Bergeron process
The Bergeron–Findeisen process (after Tor Bergeron and W. Findeisen), also known as the cold rain or ice crystal process, is the formation of precipitation in the cold clouds of the mid and upper latitudes by ice crystal growth. The equilibrium vapor pressure over water is greater than the saturation vapor pressure over ice, at the same temperature. Therefore in a mixed phase cloud, the liquid water will be out of vapor pressure equilibrium and will evaporate to reach equilibrium. The water droplets will move toward the lower pressure over the ice and diffuse onto the ice crystals. The vapor will be condensed and freeze onto the ice crystal, causing it to grow larger.
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[edit] Conditions needed
In order for the Bergeron Process to occur, supercooled water droplets and ice crystals must be present together in the cloud.
[edit] Formation of ice crystals
The most common way to form an ice crystal, starts with an ice nucleus in the cloud. Ice crystals can form from heterogeneous deposition, contact, immersion, or freezing after condensation. In heterogeneous deposition, an ice nucleus is simply coated with water. For contact, ice nuclei will collide with water droplets that freeze upon impact. During immersion, an ice nucleus will hit a water droplet and instantly freeze it. Water can also condense onto ice nuclei and then freeze.
Water will freeze at different temperatures depending upon the type of ice nuclei present. Ice nuclei cause water to freeze at higher temperatures then it would spontaneously. For pure water to freeze spontaneously, called homogenous nucleation, cloud temperatures would have to be -42 degrees Celsius.[1] Here are some examples of ice nuclei:
| Ice Nuclei | Temperature to Freeze(degrees C) |
|---|---|
| Bacteria | -2.6 |
| Kaolinite | -4 |
| Silver Iodide | -7 |
| Vaterite | -9 |
[edit] Ice Multiplication
As the ice crystals grow, they can bump into each other and splinter and fracture, resulting in many new ice crystals. There are many shapes of ice crystals to bump into each other. These shapes include hexagons, cubes, columns, and dendrites. This process is referred to as "Ice Enhancement" by Atmospheric Physicists and Chemists.[2]
[edit] Aggregation
The process of ice crystals sticking together is called aggregation. This happens when ice crystals are slick or sticky at temperatures of -5 degrees Celsius and above, because of a coating of water surrounding the crystal. The different sizes and shapes of ice crystals fall at different terminal velocities and commonly collide and stick.
[edit] Accretion
When an ice crystal collides with supercooled water its called accretion. Droplets freeze upon impact and can form graupel. If the graupel formed is reintroduced into the cloud by wind, it may continue to grow larger and more dense, eventually forming hail.[3]
[edit] Precipitation
Eventually this ice crystal will grow large enough to fall. It may even collide with other ice crystals and grow larger still through collision coalescence, aggregation, or accretion.
The Bergeron Process often results in precipitation. As the crystals grow and fall, they pass through the base of the cloud, which may be above freezing. This causes the crystals to melt and fall as rain. There also may be a layer of air below freezing below the cloud base, causing the precipitation to refreeze in the form of ice pellets. Similarly, the layer of air below freezing may be at the surface, causing the precipitation to fall as freezing rain. The process may also result in no precipitation, evaporating before it reaches the ground, in the case of forming virga.
[edit] See also
- List of meteorology topics
- Precipitation (meteorology)
- Coalescence (meteorology)
- Ice nucleus
- Ice
- Nucleation
- Physical vapor deposition
- Saturation vapor pressure
[edit] References
- ^ Koop, T. (March 25, 2004). "Homogeneous ice nucleation in water and aqueous solutions". Zeitschrift für physikalische Chemie 218 (11): 1231–1258. http://cat.inist.fr/?aModele=afficheN&cpsidt=16233451. Retrieved 2008-04-07.
- ^ Microphysics of clouds and precipitation. Pruppacher, Hans R., Keltt, James, 1965
- ^ Microphysics of clouds and precipitation. Pruppacher, Hans R., Keltt, James, 1965
- Wallace, John M. and Peter V. Hobbs: Atmospheric Science, 2006. ISBN 0-12-732951-X
- Yau, M.K. and Rodgers, R.R.: "A Short Course in Cloud Physics", 1989. ISBN 0-75-0632151
