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Antarctic Circumpolar Current

January 01, 1970

Antarctic Circumpolar Current (ACC) is an ocean current that flows clockwise (as seen from the South Pole) from west to east around Antarctica. An alternative name for the ACC is the West Wind Drift. The ACC is the dominant circulation feature of the Southern Ocean and has a mean transport estimated at 100–150 Sverdrups (Sv, million m3/s),[1] or possibly even higher,[2] making it the largest ocean current. The current is circumpolar due to the lack of any landmass connecting with Antarctica and this keeps warm ocean waters away from Antarctica, enabling that continent to maintain its huge ice sheet.

Antarctic Circumpolar Current, showing branches connecting to the larger thermohaline circulation
Animation of the thermohaline circulation. The later part of this animation shows the Antarctic Circumpolar Current.

Associated with the Circumpolar Current is the Antarctic Convergence, where the cold Antarctic waters meet the warmer waters of the subantarctic, creating a zone of upwelling nutrients. These nurture high levels of phytoplankton with associated copepods and krill, and resultant food chains supporting fish, whales, seals, penguins, albatrosses, and a wealth of other species.

The ACC has been known to sailors for centuries; it greatly speeds up any travel from west to east, but makes sailing extremely difficult from east to west, although this is mostly due to the prevailing westerly winds. Jack London's story "Make Westing" and the circumstances preceding the mutiny on the Bounty poignantly illustrate the difficulty it caused for mariners seeking to round Cape Horn westbound on the clipper ship route from New York to California.[3] The eastbound clipper route, which is the fastest sailing route around the world, follows the ACC around three continental capes – Cape Agulhas (Africa), South East Cape (Australia), and Cape Horn (South America).

The current creates the Ross and Weddell gyres.

Structure edit

 
The Antarctic Circumpolar Current is the strongest current system in the world oceans and the only ocean current linking all major oceans: the Atlantic, Indian, and Pacific Oceans. Seawater density fronts after Orsi, Whitworth & Nowlin 1995.

The ACC connects the Atlantic, Pacific, and Indian Oceans, and serves as a principal pathway of exchange among them. The current is strongly constrained by landform and bathymetric features. To trace it starting arbitrarily at South America, it flows through the Drake Passage between South America and the Antarctic Peninsula and then is split by the Scotia Arc to the east, with a shallow warm branch flowing to the north in the Falkland Current and a deeper branch passing through the Arc more to the east before also turning to the north. Passing through the Indian Ocean, the current first retroflects the Agulhas Current to form the Agulhas Return Current before it is split by the Kerguelen Plateau, and then moving northward again. Deflection is also seen as it passes over the mid-ocean ridge in the Southeast Pacific.

Fronts edit

The current is accompanied by three fronts: the Subantarctic front (SAF), the Polar front (PF), and the Southern ACC front (SACC).[4] Furthermore, the waters of the Southern Ocean are separated from the warmer and saltier subtropical waters by the subtropical front (STF).[5]

The northern boundary of the ACC is defined by the northern edge of the SAF, this being the most northerly water to pass through Drake Passage and therefore be circumpolar. Much of the ACC transport is carried in this front, which is defined as the latitude at which a subsurface salinity minimum or a thick layer of unstratified Subantarctic mode water first appears, allowed by temperature dominating density stratification. Still further south lies the PF, which is marked by a transition to very cold, relatively fresh, Antarctic Surface Water at the surface. Here a temperature minimum is allowed by salinity dominating density stratification, due to the lower temperatures. Farther south still is the SACC, which is determined as the southernmost extent of Circumpolar Deep Water (temperature of about 2 °C at 400 m). This water mass flows along the shelfbreak of the western Antarctic Peninsula and thus marks the most southerly water flowing through Drake Passage and therefore circumpolar. The bulk of the transport is carried in the middle two fronts.

The total transport of the ACC at Drake Passage is estimated to be around 135 Sv, or about 135 times the transport of all the world's rivers combined. There is a relatively small addition of flow in the Indian Ocean, with the transport south of Tasmania reaching around 147 Sv, at which point the current is probably the largest on the planet.

Dynamics edit

The circumpolar current is driven by the strong westerly winds in the latitudes of the Southern Ocean.

 
The ACC (red circle near the middle of the image) in relation to the global thermohaline circulation (animation)

In latitudes where there are continents, winds blowing on light surface water can simply pile up light water against these continents. But in the Southern Ocean, the momentum imparted to the surface waters cannot be offset in this way. There are different theories on how the Circumpolar Current balances the momentum imparted by the winds. The increasing eastward momentum imparted by the winds causes water parcels to drift outward from the axis of the Earth's rotation (in other words, northward) as a result of the Coriolis force. This northward Ekman transport is balanced by a southward, pressure-driven flow below the depths of the major ridge systems. Some theories connect these flows directly, implying that there is significant upwelling of dense deep waters within the Southern Ocean, transformation of these waters into light surface waters, and a transformation of waters in the opposite direction to the north. Such theories link the magnitude of the Circumpolar Current with the global thermohaline circulation, particularly the properties of the North Atlantic.

Alternatively, ocean eddies, the oceanic equivalent of atmospheric storms, or the large-scale meanders of the Circumpolar Current may directly transport momentum downward in the water column. This is because such flows can produce a net southward flow in the troughs and a net northward flow over the ridges without requiring any transformation of density. In practice both the thermohaline and the eddy/meander mechanisms are likely to be important.

The current flows at a rate of about 4 km/h (2.5 mph) over the Macquarie Ridge south of New Zealand.[6] The ACC varies with time. Evidence of this is the Antarctic Circumpolar Wave, a periodic oscillation that affects the climate of much of the southern hemisphere.[7] There is also the Antarctic oscillation, which involves changes in the location and strength of Antarctic winds. Trends in the Antarctic Oscillation have been hypothesized to account for an increase in the transport of the Circumpolar Current over the past two decades.

Formation edit

Published estimates of the onset of the Antarctic Circumpolar Current vary, but it is commonly considered to have started at the Eocene/Oligocene boundary. The isolation of Antarctica and formation of the ACC occurred with the openings of the Tasmanian Passage and the Drake Passage. The Tasmanian Seaway separates East Antarctica and Australia, and is reported to have opened to water circulation 33.5 million years ago (Ma).[8] The timing of the opening of the Drake Passage, between South America and the Antarctic Peninsula, is more disputed; tectonic and sediment evidence show that it could have been open as early as pre-34 Ma,[9] estimates of the opening of the Drake passage are between 20 and 40 Ma.[10] The isolation of Antarctica by the current is credited by many researchers with causing the glaciation of Antarctica and global cooling in the Eocene epoch. Oceanic models have shown that the opening of these two passages limited polar heat convergence and caused a cooling of sea surface temperatures by several degrees; other models have shown that CO2 levels also played a significant role in the glaciation of Antarctica.[10][11]

Phytoplankton edit

 
The Falkland Current transports nutrient-rich cold waters from the ACC north toward the Brazil–Malvinas Confluence. Phytoplankton chlorophyll concentration are shown in blue (lower concentrations) and yellow (higher concentrations).

Antarctic sea ice cycles seasonally, in February–March the amount of sea ice is lowest, and in August–September the sea ice is at its greatest extent.[12] Ice levels have been monitored by satellite since 1973. Upwelling of deep water under the sea ice brings substantial amounts of nutrients. As the ice melts, the melt water provides stability and the critical depth is well below the mixing depth, which allows for a positive net primary production.[13] As the sea ice recedes epontic algae dominate the first phase of the bloom, and a strong bloom dominate by diatoms follows the ice melt south.[13]

Another phytoplankton bloom occurs more to the north near the Antarctic convergence, here nutrients are present from thermohaline circulation. Phytoplankton blooms are dominated by diatoms and grazed by copepods in the open ocean, and by krill closer to the continent. Diatom production continues through the summer, and populations of krill are sustained, bringing large numbers of cetaceans, cephalopods, seals, birds, and fish to the area.[13]

Phytoplankton blooms are believed to be limited by irradiance in the austral (southern hemisphere) spring, and by biologically available iron in the summer.[14] Much of the biology in the area occurs along the major fronts of the current, the Subtropical, Subantarctic, and the Antarctic Polar fronts, these are areas associated with well defined temperature changes.[15] Size and distribution of phytoplankton are also related to fronts. Microphytoplankton (>20 μm) are found at fronts and at sea ice boundaries, while nanophytoplankton (<20 μm) are found between fronts.[16]

Studies of phytoplankton stocks in the southern sea have shown that the Antarctic Circumpolar Current is dominated by diatoms, while the Weddell Sea has abundant coccolithophorids and silicoflagellates. Surveys of the SW Indian Ocean have shown phytoplankton group variation based on their location relative to the Polar Front, with diatoms dominating South of the front, and dinoflagellates and flagellates in higher populations North of the front.[16]

Some research has been conducted on Antarctic phytoplankton as a carbon sink. Areas of open water left from ice melt are good areas for phytoplankton blooms. The phytoplankton takes carbon from the atmosphere during photosynthesis. As the blooms die and sink, the carbon can be stored in sediments for thousands of years. This natural carbon sink is estimated to remove 3.5 million tonnes from the ocean each year. 3.5 million tonnes of carbon taken from the ocean and atmosphere is equivalent to 12.8 million tonnes of carbon dioxide.[17]

Studies edit

An expedition in May 2008 by 19 scientists[18] studied the geology and biology of eight Macquarie Ridge sea mounts, as well as the Antarctic Circumpolar Current to investigate the effects of climate change of the Southern Ocean. The circumpolar current merges the waters of the Atlantic, Indian, and Pacific Oceans and carries up to 150 times the volume of water flowing in all of the world's rivers. The study found that any damage on the cold-water corals nourished by the current will have a long-lasting effect.[6] After studying the circumpolar current it is clear that it strongly influences regional and global climate as well as underwater biodiversity.[19] The subject has been characterized recently as "the spectral peak of the global extra-tropical circulation at ≈ 10^4 kilometers".[20]

The current helps preserve wooden shipwrecks by preventing wood-boring "ship worms" from reaching targets such as Ernest Shackleton's ship, the Endurance.[21]

References edit

Notes edit

  1. ^ Smith et al. 2013
  2. ^ Donohue, K.A.; et al. (21 November 2016). "Mean Antarctic Circumpolar Current transport measured in Drake Passage". Geophysical Research Letters. 43 (11): 760. Bibcode:2016GeoRL..4311760D. doi:10.1002/2016GL070319. hdl:11336/47067.
  3. ^ London 1907
  4. ^ Stewart 2007
  5. ^ Orsi, Whitworth & Nowlin 1995, Introduction, p. 641
  6. ^ a b "Explorers marvel at 'Brittlestar City' on seamount in powerful current swirling around Antarctica". 18 May 2008. Retrieved 6 June 2008.
  7. ^ Connolley 2002
  8. ^ Hassold et al. 2009
  9. ^ Barker et al. 2007
  10. ^ a b Siegert et al. 2008
  11. ^ Stott 2011, See "Ancient Current Systems" illustrations at bottom of page
  12. ^ Geerts 1998
  13. ^ a b c Miller 2004, p. 219
  14. ^ Peloquin & Smith 2007
  15. ^ . GES DISC: Goddard Earth Sciences, Data & Information Services Center. May 2012. Archived from the original on 18 May 2015. Retrieved 13 August 2012.
  16. ^ a b Knox 2007, p. 23
  17. ^ Peck et al. 2010
  18. ^ O'Hara, Rowden & Williams 2008
  19. ^ Rintoul, Hughes & Olbers 2001, e.g. p. 271
  20. ^ Storer, B.A., Buzzicotti, M., Khatri, H. et al. Global energy spectrum of the general oceanic circulation. Nat Commun 13, 5314 (2022). https://doi.org/10.1038/s41467-022-33031-3. Retrieved 17 September 2022.
  21. ^ Glover et al. 2013

Sources edit

  • Barker, P. F.; Filippelli, G. M.; Florindo, F.; Martin, E. E.; Scher, H. D. (2007). "Onset and Role of the Antarctic Circumpolar Current" (PDF). Deep-Sea Research Part II. 54 (21): 2388–2398. Bibcode:2007DSRII..54.2388B. doi:10.1016/j.dsr2.2007.07.028.
  • Connolley, W. M. (2002). "Long-term variation of the Antarctic Circumpolar Wave". Journal of Geophysical Research. 107 (C4): 8076. Bibcode:2002JGRC..107.8076C. CiteSeerX 10.1.1.693.4116. doi:10.1029/2000JC000380.
  • Geerts, B. (1998). "Antarctic sea ice: seasonal and long-term changes". Department of Atmospheric science, University of Wyoming. Retrieved 29 December 2016.
  • Glover, A. G.; Wiklund, H.; Taboada, S.; Avila, C.; Cristobo, J.; Smith, C. R.; Kemp, K. M.; Jamieson, A. J.; Dahlgren, T. G. (2013). "Bone-eating worms from the Antarctic: the contrasting fate of whale and wood remains on the Southern Ocean seafloor". Proceedings of the Royal Society B. 280 (1768): 20131390. doi:10.1098/rspb.2013.1390. PMC 3757972. PMID 23945684.
    • Amos, Jonathan (14 August 2013). "Antarctic: Where 'zombies' thrive and shipwrecks are preserved". BBC News.
  • Hassold, N. J. C.; Rea, D. K.; Pluijm, B. A., van der; Parés, J. M. (2009). "A physical record of the Antarctic Circumpolar Current: late Miocene to recent slowing of abyssal circulation" (PDF). Palaeogeography, Palaeoclimatology, Palaeoecology. 275 (1–4): 28–36. Bibcode:2009PPP...275...28H. doi:10.1016/j.palaeo.2009.01.011.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  • Knox, G. A. (2007). Biology of the Southern Ocean. CRC Marine Biology Series. CRC Press. ISBN 9780849333941.
  • London, Jack (1907). "Make Westing". Literature Collection. Archived from the original on 27 January 2013. Retrieved 29 December 2016.
  • Miller, C. B. (2004). Biological Oceanography. Blackwell Publishing. ISBN 9780632055364.
  • O'Hara, T. D.; Rowden, A. A.; Williams, A. (2008). "Cold-water coral habitats on seamounts: do they have a specialist fauna?". Diversity and Distributions. 14 (6): 925–934. doi:10.1111/j.1472-4642.2008.00495.x. S2CID 86154159.
  • Orsi, A. H.; Whitworth, T.; Nowlin, W. D. Jr. (1995). "On the meridional extent and fronts of the Antarctic Circumpolar Current" (PDF). Deep-Sea Research. 42 (5): 641–673. Bibcode:1995DSRI...42..641O. doi:10.1016/0967-0637(95)00021-W.
  • Peck, L. S.; Barnes, D. K. A.; Cook, A. J.; Fleming, A. H.; Clarke, A. (2010). "Negative feedback in the cold: ice retreat produces new carbon sinks in Antarctica". Global Change Biology. 16 (9): 2614–2623. Bibcode:2010GCBio..16.2614P. doi:10.1111/j.1365-2486.2009.02071.x. S2CID 85748895. Retrieved 29 December 2016.
    • "Antarctica glacier retreat creates new carbon dioxide store; has beneficial impact on climate change". ScienceDaily (Press release). 10 November 2009.
  • Peloquin, J. A.; Smith, W. O. Jr. (2007). "Phytoplankton blooms in the Ross Sea, Antarctica: Interannual variability in magnitude, temporal patterns, and composition" (PDF). Journal of Geophysical Research: Oceans. 112 (C08013): C08013. Bibcode:2007JGRC..112.8013P. doi:10.1029/2006JC003816.
  • Rintoul, S. R.; Hughes, C.; Olbers, D. (2001). "The Antarctic Circumpolar Current System" (PDF). In Siedler, G.; Church, J.; Gould, J. (eds.). Ocean Circulation and Climate. New York: Academic Press. hdl:10013/epic.13233. ISBN 0-12-641351-7.
  • Siegert, M. J.; Barrett, P.; Deconto, R. M.; Dunbar, R.; Cofaigh, C. O.; Passchier, S.; Naish, T. (2008). "Recent Advances in Understanding Antarctic Climate Evolution". Antarctic Science. 20 (4): 313–325. Bibcode:2008AntSc..20..313S. CiteSeerX 10.1.1.210.9532. doi:10.1017/S0954102008000941. S2CID 18274113.
  • Smith, R.; Desflots, M.; White, S.; Mariano, A. J.; Ryan, E. H. (2013). "The Antarctic Circumpolar Current". Rosenstiel School of Marine & Atmospheric Science. Retrieved 29 December 2016.
  • Stewart, R. H. (2007). "Deep Circulation in the Ocean: Antarctic Circumpolar Current". Department of Oceanography, Texas A&M University. Archived from the original on 13 July 2012. Retrieved 29 December 2016.
  • Stott, L. D. (2011). "Ocean Currents and Climate". Department of Earth Sciences, University of Southern California. Retrieved 29 December 2016.

January 01, 1970
antarctic, circumpolar, current, ocean, current, that, flows, clockwise, seen, from, south, pole, from, west, east, around, antarctica, alternative, name, west, wind, drift, dominant, circulation, feature, southern, ocean, mean, transport, estimated, sverdrups. Antarctic Circumpolar Current ACC is an ocean current that flows clockwise as seen from the South Pole from west to east around Antarctica An alternative name for the ACC is the West Wind Drift The ACC is the dominant circulation feature of the Southern Ocean and has a mean transport estimated at 100 150 Sverdrups Sv million m3 s 1 or possibly even higher 2 making it the largest ocean current The current is circumpolar due to the lack of any landmass connecting with Antarctica and this keeps warm ocean waters away from Antarctica enabling that continent to maintain its huge ice sheet Antarctic Circumpolar Current showing branches connecting to the larger thermohaline circulation source source source source source Animation of the thermohaline circulation The later part of this animation shows the Antarctic Circumpolar Current Associated with the Circumpolar Current is the Antarctic Convergence where the cold Antarctic waters meet the warmer waters of the subantarctic creating a zone of upwelling nutrients These nurture high levels of phytoplankton with associated copepods and krill and resultant food chains supporting fish whales seals penguins albatrosses and a wealth of other species The ACC has been known to sailors for centuries it greatly speeds up any travel from west to east but makes sailing extremely difficult from east to west although this is mostly due to the prevailing westerly winds Jack London s story Make Westing and the circumstances preceding the mutiny on the Bounty poignantly illustrate the difficulty it caused for mariners seeking to round Cape Horn westbound on the clipper ship route from New York to California 3 The eastbound clipper route which is the fastest sailing route around the world follows the ACC around three continental capes Cape Agulhas Africa South East Cape Australia and Cape Horn South America The current creates the Ross and Weddell gyres Contents 1 Structure 1 1 Fronts 2 Dynamics 3 Formation 4 Phytoplankton 5 Studies 6 References 6 1 Notes 6 2 SourcesStructure edit nbsp The Antarctic Circumpolar Current is the strongest current system in the world oceans and the only ocean current linking all major oceans the Atlantic Indian and Pacific Oceans Seawater density fronts after Orsi Whitworth amp Nowlin 1995 The ACC connects the Atlantic Pacific and Indian Oceans and serves as a principal pathway of exchange among them The current is strongly constrained by landform and bathymetric features To trace it starting arbitrarily at South America it flows through the Drake Passage between South America and the Antarctic Peninsula and then is split by the Scotia Arc to the east with a shallow warm branch flowing to the north in the Falkland Current and a deeper branch passing through the Arc more to the east before also turning to the north Passing through the Indian Ocean the current first retroflects the Agulhas Current to form the Agulhas Return Current before it is split by the Kerguelen Plateau and then moving northward again Deflection is also seen as it passes over the mid ocean ridge in the Southeast Pacific Fronts edit The current is accompanied by three fronts the Subantarctic front SAF the Polar front PF and the Southern ACC front SACC 4 Furthermore the waters of the Southern Ocean are separated from the warmer and saltier subtropical waters by the subtropical front STF 5 The northern boundary of the ACC is defined by the northern edge of the SAF this being the most northerly water to pass through Drake Passage and therefore be circumpolar Much of the ACC transport is carried in this front which is defined as the latitude at which a subsurface salinity minimum or a thick layer of unstratified Subantarctic mode water first appears allowed by temperature dominating density stratification Still further south lies the PF which is marked by a transition to very cold relatively fresh Antarctic Surface Water at the surface Here a temperature minimum is allowed by salinity dominating density stratification due to the lower temperatures Farther south still is the SACC which is determined as the southernmost extent of Circumpolar Deep Water temperature of about 2 C at 400 m This water mass flows along the shelfbreak of the western Antarctic Peninsula and thus marks the most southerly water flowing through Drake Passage and therefore circumpolar The bulk of the transport is carried in the middle two fronts The total transport of the ACC at Drake Passage is estimated to be around 135 Sv or about 135 times the transport of all the world s rivers combined There is a relatively small addition of flow in the Indian Ocean with the transport south of Tasmania reaching around 147 Sv at which point the current is probably the largest on the planet Dynamics editThe circumpolar current is driven by the strong westerly winds in the latitudes of the Southern Ocean nbsp The ACC red circle near the middle of the image in relation to the global thermohaline circulation animation In latitudes where there are continents winds blowing on light surface water can simply pile up light water against these continents But in the Southern Ocean the momentum imparted to the surface waters cannot be offset in this way There are different theories on how the Circumpolar Current balances the momentum imparted by the winds The increasing eastward momentum imparted by the winds causes water parcels to drift outward from the axis of the Earth s rotation in other words northward as a result of the Coriolis force This northward Ekman transport is balanced by a southward pressure driven flow below the depths of the major ridge systems Some theories connect these flows directly implying that there is significant upwelling of dense deep waters within the Southern Ocean transformation of these waters into light surface waters and a transformation of waters in the opposite direction to the north Such theories link the magnitude of the Circumpolar Current with the global thermohaline circulation particularly the properties of the North Atlantic Alternatively ocean eddies the oceanic equivalent of atmospheric storms or the large scale meanders of the Circumpolar Current may directly transport momentum downward in the water column This is because such flows can produce a net southward flow in the troughs and a net northward flow over the ridges without requiring any transformation of density In practice both the thermohaline and the eddy meander mechanisms are likely to be important The current flows at a rate of about 4 km h 2 5 mph over the Macquarie Ridge south of New Zealand 6 The ACC varies with time Evidence of this is the Antarctic Circumpolar Wave a periodic oscillation that affects the climate of much of the southern hemisphere 7 There is also the Antarctic oscillation which involves changes in the location and strength of Antarctic winds Trends in the Antarctic Oscillation have been hypothesized to account for an increase in the transport of the Circumpolar Current over the past two decades Formation editPublished estimates of the onset of the Antarctic Circumpolar Current vary but it is commonly considered to have started at the Eocene Oligocene boundary The isolation of Antarctica and formation of the ACC occurred with the openings of the Tasmanian Passage and the Drake Passage The Tasmanian Seaway separates East Antarctica and Australia and is reported to have opened to water circulation 33 5 million years ago Ma 8 The timing of the opening of the Drake Passage between South America and the Antarctic Peninsula is more disputed tectonic and sediment evidence show that it could have been open as early as pre 34 Ma 9 estimates of the opening of the Drake passage are between 20 and 40 Ma 10 The isolation of Antarctica by the current is credited by many researchers with causing the glaciation of Antarctica and global cooling in the Eocene epoch Oceanic models have shown that the opening of these two passages limited polar heat convergence and caused a cooling of sea surface temperatures by several degrees other models have shown that CO2 levels also played a significant role in the glaciation of Antarctica 10 11 Phytoplankton edit nbsp The Falkland Current transports nutrient rich cold waters from the ACC north toward the Brazil Malvinas Confluence Phytoplankton chlorophyll concentration are shown in blue lower concentrations and yellow higher concentrations Antarctic sea ice cycles seasonally in February March the amount of sea ice is lowest and in August September the sea ice is at its greatest extent 12 Ice levels have been monitored by satellite since 1973 Upwelling of deep water under the sea ice brings substantial amounts of nutrients As the ice melts the melt water provides stability and the critical depth is well below the mixing depth which allows for a positive net primary production 13 As the sea ice recedes epontic algae dominate the first phase of the bloom and a strong bloom dominate by diatoms follows the ice melt south 13 Another phytoplankton bloom occurs more to the north near the Antarctic convergence here nutrients are present from thermohaline circulation Phytoplankton blooms are dominated by diatoms and grazed by copepods in the open ocean and by krill closer to the continent Diatom production continues through the summer and populations of krill are sustained bringing large numbers of cetaceans cephalopods seals birds and fish to the area 13 Phytoplankton blooms are believed to be limited by irradiance in the austral southern hemisphere spring and by biologically available iron in the summer 14 Much of the biology in the area occurs along the major fronts of the current the Subtropical Subantarctic and the Antarctic Polar fronts these are areas associated with well defined temperature changes 15 Size and distribution of phytoplankton are also related to fronts Microphytoplankton gt 20 mm are found at fronts and at sea ice boundaries while nanophytoplankton lt 20 mm are found between fronts 16 Studies of phytoplankton stocks in the southern sea have shown that the Antarctic Circumpolar Current is dominated by diatoms while the Weddell Sea has abundant coccolithophorids and silicoflagellates Surveys of the SW Indian Ocean have shown phytoplankton group variation based on their location relative to the Polar Front with diatoms dominating South of the front and dinoflagellates and flagellates in higher populations North of the front 16 Some research has been conducted on Antarctic phytoplankton as a carbon sink Areas of open water left from ice melt are good areas for phytoplankton blooms The phytoplankton takes carbon from the atmosphere during photosynthesis As the blooms die and sink the carbon can be stored in sediments for thousands of years This natural carbon sink is estimated to remove 3 5 million tonnes from the ocean each year 3 5 million tonnes of carbon taken from the ocean and atmosphere is equivalent to 12 8 million tonnes of carbon dioxide 17 Studies editAn expedition in May 2008 by 19 scientists 18 studied the geology and biology of eight Macquarie Ridge sea mounts as well as the Antarctic Circumpolar Current to investigate the effects of climate change of the Southern Ocean The circumpolar current merges the waters of the Atlantic Indian and Pacific Oceans and carries up to 150 times the volume of water flowing in all of the world s rivers The study found that any damage on the cold water corals nourished by the current will have a long lasting effect 6 After studying the circumpolar current it is clear that it strongly influences regional and global climate as well as underwater biodiversity 19 The subject has been characterized recently as the spectral peak of the global extra tropical circulation at 10 4 kilometers 20 The current helps preserve wooden shipwrecks by preventing wood boring ship worms from reaching targets such as Ernest Shackleton s ship the Endurance 21 References editNotes edit Smith et al 2013 Donohue K A et al 21 November 2016 Mean Antarctic Circumpolar Current transport measured in Drake Passage Geophysical Research Letters 43 11 760 Bibcode 2016GeoRL 4311760D doi 10 1002 2016GL070319 hdl 11336 47067 London 1907 Stewart 2007 Orsi Whitworth amp Nowlin 1995 Introduction p 641 a b Explorers marvel at Brittlestar City on seamount in powerful current swirling around Antarctica 18 May 2008 Retrieved 6 June 2008 Connolley 2002 Hassold et al 2009 Barker et al 2007 a b Siegert et al 2008 Stott 2011 See Ancient Current Systems illustrations at bottom of page Geerts 1998 a b c Miller 2004 p 219 Peloquin amp Smith 2007 The Southern Ocean GES DISC Goddard Earth Sciences Data amp Information Services Center May 2012 Archived from the original on 18 May 2015 Retrieved 13 August 2012 a b Knox 2007 p 23 Peck et al 2010 O Hara Rowden amp Williams 2008 Rintoul Hughes amp Olbers 2001 e g p 271 Storer B A Buzzicotti M Khatri H et al Global energy spectrum of the general oceanic circulation Nat Commun 13 5314 2022 https doi org 10 1038 s41467 022 33031 3 Retrieved 17 September 2022 Glover et al 2013 Sources edit Barker P F Filippelli G M Florindo F Martin E E Scher H D 2007 Onset and Role of the Antarctic Circumpolar Current PDF Deep Sea Research Part II 54 21 2388 2398 Bibcode 2007DSRII 54 2388B doi 10 1016 j dsr2 2007 07 028 Connolley W M 2002 Long term variation of the Antarctic Circumpolar Wave Journal of Geophysical Research 107 C4 8076 Bibcode 2002JGRC 107 8076C CiteSeerX 10 1 1 693 4116 doi 10 1029 2000JC000380 Geerts B 1998 Antarctic sea ice seasonal and long term changes Department of Atmospheric science University of Wyoming Retrieved 29 December 2016 Glover A G Wiklund H Taboada S Avila C Cristobo J Smith C R Kemp K M Jamieson A J Dahlgren T G 2013 Bone eating worms from the Antarctic the contrasting fate of whale and wood remains on the Southern Ocean seafloor Proceedings of the Royal Society B 280 1768 20131390 doi 10 1098 rspb 2013 1390 PMC 3757972 PMID 23945684 Amos Jonathan 14 August 2013 Antarctic Where zombies thrive and shipwrecks are preserved BBC News Hassold N J C Rea D K Pluijm B A van der Pares J M 2009 A physical record of the Antarctic Circumpolar Current late Miocene to recent slowing of abyssal circulation PDF Palaeogeography Palaeoclimatology Palaeoecology 275 1 4 28 36 Bibcode 2009PPP 275 28H doi 10 1016 j palaeo 2009 01 011 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Knox G A 2007 Biology of the Southern Ocean CRC Marine Biology Series CRC Press ISBN 9780849333941 London Jack 1907 Make Westing Literature Collection Archived from the original on 27 January 2013 Retrieved 29 December 2016 Miller C B 2004 Biological Oceanography Blackwell Publishing ISBN 9780632055364 O Hara T D Rowden A A Williams A 2008 Cold water coral habitats on seamounts do they have a specialist fauna Diversity and Distributions 14 6 925 934 doi 10 1111 j 1472 4642 2008 00495 x S2CID 86154159 Orsi A H Whitworth T Nowlin W D Jr 1995 On the meridional extent and fronts of the Antarctic Circumpolar Current PDF Deep Sea Research 42 5 641 673 Bibcode 1995DSRI 42 641O doi 10 1016 0967 0637 95 00021 W Peck L S Barnes D K A Cook A J Fleming A H Clarke A 2010 Negative feedback in the cold ice retreat produces new carbon sinks in Antarctica Global Change Biology 16 9 2614 2623 Bibcode 2010GCBio 16 2614P doi 10 1111 j 1365 2486 2009 02071 x S2CID 85748895 Retrieved 29 December 2016 Antarctica glacier retreat creates new carbon dioxide store has beneficial impact on climate change ScienceDaily Press release 10 November 2009 Peloquin J A Smith W O Jr 2007 Phytoplankton blooms in the Ross Sea Antarctica Interannual variability in magnitude temporal patterns and composition PDF Journal of Geophysical Research Oceans 112 C08013 C08013 Bibcode 2007JGRC 112 8013P doi 10 1029 2006JC003816 Rintoul S R Hughes C Olbers D 2001 The Antarctic Circumpolar Current System PDF In Siedler G 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