays in the formation of clouds. • Note that from the surface up to the condensation level the air coolsat the dry adiabatic rate of 10 degrees Celsius per 1000 meters of rise. • Thewet adiabatic rate then begins where the condensation starts to occur; dropping only 5 degrees per 1000 meters of rise.

  11. Processes That Lift Air • In general, air resists vertical movement. • Air located near the surface tends to stay near the surface. Air far above the surface tends to stay far above the surface. • Some exceptions to this happen when conditions in the atmosphere make air buoyant enough to rise without the aid of outside forces. • In other words, clouds form when there is some mechanical process that forces air to rise. • Four forcesthat can force air to rise include orographic lifting, frontal wedging, convergence, and localized convective lifting. Orographic lifting

  12. Orographic Lifting • When elevated terrains, such as mountains, act as barriers to air-flow, orographic lifting of air occurs. • Look at the figure at right. As air goes up a mountain slope, adiabatic cooling occurs often creating clouds and precipitation. • Most of the rainiest places on earth are located on these windward mountain slopes. Orographic lifting

  13. Orographic Lifting • By the time air reaches the leeward side of a mountain, much of it’s moisture has been lost already. • If the air descends, it warms adiabatically making precipitation even less likely. • Because of this, a rain shadow desert can occur on the leeward side of mountains. • For example, the Great Basin Desert of the Western United States is only a few hundred kilometers from the moist winds coming off the Pacific. • This moisture is cut off by the Sierra Nevada Mountains however and never reaches past the mountains.

  14. Frontal Wedging • If orthographic lifting was the only mechanism that lifted air, the relatively flat central portion of North America would be an expansive desert instead of the nation’s primary food source. • In central North America, masses of warm air and cold air collide, producing a front. • Here the cooler denser air acts as a barrier over which the warmer, less dense air, rises. • This process, known as frontal wedging, is shown at right.

  15. Convergence • Recall that the collision of contrasting air masses forces hot air to rise. • In a more general sense, whenever air in the lower atmosphere flows together, liftingresults. • This is called convergence. • When air flows in from more than one direction, it must go somewhere. Because it can not go down, it goes up as shown at right. • This leads to adiabatic cooling and possible cloud formation.

  16. Convergence • The Florida Peninsula provides an example of how convergence can cause cloud development. • On warm days, the airflow is from the ocean to the land along both coasts of Florida. • This leads to a pileup of air along the coasts and general convergence over the peninsula. • This pattern of air movement and uplift that results is helped along by intense solar heating of the land. • The result is the peninsula of Florida receives the greatest number of mid-afternoon thunderstorms of any place in the United States. Convergence over Florida peninsula

  17. Localized Convective Lifting • On warm summer days, unequal heating of Earth’s surface may cause pockets of air to be warmed more than the surrounding air. • For example, air above a paved parking lot will be warmed more than air above an adjacent wooded park. • Consequently, the parcel of air that is above the parking lot , which is warmer and less dense than the surrounding air, will move upward. • These rising parcels of warmer air are called thermals.

  18. Localized Convective Lifting • The process that produces rising thermals is localized convection lifting. • Birds such as hawks or eagles use these thermals to carry themselves to great heights where they can gaze down on unsuspecting prey. • People have learned to use these thermals for sports such as hang gliding. • When these warm parcels of air rise above the condensation level, clouds form. • These clouds may create mid-afternoon showers.

  19. Stability • If a volume of air was forced to rise, it’s temperature would drop because of expansion. • If this volume of air was cooler than the surrounding atmosphere, it would be denser, and if allowed to do so it would sink back into it’s vertical position. • Air of this type, called stable air, resists vertical motion.

  20. Density Differences • If this imaginary volume of rising air was warmer and therefore less dense than the surrounding air, it would continue to rise until it reached an altitude where it’s temperature equaled that of it’s surrounding. • This is exactly how a hot air balloon works. • The balloon rises as long as it is warmer and less dense than surrounding air. • This type of air is classified as unstable air. • Stable air tends to stay in it’s position while unstable air tends to rise.

  21. Stability Measurements • Air stability is determined by measuring the temperature of the atmosphere at various heights. • The rate of change of air temperature with height is called the environmental lapse rate. • This rate is determined from observations made by aircraft and by radiosondes. • A radiosondeis an instrument designed to collect weather data high in the atmosphere. • Radiosondes are often carried into the atmosphere by balloons.

  22. Degrees of Stability • Air is stable when the temperature decreases gradually with increasing altitude. • The most stable conditions happen when temperature actually increases with height, called a temperature inversion. • Temperature inversions usually happen on clear nights as a result of radiation cooling off Earth’s surface. • The inversion is created because the ground, and air above the ground, will cool off more rapidly than air farther above the ground.

  23. Degrees of Stability • Under these conditions, there is very little vertical air movement rising or falling. • In contrast, air is considered unstable when the air close to the surface of Earth is significantly warmer than the air higher above the surface, indicating a large environmental lapse rate. • Under these conditions, the air actually turns over, as the warm air rises and is displaced by the colder air higher above the ground. The warm and cold air exchange places.

  24. Stability and daily weather • Recall that stable air resist vertical movement and that unstable air rises freely. How do these facts apply to our daily weather? • Because stable air resist upward movement, you might conclude that clouds won’t form when stable conditions are present. • Remember however that there are other forces that force air to rise, such as mountains that cause orographic lifting, frontal wedging and convergence. • When stable air is forced upward from Earth’s surface, the clouds that form are widespread and thin. Precipitation, if any, is very little. Frontal wedging Orograpic lifting convergence

  25. Stability and daily weather • In contrast, clouds associated with the lifting of unstable air are towering and often generate thunderstorms and occasionally even a tornado. • For this reason, on dreary overcast day with light drizzle, stable air has been forced above Earth’s surface. • During a day when cauliflower-shaped clouds appear to grow as if bubbles of hot air surged upwards, the air moving upward is unstable. thunderclouds

  26. Condensation • Recall that condensation happens when water vapor in the air changes to a liquid. • This may be in the form of dew, fog, or clouds. • For any of these forms of condensation to occur, the air must be saturated with water. • Saturation occurs most commonly when air is cooled to it’s dew point, or less often when water vapor is added to the air.

  27. Condensation Types of Surfaces: • Generally, there must be a surface for water vapor to condense on. • When dew forms, objects at or near the ground. Such as grass and car windows, serve this purpose. • But when condensation occurs in the air above the ground, tiny bits of particular matter , called condensation nuclei, serve as surfaces for water-vapor condensation to form around.

  28. Condensation Types of Surfaces: • Thesecondensation nuclei are important because if they are absent, a relative humidity much above 100 percent is needed to produce clouds. • Condensation nuclei such as microscopic dust, smoke, and salt particles from the ocean are abundant in the lower atmosphere. • Because of these plentiful particles, relative humidity rarely exceeds 100 percent. • Some particles, such as salt, are especially good nuclei because they absorb water.

  29. Condensation Types of Surfaces: • When condensation takes place, the initial growth rate of cloud droplets is rapid. • It diminishes quickly because the excess water vapor is quickly absorbed by the numerous competing particles. • This results in the formation of a cloud consisting of millions upon millions of tiny water droplets. • These droplets are all so fine that they remain suspended in air.

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