Ship tracks

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Ship tracks can be seen as lines in these clouds over the Atlantic Ocean on the east coast of the United States. May 11, 2005
Atlantic ship tracks ESA389965.tiff

Ship tracks are clouds that form around the exhaust released by ships into the still ocean air.[1] Water molecules collect around the tiny particles (aerosols) from exhaust to form a cloud seed. More and more water accumulates on the seed until a visible cloud is formed. In the case of ship tracks, the cloud seeds are stretched over a long narrow path where the wind has blown the ship's exhaust, so the resulting clouds resemble long strings over the ocean.[2] Ship tracks are a type of homogenitus cloud.[3]

Ship tracks study[]

In 1965, the first "anomalous cloud lines" were observed in images from the TIROS VII satellite. It was hypothesized that the most likely cause was from the exhaust from ships.[4] Many studies since have confirmed the cause, and they are now referred to as ship tracks. Scientists soon realized that the climatic impacts from aerosols could have a large effect on climate through the Twomey effect,[5] and that ship tracks provided an excellent laboratory for their studies.

Scientists who study how human-produced aerosols affect cloud formation observe ship tracks because in most urban areas, they are unable to discern exactly how pollutants contribute to forming clouds because the atmosphere over the land is too tumultuous. In contrast, ships release their exhaust into the relatively clean and still marine air, where the scientists have an easier time of measuring the effects of fossil fuel emissions on cloud formation.

In general, the air above the oceans suffers from less turbulence and convection than the air above land. The lower atmosphere is especially calm over the eastern Pacific in the summertime due to a layer of hot air that settles in 500 to 700 meters above that region of the ocean. This effect creates a temperature inversion, placing a cap on the cooler air below, trapping pollutants and water vapor. While the inversion is responsible for the smog that reduces air quality in Los Angeles, it also allows for the formation of long lasting ship tracks. The particles billowing from ships' smokestacks enter the air above the eastern Pacific and create long, thin clouds that remain there for days. These clouds are a type known as homomutatus.[3]

Findings[]

Visible ship tracks in the Northern Pacific, on March 4th 2009.

It is theorised that sulfur dioxide released from ships' smokestacks could be forming sulfate aerosol particles in the atmosphere, which cause the clouds to be more reflective, carry more water and possibly stop precipitating.[6] This is regarded as proof that humans have been creating and modifying clouds for generations through the combustion of fossil fuels.

Although ship tracks can sometimes be visible, researchers usually scan the near-infrared light coming off the clouds. At this wavelength many ship tracks appear as bright lines that can be distinguished from the surrounding, uncontaminated clouds. On average, polluted clouds reflect more sunlight than their unaffected counterparts.

When compared to normal clouds, the number of water droplets per volume of air in ship tracks is more than doubled, the radius of the drops is decreased by roughly six percent and the total volume of liquid water per volume of air is increased twofold.[contradictory][citation needed] In other words, this excessive cloud seeding from the ship causes the clouds to retain more water. Normally, rain forms when cloud drops coagulate and reach a size at which gravity can pull them to the ground. Yet, in ship tracks, the cloud seeding makes the drops so small that they can no longer easily merge to reach the size needed to escape. Since no drizzle comes out of the seeded clouds, the liquid water just keeps building in the cloud. This makes the cloud brighter and more reflective to incoming sunlight, especially in the near-infrared part of the spectrum.

Discoveries from recent[when?] satellite observations of several hundred ship tracks revealed that approximately 25% had a lower cloud albedo (reflectivity) than the surrounding unpolluted clouds.[7] These dimmer ship tracks tended to have significantly less water despite the strong suppression of precipitation by the aerosol plume.[8] Dimmer ship tracks are hypothesized to occur when the air above the cloud tops is sufficiently dry. Smaller droplets in polluted clouds enhance cloud-top evaporation and entrainment. The polluted clouds thus engulf more of the overlying dry air causing them to rigorously evaporate and thin under dry meteorological conditions. Under a moist/unstable atmosphere the entrainment effect is smaller and the pollutants from the ship cause the clouds to thicken and the albedo to increase.[9]

See also[]

References[]

  1. ^ "Ship Tracks over the Atlantic". earthobservatory.nasa.gov. 2005-05-12. Retrieved 2018-09-11.
  2. ^ "Ship Tracks over the Atlantic". NASA Earth Observatory. Archived from the original on 2005-05-26. Retrieved 2006-05-11. Not available as NASA no longer supports Earth Observatory press releases (accession attempt 2017-09-21
  3. ^ Jump up to: a b Sutherland, Scott (March 23, 2017). "Cloud Atlas leaps into 21st century with 12 new cloud types". The Weather Network. Pelmorex Media. Retrieved 24 March 2017.
  4. ^ Conover, J.H. (1966). "Anomalous cloud lines". J. Atmos. Sci. 23 (6): 778–785. Bibcode:1966JAtS...23..778C. doi:10.1175/1520-0469(1966)023<0778:ACL>2.0.CO;2. ISSN 1520-0469.
  5. ^ Twomey, S. (1977). "The Influence of Pollution on the Shortwave Albedo of Clouds". J. Atmos. Sci. 34 (7): 1149–1152. Bibcode:1977JAtS...34.1149T. doi:10.1175/1520-0469(1977)034<1149:TIOPOT>2.0.CO;2. ISSN 1520-0469.
  6. ^ Albrecht, B.A. (1989). "Aerosols, Cloud Microphysics, and Fractional Cloudiness". Science. 245 (4923): 1227–1230. Bibcode:1989Sci...245.1227A. doi:10.1126/science.245.4923.1227. PMID 17747885. S2CID 46152332.
  7. ^ Chen, Y.C. (2012). "Occurrence of lower cloud albedo in ship tracks". Atmospheric Chemistry and Physics. 12 (17): 8223–8235. Bibcode:2012ACP....12.8223C. doi:10.5194/acp-12-8223-2012.
  8. ^ Christensen, M. W. (2012). "Microphysical and macrophysical responses of marine stratocumulus polluted by underlying ships: 2. Impacts of haze on precipitating clouds". Journal of Geophysical Research: Atmospheres. 117 (D11): n/a. Bibcode:2012JGRD..11711203C. doi:10.1029/2011JD017125.
  9. ^ Christensen, M. W. (2011). "Microphysical and macrophysical responses of marine stratocumulus polluted by underlying ships: Evidence of cloud deepening". Journal of Geophysical Research. 116 (D3): D03201. Bibcode:2011JGRD..116.3201C. doi:10.1029/2010JD014638.
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