Ocean current

(Redirected from Sea current)

An ocean current is a continuous, directed movement of seawater generated by a number of forces acting upon the water, including wind, the Coriolis effect, breaking waves, cabbeling, and temperature and salinity differences.[1] Depth contours, shoreline configurations, and interactions with other currents influence a current's direction and strength. Ocean currents move both horizontally, on scales that can span entire oceans, as well as vertically, with vertical currents (upwelling and downwelling) playing an important role in the movement of nutrients and gases, such as carbon dioxide, between the surface and the deep ocean.

Ocean surface currents
Distinctive white lines trace the flow of surface currents around the world.
Visualization showing global ocean currents from January 1, 2010, to December 31, 2012, at sea level, then at 2,000 m (6,600 ft) below sea level
Animation of circulation around ice shelves of Antarctica

Ocean currents flow for great distances and together they create the global conveyor belt, which plays a dominant role in determining the climate of many of Earth's regions. More specifically, ocean currents influence the temperature of the regions through which they travel. For example, warm currents traveling along more temperate coasts increase the temperature of the area by warming the sea breezes that blow over them. Perhaps the most striking example is the Gulf Stream, which, together with its extension the North Atlantic Drift, makes northwest Europe much more temperate for its high latitude than other areas at the same latitude. Another example is Lima, Peru, whose cooler subtropical climate contrasts with that of its surrounding tropical latitudes because of the Humboldt Current.

The largest ocean current is the Antarctic Circumpolar Current (ACC), a wind-driven current which flows clockwise uninterrupted around Antarctica. The ACC connects all the ocean basins together, and also provides a link between the atmosphere and the deep ocean due to the way water upwells and downwells on either side of it.

Ocean currents are patterns of water movement that influence climate zones and weather patterns around the world. They are primarily driven by winds and by seawater density, although many other factors influence them – including the shape and configuration of the ocean basin they flow through. The two basic types of currents – surface and deep-water currents – help define the character and flow of ocean waters across the planet.

Causes

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The bathymetry of the Kerguelen Plateau in the Southern Ocean governs the course of the Kerguelen deep western boundary current, part of the global network of ocean currents.[2][3]

Ocean currents are driven by the wind, by the gravitational pull of the moon in the form of tides, and by the effects of variations in water density.[4] Ocean dynamics define and describe the motion of water within the oceans.

Ocean temperature and motion fields can be separated into three distinct layers: mixed (surface) layer, upper ocean (above the thermocline), and deep ocean. Ocean currents are measured in units of sverdrup (Sv), where 1 Sv is equivalent to a volume flow rate of 1,000,000 m3 (35,000,000 cu ft) per second.

There are two main types of currents, surface currents and deep water currents. Generally surface currents are driven by wind systems and deep water currents are driven by differences in water density due to variations in water temperature and salinity.[5]

Wind-driven circulation

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Surface oceanic currents are driven by wind currents, the large scale prevailing winds drive major persistent ocean currents, and seasonal or occasional winds drive currents of similar persistence to the winds that drive them,[6] and the Coriolis effect plays a major role in their development.[7] The Ekman spiral velocity distribution results in the currents flowing at an angle to the driving winds, and they develop typical clockwise spirals in the northern hemisphere and counter-clockwise rotation in the southern hemisphere.[8] In addition, the areas of surface ocean currents move somewhat with the seasons; this is most notable in equatorial currents.

Deep ocean basins generally have a non-symmetric surface current, in that the eastern equator-ward flowing branch is broad and diffuse whereas the pole-ward flowing western boundary current is relatively narrow.

Thermohaline circulation

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Coupling data collected by NASA/JPL by several different satellite-borne sensors, researchers have been able to "break through" the ocean's surface to detect "Meddies" – super-salty warm-water eddies that originate in the Mediterranean Sea and then sink more than a half-mile underwater in the Atlantic Ocean. The Meddies are shown in red in this scientific figure.

Large scale currents are driven by gradients in water density, which in turn depend on variations in temperature and salinity. This thermohaline circulation is also known as the ocean's conveyor belt. Where significant vertical movement of ocean currents is observed, this is known as upwelling and downwelling. The adjective thermohaline derives from thermo- referring to temperature and -haline referring to salt content, factors which together determine the density of seawater.

The thermohaline circulation is a part of the large-scale ocean circulation that is driven by global density gradients created by surface heat and freshwater fluxes.[9][10] Wind-driven surface currents (such as the Gulf Stream) travel polewards from the equatorial Atlantic Ocean, cooling en route, and eventually sinking at high latitudes (forming North Atlantic Deep Water). This dense water then flows into the ocean basins. While the bulk of it upwells in the Southern Ocean, the oldest waters (with a transit time of around 1000 years)[11] upwell in the North Pacific.[12] Extensive mixing therefore takes place between the ocean basins, reducing differences between them and making the Earth's oceans a global system. On their journey, the water masses transport both energy (in the form of heat) and matter (solids, dissolved substances and gases) around the globe. As such, the state of the circulation has a large impact on the climate of the Earth. The thermohaline circulation is sometimes called the ocean conveyor belt, the great ocean conveyor, or the global conveyor belt. On occasion, it is imprecisely used to refer to the meridional overturning circulation, (MOC).

Since the 2000s an international program called Argo has been mapping the temperature and salinity structure of the ocean with a fleet of automated platforms that float with the ocean currents. The information gathered will help explain the role the oceans play in the earth's climate.[13]

Effects on climate and ecology

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Ocean currents affect temperatures throughout the world. For example, the ocean current that brings warm water up the north Atlantic to northwest Europe also cumulatively and slowly blocks ice from forming along the seashores, which would also block ships from entering and exiting inland waterways and seaports, hence ocean currents play a decisive role in influencing the climates of regions through which they flow.[14] Ocean currents are important in the study of marine debris.[15][16]

 
Plankton are dispersed by ocean currents.

Upwellings and cold ocean water currents flowing from polar and sub-polar regions bring in nutrients that support plankton growth, which are crucial prey items for several key species in marine ecosystems.[17]

Ocean currents are also important in the dispersal and distribution of many organisms, inclusing those with pelagic egg or larval stages.[18] An example is the life-cycle of the European Eel. Terrestrial species, for example tortoises and lizards, can be carried on floating debris by currents to colonise new terrestrial areas and islands.[18]

Ocean currents and climate change

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The continued rise of atmospheric temperatures is anticipated to have various effects on the strength of surface ocean currents, wind-driven circulation and dispersal patterns.[19][20][21] Ocean currents play a significant role in influencing climate, and shifts in climate in turn impact ocean currents.[20]

 
Human-induced climate change is leading to long-term alterations in ocean and atmospheric circulation. The accumulation of greenhouse gases traps extra heat within the Earth’s system, causing both the atmosphere and oceans to warm. Notably, over 90% of this trapped heat is absorbed by the oceans. There are signs that crucial circulation patterns are shifting, with growing evidence suggesting that the Atlantic Meridional Overturning Circulation may be slowing down.

Over the last century, reconstructed sea surface temperature data reveal that western boundary currents are heating at double the rate of the global average.[22] These observations indicate that the western boundary currents are likely intensifying due to this change in temperature, and may continue to grow stronger in the near future.[20] There is evidence that surface warming due to anthropogenic climate change has accelerated upper ocean currents in 77% of the global ocean.[21] Specifically, increased vertical stratification due to surface warming intensifies upper ocean currents, while changes in horizontal density gradients caused by differential warming across different ocean regions results in the acceleration of surface zonal currents.[21]

There are suggestions that the Atlantic meridional overturning circulation (AMOC) is in danger of collapsing due to climate change, which would have extreme impacts on the climate of northern Europe and more widely,[23][24][25] although this topic is controversial and remains an active area of research.[26][27][28] The "State of the cryosphere" report, dedicates significant space to AMOC, saying it may be enroute to collapse because of ice melt and water warming. In the same time, the Antarctic Circumpolar Current (ACC) is also slowing down and is expected to lose 20% of it power by the year 2050, "with widespread impacts on ocean circulation and climate".[29] UNESCO mentions that the report in the first time "notes a growing scientific consensus that melting Greenland and Antarctic ice sheets, among other factors, may be slowing important ocean currents at both poles, with potentially dire consequences for a much colder northern Europe and greater sea-level rise along the U.S. East Coast."[30]

In addition to water surface temperatures, the wind systems are a crucial determinant of ocean currents.[31] Wind wave systems influence oceanic heat exchange, the condition of the sea surface, and can alter ocean currents.[32] In the North Atlantic, equatorial Pacific, and Southern Ocean, increased wind speeds as well as significant wave heights have been attributed to climate change and natural processes combined.[32] In the East Australian Current, global warming has also been accredited to increased wind stress curl, which intensifies these currents, and may even indirectly increase sea levels, due to the additional warming created by stronger currents.[33]

As ocean circulation changes due to climate, typical distribution patterns are also changing. The dispersal patterns of marine organisms depend on oceanographic conditions, which as a result, influence the biological composition of oceans.[19] Due to the patchiness of the natural ecological world, dispersal is a species survival mechanism for various organisms.[34] With strengthened boundary currents moving toward the poles, it is expected that some marine species will be redirected to the poles and greater depths.[19][35] The strengthening or weakening of typical dispersal pathways by increased temperatures are expected to not only impact the survival of native marine species due to inability to replenish their meta populations but also may increase the prevalence of invasive species.[19] In Japanese corals and macroalgae, the unusual dispersal pattern of organisms toward the poles may destabilize native species.[36]

Economic importance

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Knowledge of surface ocean currents is essential in reducing costs of shipping, since traveling with them reduces fuel costs. In the wind powered sailing-ship era, knowledge of wind patterns and ocean currents was even more essential. Using ocean currents to help their ships into harbor and using currents such as the gulf stream to get back home.[37] The lack of understanding of ocean currents during that time period is hypothesized to be one of the contributing factors to exploration failure. The Gulf Stream and the Canary current keep western European countries warmer and less variable, while at the same latitude North America's weather was colder.[38] A good example of this is the Agulhas Current (down along eastern Africa), which long prevented sailors from reaching India.

In recent times, around-the-world sailing competitors make good use of surface currents to build and maintain speed. Ocean currents can also be used for marine power generation, with areas of Japan, Florida and Hawaii being considered for test projects. The utilization of currents today can still impact global trade, it can reduce the cost and emissions of shipping vessels.[39]

 
Skipjack tuna fishery in Indonesia.

Ocean currents can also impact the fishing industry, examples of this include the Tsugaru, Oyashio and Kuroshio currents all of which influence the western North Pacific temperature, which has been shown to be a habitat predictor for the Skipjack tuna.[40] It has also been shown that it is not just local currents that can affect a country's economy, but neighboring currents can influence the viability of local fishing industries.[41]

Distribution

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A 1943 map of the world's ocean currents

Currents of the Arctic Ocean

Currents of the Atlantic Ocean

 
A recording current meter. It records information about currents (speed, direction, depth, temperature).

Currents of the Indian Ocean

Currents of the Pacific Ocean

Currents of the Southern Ocean

Oceanic gyres

See also

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References

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  1. ^ "What is a current?". NOAA's National Ocean Service. 2009-03-01. Retrieved 2023-03-14.
  2. ^ a b "Massive Southern Ocean current discovered". ScienceDaily. Apr 27, 2010.
  3. ^ a b Yasushi Fukamachi, Stephen Rintoul; et al. (Apr 2010). "Strong export of Antarctic Bottom Water east of the Kerguelen plateau". Nature Geoscience. 3 (5): 327–331. Bibcode:2010NatGe...3..327F. doi:10.1038/NGEO842. hdl:2115/44116. S2CID 67815755.
  4. ^ National Oceanic and Atmospheric Administration (16 June 2024). "What is a current?". oceanservice.noaa.gov. Retrieved 2024-09-03.
  5. ^ National Oceanic and Atmospheric Administration (1 August 2011). "Ocean currents". www.noaa.gov. Retrieved 2024-09-14.{{cite web}}: CS1 maint: date and year (link)
  6. ^ "Current". www.nationalgeographic.org. National Geographic. 2 September 2011. Retrieved 7 January 2021.
  7. ^ "Ocean Currents of the World: Causes". 29 August 2020. Retrieved 2020-11-20.
  8. ^ National Ocean Service (March 25, 2008). "Surface Ocean Currents". noaa.gov. National Oceanic and Atmospheric Administration. Archived from the original on July 6, 2017. Retrieved 2017-06-13.
  9. ^ Rahmstorf, S (2003). "The concept of the thermohaline circulation" (PDF). Nature. 421 (6924): 699. Bibcode:2003Natur.421..699R. doi:10.1038/421699a. PMID 12610602. S2CID 4414604.
  10. ^ Lappo, SS (1984). "On reason of the northward heat advection across the Equator in the South Pacific and Atlantic ocean". Study of Ocean and Atmosphere Interaction Processes. Moscow Department of Gidrometeoizdat (in Mandarin): 125–9.
  11. ^ The global ocean conveyor belt is a constantly moving system of deep-ocean circulation driven by temperature and salinity; What is the global ocean conveyor belt?
  12. ^ Primeau, F (2005). "Characterizing transport between the surface mixed layer and the ocean interior with a forward and adjoint global ocean transport model" (PDF). Journal of Physical Oceanography. 35 (4): 545–64. Bibcode:2005JPO....35..545P. doi:10.1175/JPO2699.1. S2CID 130736022.
  13. ^ Scripps Institution of Oceanography, UC San Diego. "Argo". Argo. Archived from the original on 1 September 2024. Retrieved 2024-09-05.
  14. ^ "What Is the Gulf Stream? | NOAA SciJinks – All About Weather". scijinks.gov. Retrieved 2024-04-15.
  15. ^ National Oceanic and Atmospheric Administration (1 April 2020). "Ocean pollution and marine debris". www.noaa.gov. Retrieved 2024-09-08.
  16. ^ van Sebille, Erik; Aliani, Stefano; Law, Kara Lavender; Maximenko, Nikolai; Alsina, José M; Bagaev, Andrei; Bergmann, Melanie; Chapron, Bertrand; Chubarenko, Irina; Cózar, Andrés; Delandmeter, Philippe; Egger, Matthias; Fox-Kemper, Baylor; Garaba, Shungudzemwoyo P; Goddijn-Murphy, Lonneke (2020-02-01). "The physical oceanography of the transport of floating marine debris". Environmental Research Letters. 15 (2): 023003. Bibcode:2020ERL....15b3003V. doi:10.1088/1748-9326/ab6d7d. hdl:2117/187082. ISSN 1748-9326.
  17. ^ Royce, William F., ed. (1996). "Circulation". Introduction to the Practice of Fishery Science. Elsevier. doi:10.1016/b978-0-12-600952-1.x5000-2. ISBN 978-0-12-600952-1.
  18. ^ a b Hays, Graeme C. (5 June 2017). "Ocean currents and marine life". Current Biology. 27 (11): R470–R473. Bibcode:2017CBio...27.R470H. doi:10.1016/j.cub.2017.01.044.
  19. ^ a b c d Wilson, Laura J.; Fulton, Christopher J.; Hogg, Andrew McC; Joyce, Karen E.; Radford, Ben T. M.; Fraser, Ceridwen I. (2016-05-02). "Climate-driven changes to ocean circulation and their inferred impacts on marine dispersal patterns". Global Ecology and Biogeography. 25 (8): 923–939. Bibcode:2016GloEB..25..923W. doi:10.1111/geb.12456. ISSN 1466-822X.
  20. ^ a b c Miller, Johanna L. (2017). "Ocean currents respond to climate change in unexpected ways". Physics Today. 70 (1): 17–18.
  21. ^ a b c Peng, Qihua; Xie, Shang-Ping; Wang, Dongxiao; Huang, Rui Xin; Chen, Gengxin; Shu, Yeqiang; Shi, Jia-Rui; Liu, Wei (2022-04-22). "Surface warming–induced global acceleration of upper ocean currents". Science Advances. 8 (16): eabj8394. Bibcode:2022SciA....8J8394P. doi:10.1126/sciadv.abj8394. ISSN 2375-2548. PMC 9020668. PMID 35442733.
  22. ^ Wu, Lixin; Cai, Wenju; Zhang, Liping; Nakamura, Hisashi; Timmermann, Axel; Joyce, Terry; McPhaden, Michael J.; Alexander, Michael; Qiu, Bo; Visbeck, Martin; Chang, Ping; Giese, Benjamin (2012-01-29). "Enhanced warming over the global subtropical western boundary currents". Nature Climate Change. 2 (3): 161–166. Bibcode:2012NatCC...2..161W. doi:10.1038/nclimate1353. hdl:1912/5125. ISSN 1758-6798.
  23. ^ Ditlevsen, Peter; Ditlevsen, Susanne (2023-07-25). "Warning of a forthcoming collapse of the Atlantic meridional overturning circulation". Nature Communications. 14: 4254. doi:10.1038/s41467-023-39810-w. ISSN 2041-1723. PMC 10368695. PMID 37491344.
  24. ^ Zhu, Chenyu; Liu, Zhengyu; Zhang, Shaoqing; Wu, Lixin (2023-03-04). "Likely accelerated weakening of Atlantic overturning circulation emerges in optimal salinity fingerprint". Nature Communications. 14 (1): 1245. doi:10.1038/s41467-023-36288-4. ISSN 2041-1723. PMC 9985640.
  25. ^ Boulton, Chris A.; Allison, Lesley C.; Lenton, Timothy M. (2014-12-08). "Early warning signals of Atlantic Meridional Overturning Circulation collapse in a fully coupled climate model". Nature Communications. 5 (1): 5752. doi:10.1038/ncomms6752. ISSN 2041-1723. PMC 4268699.
  26. ^ Science Media Centre (25 July 2023). "Expert reaction to paper warning of a collapse of the Atlantic meridional overturning circulation". Science Media Centre. Retrieved 2024-09-12.
  27. ^ Rahmstorf, Stefan (10 April 2024). "Is the Atlantic Overturning Circulation Approaching a Tipping Point?". Oceanography. 37 (3): 1–0. doi:10.5670/oceanog.2024.501.
  28. ^ Met Office Press (2 May 2024). "The Atlantic Meridional Overturning Circulation in a changing climate". Official blog of the Met Office news team. Retrieved 2024-09-12.
  29. ^ State of the Cryosphere 2024 Lost Ice, Global Damage (PDF). International Cryosphere Climate Initiative. November 2024. pp. x (in the beginning), 8, 48, 52. Retrieved 20 November 2024.
  30. ^ "State of the Cryosphere Report 2024 Lost Ice, Global Damage". UNESCO. Retrieved 20 November 2024.
  31. ^ Constantin, Adrian (2021-01-02). "Frictional effects in wind-driven ocean currents". Geophysical & Astrophysical Fluid Dynamics. 115 (1): 1–14. Bibcode:2021GApFD.115....1C. doi:10.1080/03091929.2020.1748614. ISSN 0309-1929.
  32. ^ a b Dobrynin, Mikhail; Murawski, Jens; Baehr, Johanna; Ilyina, Tatiana (2015-02-15). "Detection and Attribution of Climate Change Signal in Ocean Wind Waves". Journal of Climate. 28 (4): 1578–1591. Bibcode:2015JCli...28.1578D. doi:10.1175/JCLI-D-13-00664.1. ISSN 0894-8755.
  33. ^ Cai, W.; Shi, G.; Cowan, T.; Bi, D.; Ribbe, J. (2005-12-10). "The response of the Southern Annular Mode, the East Australian Current, and the southern mid-latitude ocean circulation to global warming". Geophysical Research Letters. 32 (23). Bibcode:2005GeoRL..3223706C. doi:10.1029/2005GL024701. ISSN 0094-8276.
  34. ^ Kininmonth, Stuart (2011-04-11). "Dispersal connectivity and reserve selection for marine conservation". Ecological Modelling. 222 (7): 1272–1282. Bibcode:2011EcMod.222.1272K. doi:10.1016/j.ecolmodel.2011.01.012.
  35. ^ Vergés, Adriana; Steinberg, Peter D.; Hay, Mark E.; Poore, Alistair G. B.; Campbell, Alexandra H.; Ballesteros, Enric; Heck, Kenneth L.; Booth, David J.; Coleman, Melinda A.; Feary, David A.; Figueira, Will; Langlois, Tim; Marzinelli, Ezequiel M.; Mizerek, Toni; Mumby, Peter J. (2014-08-22). "The tropicalization of temperate marine ecosystems: climate-mediated changes in herbivory and community phase shifts". Proceedings of the Royal Society B: Biological Sciences. 281 (1789): 20140846. doi:10.1098/rspb.2014.0846. ISSN 0962-8452. PMC 4100510. PMID 25009065.
  36. ^ Kumagai, Naoki H.; García Molinos, Jorge; Yamano, Hiroya; Takao, Shintaro; Fujii, Masahiko; Yamanaka, Yasuhiro (2018-09-04). "Ocean currents and herbivory drive macroalgae-to-coral community shift under climate warming". Proceedings of the National Academy of Sciences. 115 (36): 8990–8995. Bibcode:2018PNAS..115.8990K. doi:10.1073/pnas.1716826115. ISSN 0027-8424. PMC 6130349. PMID 30126981.
  37. ^ "Atlantic Ocean - Exploration, Currents, Marine Life | Britannica". www.britannica.com. Retrieved 2024-04-20.
  38. ^ US Department of Commerce, National Oceanic and Atmospheric Administration. "Boundary Currents - Currents: NOAA's National Ocean Service Education". oceanservice.noaa.gov. Retrieved 2024-04-20.
  39. ^ Chang, Yu-Chia; Tseng, Ruo-Shan; Chen, Guan-Yu; Chu, Peter C.; Shen, Yung-Ting (November 2013). "Ship Routing Utilizing Strong Ocean Currents". The Journal of Navigation. 66 (6): 825–835. doi:10.1017/S0373463313000441. ISSN 0373-4633.
  40. ^ Ramesh, Nandini; Rising, James A.; Oremus, Kimberly L. (2019-06-21). "The small world of global marine fisheries: The cross-boundary consequences of larval dispersal". Science. 364 (6446): 1192–1196. Bibcode:2019Sci...364.1192R. doi:10.1126/science.aav3409. ISSN 0036-8075. PMID 31221860.
  41. ^ Talley, Lynne D. (April 1, 1995). "North Pacific Intermediate Water in the Kuroshio/Oyashio Mixed Water Region". American Meteorological Society. 25 (4): 475–501. Bibcode:1995JPO....25..475T. doi:10.1175/1520-0485(1995)025<0475:NPIWIT>2.0.CO;2 – via AMS Publications.

Further reading

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