Eco-1058: Agulhas Current
Source: Wikipedia
The Agulhas Current (/əˈɡʌləs/) is the western boundary current of the southwest Indian Ocean. It flows south along the east coast of Africa from 27°S to 40°S. It is narrow, swift and strong. It is suggested that it is the largest western boundary current in the world ocean, with an estimated net transport of 70 sverdrups (70 million cubic metres per second), as western boundary currents at comparable latitudes transport less — Brazil Current (16.2 Sv), Gulf Stream (34 Sv), Kuroshio (42 Sv).[1]
Physical properties
The sources of the Agulhas Current are the East Madagascar Current (25 Sv), the Mozambique Current (5 Sv) and a recirculated part of the south-west Indian subgyre south of Madagascar (35 Sv).[2] The net transport of the Agulhas Current is estimated as 100 Sv. The flow of the Agulhas Current is directed by the topography. The current follows the continental shelf from Maputo to the tip of the Agulhas Bank (250 km south of Cape Agulhas). Here the momentum of the current overcomes the vorticity balance holding the current to the topography and the current leaves the shelf.[3] The current reaches its maximum transport near the Agulhas Bank where it ranges between 95 and 136 Sv.[4]
The core of the current is defined as where the surface velocities reach 100 cm/s (39 in/s), which gives the core an average width of 34 km (21 mi). The mean peak speed is 136 cm/s (54 in/s), but the current can reach 245 cm/s (96 in/s).[4]
Agulhas meanders and Natal pulses
As the Agulhas Current flows south along the African east coast, it tends to bulge inshore frequently, a deviation from the current's normal path known as Agulhas Current meanders (ACM). These bulges are occasionally (1-7 times per year) followed by a much larger offshore bulge, known as Natal pulses (NP). Natal pulses move along the coast at 20 km (12 mi) per day. An ACM can bulge up to 20 km (12 mi) and a NP up to 120 km (75 mi) from the current's mean position.[5] The AC passes 34 km (21 mi) offshore and an ACM can reach 123 km (76 mi) offshore. When the AC meanders, its width broadens from 88 km (55 mi) to 125 km (78 mi) and its velocity weakens from 208 cm/s (82 in/s) to 136 cm/s (54 in/s). An ACM induces a strong inshore counter-current.[6]
Large-scale cyclonic meanders known as Natal pulses are formed as the Agulhas Current reaches the continental shelf on the South African east-coast (i.e. the eastern Agulhas Bank off Natal). As these pulses moves along the coast on the Agulhas Bank, they tend to pinch off Agulhas rings from the Agulhas Current. Such a ring shedding can be triggered by a Natal pulse alone, but sometimes meanders on the Agulhas Return Current merge to contribute to the shedding of an Agulhas ring.[7]
Retroflection
In the southeast Atlantic Ocean the current retroflects (turns back on itself) in the Agulhas Retroflection due to shear interactions with the strong Antarctic Circumpolar Current, also known as the "West Wind Drift" despite referring to the ocean current rather than to the surface winds. This water becomes the Agulhas Return Current, rejoining the Indian Ocean Gyre. It is estimated that up to 85 Sv (Sv) of the net transport is returned to the Indian Ocean through the retroflection. The remaining water is transported into the South Atlantic Gyre in the Agulhas Leakage. Along with direct branch currents, this leakage takes place in surface water filaments, and Agulhas Eddies.
Agulhas leakage and rings
It is estimated that as much as 15 Sv of Indian Ocean water is leaked directly into the South Atlantic. 10 Sv of this is relatively warm, salty thermocline water, with the remaining 5 Sv being cold, low salinity Antarctic Intermediate Water. Since Indian Ocean water is significantly warmer (24-26 °C) and saltier than South Atlantic water, the Agulhas Leakage is a significant source of salt and heat for the South Atlantic Gyre. This heat flux is believed to contribute to the high rate of evaporation in the South Atlantic, a key mechanism in the Meridional Overturning Circulation. A small amount of the Agulhas Leakage joins the North Brazil Current, carrying Indian Ocean water into the North Atlantic Subtropical Gyre.[3] Before reaching the Caribbean Sea, this leakage gets heated up by the sun around the equator, and, when finally joining the Gulf Stream, this warm and salty water contributes to the formation of deep water in the North Atlantic.[8]
Surface water filaments are estimated to account for up to 13% of the total salt transport from the Agulhas Current into the Benguela Current and South Atlantic Gyre. Due to surface dissipation, these filaments are not believed to significantly contribute to inter-basin heat flux.[3]
Where the Agulhas turns back on itself the loop of the retroflection pinches off periodically, releasing an eddy into the South Atlantic Gyre. These "Agulhas Rings" enter the flow of the Benguela Current or are advected northwestward across the South Atlantic where they join the South Equatorial Current, where they dissipate into the larger background currents. These anticyclonic warm core rings are estimated to have a transport of 3-9 Sv each, in total injecting salt at a rate of 2.5106 kg/s and heat at a rate of 45 TW.[3]
Paleoclimate
Since the Pleistocene, the buoyancy of the South Atlantic thermocline and the strength of the Atlantic meridional overturning circulation has been regulated by the shedding of warm, saline Agulhas Rings. The Agulhas leakage affects the Atlantic thermocline on a decadal timescale and over centuries it can change the buoyancy of the Atlantic thermocline and therefore the formation rates of North Atlantic Deep Water (NADW).[9]
The provenance of ocean sediments can be determined by analysing terrigenous strontium isotope ratios in deep ocean cores. Sediments underlying the Agulhas Current and Return Current have significantly higher ratios than surrounding sediments. Franzese et al. 2009 analysed cores in the South Atlantic deposited during the Last Glacial Maximum (LGM, 20 000 years ago), and concluded that the Agulhas leakage was significantly reduced.[10] The trajectory of the current was the same during the LGM and that the reduced leakage must be explained by a weaker current.[11] Furthermore, it can be predicted that a stronger Agulhas Current will result in a more eastward retroflection and an increased Agulhas leakage. Simon et al. 2013, however, noted that changes in temperature and salinity in the Agulhas leakage is at least partly the result of variability in the composition in the current itself and can be a poor indicator of the strength of the leakage.[12]
Rogue waves
The south-east coast of South Africa is on the main shipping route between the Middle-East and Europe/the U.S. and even large ships have sustained major damage because of rogue waves in the area where these waves occasionally can reach a height of more than 30 m (98 ft). Some 30 larger ships were severely damaged or sunk by rogue waves along the South African east-coast between 1981 and 1991.[13]
Agulhas Undercurrent
Directly under the core of the Agulhas Current, at a depth of 800 m (2,600 ft), there is an Agulhas Undercurrent which flows equatorward.[14] The undercurrent is 2,000 m (6,600 ft) deep and 40 km (25 mi) wide and can reach 90 cm/s (35 in/s) at 1,400 metres (4,600 ft), one of greatest speeds observed in any current at this depth, but it also displays a great variance with a transport of 4.2±5.2 Sv. The undercurrent can represent as much as 40% of the Indian Ocean overturning transport.[15]
Below 1,800 m (5,900 ft) a separate layer of the undercurrent can be distinguished: the more coherent North Atlantic Deep Water (NADW) which transports an average of 2.3±3.0 Sv.[15] NADW rounds the southern tip of Africa after which the major part (9 Sv) flow eastward and a smaller part (2 Sv) northward through the Agulhas Undercurrent and into the Natal Valley (the basin between South Africa and the Mocambique Plateau); remnants of NADW has been observed in the Mozambique Basin and Channel. The undercurrent is more leaky than the Agulhas above, resulting in a relatively well-mixed composition of water masses — at intermediate depth there is a mixture of Antarctic Intermediate Water and Read Sea Water.[16]
The periodicity of the meanders and Natal pulses of the Agulhas is matched by the Agulhas Undercurrent.[15] More research is needed but observations seem to indicate that during a meander event the Agulhas moves first onshore, then offshore, and finally onshore again, first weakening then strengthening 10-15 Sv. At the same time the undercurrent is first squeezed offshore and weakened when the Agulhas moves onshore, then strengthened and forced upward when the Agulhas moves offshore, and finally returns to normal.[16]
Biological properties
Primary production
The Agulhas acts as an oceanic convergence zone. Due to mass continuity this drives surface waters down, resulting in the upwelling of cold, nutrient rich water south of the current. Additionally, the convergence tends to increase the concentration of plankton in and around the Agulhas. Both of these factors result in the area being one of enhanced primary productivity as compared to the surrounding waters. This is especially notable in the Agulhas Retroflection waters, where chlorophyll-a concentrations tend to be significantly higher than the surrounding South Indian Ocean and South Atlantic Ocean waters.[17]
Impact of rings
Warm core rings are known to have lower primary productivity than surrounding cold waters. Agulhas Rings are no exception, and have been observed to carry waters with low chlorophyll-a concentration water into the South Atlantic. The size of phytoplankton in Agulhas Rings tends to be smaller than in the surrounding water (around 20 μm in diameter).[17]
Agulhas Rings have also been observed as removing larval and juvenile fish from the continental shelf. This removal of young fish can result in a reduced anchovy catch in the Benguela system if a ring passes through the fishery.
See also
- Agulhas Passage – Abyssal channel south of South Africa between the Agulhas Bank and Agulhas Plateau
- Sardine run – Annual fish migration off the shores of South Africa
- Oceans portal
References
Notes
- ↑ Bryden, Beal & Duncan 2003, Discussion, p. 491
- ↑ Stramma & Lutjeharms 1997, Abstract
- 1 2 3 4 Siedler, Church & Gould 2001, pp. 310–313
- 1 2 Baum 2014
- ↑ Jackson et al. 2012
- ↑ Leber & Beal 2012
- ↑ Leeuwen, Ruijter & Lutjeharms 2000, Abstract
- ↑ Schiele 2014
- ↑ Simon et al. 2013, Introduction, pp. 101-103
- ↑ Franzese, A; Hemming, S; Goldstein, S; Anderson, R (2006-10-15). "Reduced Agulhas Leakage during the Last Glacial Maximum inferred from an integrated provenance and flux study". Earth and Planetary Science Letters. 250 (1–2): 72–88. Bibcode:2006E&PSL.250...72F. doi:10.1016/j.epsl.2006.07.002.
- ↑ Franzese, Allison M.; Hemming, Sidney R.; Goldstein, Steven L. (2009). "Use of strontium isotopes in detrital sediments to constrain the glacial position of the Agulhas Retroflection". Paleoceanography. 24 (2): n/a. Bibcode:2009PalOc..24.2217F. doi:10.1029/2008PA001706.
- ↑ Simon et al. 2013, Conclusions, p. 110
- ↑ Forsberg & Gerber 2012
- ↑ RSMAS 2005
- 1 2 3 Beal 2009, Abstract, Introduction, pp. 2436-2437
- 1 2 Beal 2009, Discussion and summary, pp. 2448-2449
- 1 2 Mann & Lazier 2006
Sources
- Baum, S. (2014). "Agulhas Current". Encyclopedia of Earth. Retrieved 15 May 2015.
- Beal, L. M. (2009). "A time series of Agulhas Undercurrent transport". Journal of Physical Oceanography. 39 (10): 2436–2450. Bibcode:2009JPO....39.2436B. doi:10.1175/2009JPO4195.1.
- Bryden, H. L.; Beal, L. M.; Duncan, L. M. (2003). "Structure and transport of the Agulhas Current and its temporal variability" (PDF). Journal of Oceanography. 61 (3): 479–492. doi:10.1007/s10872-005-0057-8. S2CID 55798640. Retrieved 15 May 2015.
- Forsberg, B.; Gerber, M. (2012). "Rogue Waves - is forecasting possible?" (PDF). Retrieved 15 May 2015.
- Franzese, A. M.; Goldstein, S. L.; Skrivanek, A. L. (2012). "Assessing the role of the Subtropical Front in regulating Agulhas leakage at the Last Glacial Termination" (PDF). American Geophysical Union Chapman Conference. Retrieved 15 February 2015.
{{cite journal}}
: Cite journal requires|journal=
(help) - Jackson, J. M.; Rainville, L.; Roberts, M. J.; McQuald, C. D.; Porri, F.; Durgadoo, J.; Blastoch, A. (2012). "Mesoscale bio-physical interactions between the Agulhas Current and Agulhas Bank, South Africa" (PDF). American Geophysical Union Chapman Conference. Retrieved 15 February 2015.
{{cite journal}}
: Cite journal requires|journal=
(help) - Leber, G.; Beal, L. (2012). "Velocity Structure and Transport of the Meandering vs. Non-Meandering Agulhas Current" (PDF). RSMAS. Archived from the original (PDF) on 2015-04-09. Retrieved 15 April 2015.
- Leeuwen, P. J., van; Ruijter, W. P. M., de; Lutjeharms, J. R. E. (2000). "Natal pulses and the formation of Agulhas rings". Journal of Geophysical Research. 105 (C3): 6425–6436. Bibcode:2000JGR...105.6425V. doi:10.1029/1999jc900196.
{{cite journal}}
: CS1 maint: multiple names: authors list (link) - Mann, K. H.; Lazier, J.R. (2006). Dynamics of Marine Ecosystems: Biological-Physical Interactions in the Oceans (3rd ed.). Blackwell Publishing. ISBN 978-1405111188.
- "The Agulhas current". Rosenstiel School of Marine & Atmospheric Science, Miami University. 2005. Retrieved 15 May 2015.
- Schiele, Edwin (2014). "Ocean Conveyor Belt Impact". Ocean Motion. Retrieved 15 May 2015.
- Siedler, G.; Church, J.; Gould, J. (2001). Ocean Circulation & Climate. Academic Press. ISBN 9780080491974. OCLC 156788726.
- Simon, M. H.; Arthur, K. L.; Hall, I. R.; Peeters, F. J. C.; Loveday, B. R.; Barker, S.; Zieglera, M.; Zahn, R. (2013). "Millennial-scale Agulhas Current variability and its implications for salt-leakage through the Indian–Atlantic Ocean Gateway" (PDF). Earth and Planetary Science Letters. 383: 101–112. Bibcode:2013E&PSL.383..101S. doi:10.1016/j.epsl.2013.09.035. Archived from the original (PDF) on 2016-03-03. Retrieved 15 May 2015.
- Stramma, L.; Lutjeharms, J. (1997). "The flow field of the subtropical gyre in the South Indian Ocean into the Southeast Atlantic Ocean: a case study" (PDF). Journal of Geophysical Research. 99: 14053–14070. doi:10.1029/96JC03455.