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Wikipedia

Agulhas Bank

January 01, 1970

The Agulhas Bank (/əˈɡʌləs/, from Portuguese for Cape Agulhas, Cabo das Agulhas, "Cape of Needles")[1] is a broad, shallow part of the southern African continental shelf which extends up to 250 km (160 mi) south of Cape Agulhas before falling steeply to the abyssal plain.

Agulhas Bank
Map of the Agulhas Bank centred on the Outeniqua Basin
Ecology
RealmTemperate Southern Africa
Geography
Area116,000 km2 (45,000 sq mi)
CountrySouth Africa
Elevation-50 to -200 m
Coordinates34°42′33.1″S 22°28′12.4″E / 34.709194°S 22.470111°E / -34.709194; 22.470111
Oceans or seasAtlantic Ocean, Indian Ocean

It is the ocean region where the warm Indian Ocean and the cold Atlantic Ocean meet. This convergence leads to treacherous sailing conditions, accounting for numerous wrecked ships in the area over the years. However, the meeting of the oceans here also fuels the nutrient cycle for marine life, making it one of the best fishing grounds in South Africa.

Extent and characteristics edit

 
The South African marine bioregions from the 2004 classification.
 
South African marine ecoregions from the 2011 classification
Further information: Marine ecoregions of the South African exclusive economic zone

The Agulhas Bank stretches approximately 800 km (500 mi) along the African coast,[2] from off Cape Peninsula (18°E) to Port Alfred (26°E),[3] and up to 250 km (160 mi) from it. The bank slopes down relatively steeply from the coast to about 50 m (160 ft) deep and reaches 200 m (660 ft) before dropping steeply to 1,000 m (3,300 ft) on its southern edge.[2] The shelf spans an area of 116,000 km2 (45,000 sq mi) with a mean depth slightly over 100 m (330 ft).[4] It is entirely within the exclusive economic zone of South Africa.

The National Spatial Biodiversity Assessment 2004 recognised 34 biozones nested within 9 bioregions (of which four were offshore). The National Biodiversity Assessment 2011 replaced these ecozones and biozones with the terms ecoregions and ecozones. In 2011, the Agulhas Ecoregion was divided into four distinct ecozones: Agulhas inshore, Agulhas inner shelf, Agulhas outer shelf, and Agulhas shelf edge.[5] 33 different benthic habitats types were identified on the Agulhas Bank.[6]

There are dozens of warm temperate reefs along the coast of the Agulhas Ecoregion spanning from 5–30 m (16–98 ft) below sea level. Many rocky sub-tidal reefs are of aeolianite or sandstone origin, but granite, quartzite and siltstone reefs are also present. The Agulhas reefs are very heterogeneous and include several possible different sub-types. Some of the reefs are within protected areas, but only a few of those protected areas include protection from fishing.[7]

Oceanography edit

The Agulhas Bank is a natural boundary between ocean currents from the Atlantic Ocean, Indian Ocean, and Southern Ocean, resulting in one of the most turbulent waters of the world oceans.[8]

Agulhas Current edit

 
Eddies of the Agulhas Current meanders past the Agulhas Bank leaking warm and salty water into the South Atlantic before retroflecting back into the Indian Ocean
Main article: Agulhas Current

The Agulhas Current flows south along the African east-coast and along the south-eastern edge of the bank. It then retroflects back into the Indian Ocean south-west of the bank. This retroflection results in intense eddy activities such as meanders, eddies, and filaments.[3] In upper layer water, the Agulhas rings and eddies move warm and salty water into the large South Atlantic gyre, which exports it to the tropics. In the lower ocean layers water is transported in the opposite direction.[8]

Upwellings edit

Cyclonic eddies is another source of edge upwelling west of Port Elisabeth. Plumes of warm surface water migrate onto the bank along its eastern edge, providing subtropical surface water from the Indian Ocean.[4] In summer, easterly winds can intermittently drive coastal upwelling along the South African south coast.[4] The Agulhas Bank is dominated by westerly winds and most of the upwelling on the bank is related to the interaction of the Agulhas Current on the eastern edge, but easterly winds do occur, especially in summer and fall, and can generate local upwelling cells.[3]

As the current is diverged away from the coast, dynamic processes draws an onshore Ekman layer of cold water from below the warm shelf-edge flow. In spring and summer, at a depth of 100 m (330 ft), a semi-permanent ridge of cold water is present on the eastern and central shelf.[4]

In summer, there is mixture of subtropical water separated by thermoclines from cool waters, but there is a considerable seasonal variation. On the shelf, bottom waters exhibit characteristics of the central Indian Ocean in the east and central Atlantic Ocean waters in the west.[4]

Agulhas meanders and Natal pulses edit

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.[9] 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.[10]

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 move 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.[11]

Agulhas leakage and rings edit

 
Light blue plankton in a 150 km (93 mi) wide anti-cyclonic (counter-clockwise) Agulhas ring, 800 km (500 mi) off the coast of South Africa. Such eddies, among the largest in the world, are peeled off the Agulhas Current on the eastern edge of the Agulhas Bank.

Agulhas rings are large anticyclonic eddies or warm core rings of ocean water that are pinched off the Agulhas Current along the eastern edge of the Agulhas Bank from where they move into the South Atlantic. As the Agulhas Current reaches the east coast of South Africa, large solitary meanders known as Natal pulses form at irregular intervals. 165 days after the appearance of a Natal pulse, an Agulhas ring is formed off Durban. The Agulhas rings are among the largest eddies in the world and play an important role in the Agulhas Leakage, the transport of warm water from the Indian Ocean to the Atlantic Ocean, which affects the global climate.[12]

The average diameter of the Agulhas rings is 320 km (200 mi), but they can reach 500 km. They extend down to the ocean floor; circulate at 0.3–1.5 m/s (0.98–4.92 ft/s); and move into the South Atlantic at 4–8 km (2.5–5.0 mi)/day. Only half of the Agulhas eddies that leave the Cape Basin manage to cross the Walvis Ridge and those that do tend to lose half their energy before reaching the ridge within six months. The Agulhas rings transport an estimated 1-5 Sv (millions m2/s) of water from the Indian Ocean to the South Atlantic.[13]

The Agulhas rings are thought to be of global climatic importance. Their delivery of warm water from the Indian to the Atlantic Ocean can control the rate of thermohaline overturning of the entire Atlantic. Other factors contribute, to various degrees, to the inter-ocean exchanges in the region, including filaments from the Agulhas Current and intrusions of water from Antarctica. Cold, cyclonic eddies have been observed in the southwestern Atlantic.[14] Based on model simulations, researchers have found that the interaction of the Agulhas Current and the eastern edge of the bank can result in the Agulhas rings.[15]

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. Analyses of cores in the South Atlantic deposited during the Last Glacial Maximum (LGM, 20 000 years ago), show that the Agulhas leakage (shedding of Agulhas rings) was significantly reduced. It has been hypothesised that the reason for this was that the Agulhas Current was stronger which resulted in a more eastward retroflection and therefore less leakage. However, analyses of such cores south of Africa show that the trajectory of the current was the same during the LGM and that the reduced leakage must be explained by a weaker current. Consequently, it can be predicted that a stronger Agulhas Current will result in its retroflection occurring more eastward and an increased Agulhas leakage.[16]

Benguela Current edit

Main article: Benguela Current

Compared to the Agulhas Current, the Benguela Current on the west and south-west coast of Africa is more intense and steadier. Its dynamic southern upwelling system is driven by the prevailing northward winds that produce an intense off-shore Ekman transport. Most of this upwelling is concentrated to a few upwelling cells in the southern region: Namaqua (30°S), Cape Columbine (32.5°S), and Cape Peninsula (34°S). The wind is most intense from October to February, and the contrast in sea surface temperature between the open sea and the shelf is most prominent during summer.[3]

Coastal upwelling is also common on the western bank, but the more stable atmospheric condition results in larger cold water plumes that sometimes merge to form a continuous upwelling regime along the South African south-west coast. This upwelling zone is the southernmost extension of the Benguela Current Large Maritime Ecosystem. The Agulhas Current regularly flows around the southern tip of the bank and brings warm water to the western bank along the bank's western edge.[4] Regularly, the mesoscale eddies from the east interact with the Benguela upwelling system on the African west coast.[3]

Deep water eddies edit

Flowing south along the South American continental slope, the Deep Western Boundary Current (DWBC) carries North Atlantic Deep Water (NADW) into the South Atlantic. At about 8°S and at a depth of 2,200–3,500 m (7,200–11,500 ft), the DWBC breaks into anticyclonic eddies during periods of strong meridional overturning circulation. One such NADW eddy was observed in 2003 and the researchers speculated that a deeply penetrating Agulhas ring pinched it off the NADW slope current. Spinning at 20 cm/s (7.9 in/s), these deep-water eddies move around the southern tip of the Agulhas Bank and into the Indian Ocean. Most of the NADW flow (more than 7 Sv) meanders east around the Agulhas Plateau together with the surface Agulhas Return Current, but a smaller portion (3 Sv) continues north along the African east-coast as the Agulhas Undercurrent.[17] Of 89.5 Sv released from the North Atlantic, 3.6 Sv leaves the South Atlantic south of the Agulhas Bank. However, 0.9 Sv recirculate in the basin north of the Walvis Ridge for centuries, of which 50-90% end up flowing south of the Agulhas Bank within 300 years, increasing the net inter-oceanic exchange with 4.1-4.5 Sv.[18]

Alphard Banks edit

 
Juvenile Cape knifejaw and kelp forest at Alphard Banks

The Alphard Banks are a small group of long extinct volcanic seamounts on the Agulhas Bank south of Cape Agulhas. They rise from the bottom at about 80 m to about 14 m on the top. They are the southernmost recreational diving sites on the African continental shelf, and are seldom dived due to the distance offshore. The Alpard banks are in the Alphard Banks Controlled-Pelagic Linefish Zone of the Agulhas Bank Complex Marine Protected Area.[19][20][21] The habitats are depth and profile related, with the shallower, flatter, areas of the pinnacle tops dominated by spiny kelp (Ecklonia radiata), and encrusting invertebrates, and the deeper, steeper, areas below 30 m having little kelp and a more upright invertebrate community.[22]

Dalgleish Bank edit

 
Dalgleish sea fan at Dalgleish Bank

Dalgleish Bank is a relatively shallow area of rocky reef about 11 km offshore of Buffelsbaai, or 15.5 km, (about 8.3 nautical miles) bearing 218°T from Knysna Heads. Maximum depth in the immediate vicinity is about 80 m , and the shallowest part of the reef is about 29 m.

Geology edit

 
The Agulhas Bank relative to the Agulhas Ridge, Basin, and Plateau
 
As Gondwana formed 500 mya, a rift appeared which eventually developed into the Agulhas Sea. This sea filled with sediments that were to become the Cape Supergroup, which subsequently were folded into the Cape Fold Belt.
See also: Marine geology of the Cape Peninsula and False Bay

The oldest rock found along the coastline of the Agulhas Bank are eugeosynclinal[clarification needed] sediments of the up to 3 km (1.9 mi) thick Kaaimans Group deposited during continental rifting some 900 million years ago (Mya). The proto-South Atlantic closed during the Saldanian orogeny to form part of the supercontinent Gondwana (700-600 Mya). The Cape granites were emplaced and the Kaaimans Group rocks were folded and thermally metamorphosed during this period. The formation of the main basin in the Cape Province commenced 570 Mya and lasted for 200 My. The Table Mountain Group is 4 km (2.5 mi) thick and an erosional unconformity marking its base is composed of both terrestrial and marine sediments. Synclines along the coast of the southern Cape contains sediments from the Bokkveld Group.[23]

The Cape Fold Belt (CFB) rocks and the Karoo Basin were deposited 450 Mya; the Cape Supergroup 450-300 Mya during a series of transgression-regression cycles. Pan-African thrusts were reactivated 270-215 Mya to form the CFB which was then part of a continuous fold belt that developed during the Gondwanide orogeny together with Sierra de la Ventana (Argentina), Pensacola Mountains (East Antarctica), and Ellsworth Mountains (West Antarctica). In the late Carboniferous and early Jurassic, the Karoo Supergroup was deposited in the Karoo Basin north of where the CFB is located today, and covering nearly two-thirds of present-day South Africa.[24]

Gondwana breakup edit

Basaltic lavas were extruded 183 Mya to form the Karoo large igneous province; a volcanism caused by the Bouvet hotspot which is linked to the Gondwana break-up.[24] The Bouvet hotspot was located in or near present-day South Africa from the late Triassic 220 mya and until the Africa-Antarctica breakup 120 mya.[25] The Bouvet hotspot track stretches south-east from the African continent, near the South Africa-Mozambique border, and east of the AFFZ down to Bouvet Island/Bouvet Triple Junction in the South Atlantic. 100 Mya, the region where the triple junction was located passed over the hotspot, resulting in a continuous eruption that lasted to about 94 Mya and the seafloor spreading that still separates Antarctica, Africa, and South America.[26]

The Agulhas-Falkland Fracture Zone (AFFZ) stretches 1,200 kilometres (750 mi) across the South Atlantic. It is one of the largest and most spectacular fracture zones on Earth. It developed during the Early Cretaceous as West Gondwana (South America) broke up from Africa. The AFFZ is characterized by a pronounced topographic anomaly, the Agulhas Ridge (41°S,16°E-43°S,9°E) which rises more than 2 km above the surrounding sea floor. The only equivalent in size are the neighbouring Diaz Ridge and the Falkland Escarpment. The Agulhas Ridge is unique because it was not formed during the continental breakup during the Cretaceous and because it separates oceanic crusts of different age, and not oceanic crust (~14 km thick) from continental crust (25 km thick).[27][28]

North of the AFFZ is the Outeniqua Basin which is a complex system of sub-basins separated from each other by faults and basement arches; there are several smaller fault-bounded sub-basins in the north (Bredasdorp, Infanta, Pletmos, Gamtoos, and Algoa) and a distinctively deeper sub-basin in the south, the South Outeniqua Basin. The sedimentary fill of these basins developed as the northern edge of the Falkland Plateau separated from the South African southern margin during the early Cretaceous.[29]

The Diaz Marginal Ridge (DMR) separates these basins from the AFFZ. The DMR is buried under 200–250 m (660–820 ft) of sediments and sedimentary rocks and 150–200 m (490–660 ft) of this sedimentary material is undisturbed Cretaceous sediments younger than the oldest Cretaceous sedimentary rocks in the Southern Outeniqua Basin. The DMR must therefore have formed after the initial West Gondwana breakup 130-90 Mya. The DMR probably formed when new, hot oceanic crust slid past old, cold continental crust and the contrast in temperatures induced a thermal uplift.[30]

As West Gondwana drifted away from Africa roughly 125 Myr, the South Atlantic seafloor formed between them and magnetic anomalies north of the AFFZ reflects phase of the seafloor spreading. South of the AFFZ traces can be found of how the Falkland Plateau and the Agulhas Bank moved relative to each other. On a modern map, the Falkland Plateau can still be rotated and fitted into the Natal Valley in the Indian Ocean east of South Africa.[31] The Agulhas Plateau is located southeast of the shelf, separated from it by the Agulhas Passage (through which the Agulhas Current flows.)[32]

Pliocene edit

The Alphard Tertiary Igneous Province includes Palaeocene tuffs, trachybasalts, aegirine–augite trachytes and aegirine–augite phonolitic trachytes, which have been radiometrically dated at about 58 million years old. The intrusions appear to be tectonic effects.[33]

One of the largest known slumps occurred on the south-eastern edge of the Agulhas Bank in the Pliocene or more recently. Stretching from a depth of 190–700 m (620–2,300 ft), the so-called Agulhas slump is 750 km (470 mi) long, 106 km (66 mi) wide, and has a volume of 20,000 km3 (4,800 cu mi). It is a composite slump with proximal and distal allochthonous sediment masses separated by a large glide plane scar. In the western part, the sediments are dammed by basement ridges, but, in the eastern part, they have spread into the Transkei Basin. A series of slump scarps along the western edge of the shelf are 18–2 Mya, but covered by younger sediments brought there by the Benguela upwelling.[34]

Human evolution edit

See also: Pinnacle Point and Southern Dispersal

Anatomically modern humans evolved around 200 kya. The genetic diversity in the human lineage is relatively low, which indicate one or several population bottlenecks late in our lineage. It has been estimated that the population was limited to perhaps 600 individuals during the MIS 6 glacial stage (195-125 kya), one of the longest cold periods in the Quaternary of Africa. A technological and behavioural revolution that occurred globally about 50 kya led to a cultural complexity which happened in South Africa around 120-70 kya.[35]

The Cape Floral Region is a thin coastal strip and a botanic hotspot which developed at the confluence of the Benguela Upwelling and Agulhas Current. According to what professor Curtis Marean calls the "Cape Floral Region – South Coast Model" for the origins of modern humans, the early hunter-gatherers survived on shellfish, as well as geophytes, fur seal, fish, seabirds, and wash-ups found on the exposed Agulhas Bank. The bank slopes into the sea and a reconstruction of how the coastline has changed over 440 kya shows that the coast during the Pleistocene was located as far as 90 km (56 mi) from the present coast.[36]

The present South African southern coastal plain (SCP) is still separated from the rest of Africa by the Cape Fold Belt. During glacial maxima the sea-level dropped 120 metres (390 ft). This not only left large parts of the Agulhas Bank exposed, which greatly expanded the area of the SCP, but it also reconnected the SCP to the rest of Africa by the shallow water shelves, which broke the isolation of the SCP. Modern humans evolved on the SCP and the fluctuation in sea-levels would have resulted in a significant variation in selective pressure. No fossil records are known from the now submerged shelf, but a series of key fossil sites along the coastal margin of the present SCP provide earliest traces of anatomically modern humans and the use of marine resources.[37]

Commercial importance edit

South Africa began oil exploration on the Agulhas Bank in the 1980s. Of more than 200 offshore wells in South Africa, most are found on Bredasdorp Basin on the Agulhas Bank.[38]

Fishery edit

The Agulhas Bank is also significant for fisheries who use demersal trawling, demersal longline fishing, and midwater trawl fishing on the bank. Squid and small pelagic fishes are also caught. Before the introduction of the EEZ, foreign fisheries used roch-hopper gear trawling on the bank.[38]

Most of the catches are short-lived shelf-zone pelagic species and more long-lived deep-water species. The large populations of sardine and anchovy also present on the shelf follow an annual cycle. Anchovy spawn on the western Agulhas Bank in early summer while the sardines span over a broader season and area — eggs are transported by currents to the nursery area in the St Helena Bay on the South African west coast from where juvenile then migrate back to the Agulhas Bank to spawn.[39]

South Africa has a relatively large fishing industry mostly catching pelagic pilchard and anchovy and demersal hake on the south and western coasts. Though the east coast has fewer commercial fisheries, the large human population along there has resulted in overexploitation of coastal fish and invertebrate stocks by recreational and subsistence fishers. A small aquaculture industry produces mussels and oysters offshore.[40]

Several pelagic species are heavily harvested by the commercial fleet: purse-seine fishery is used to catch sardines, anchovies, and round herring; mid-water trawl fishery to catch horse mackerel and chub mackerel; pelagic longline and pole fishery to catch tunas and swordfish; while hook and line are used inshore to catch squid and teleost species, including snoek and geelbek. All these species are relatively common and are considered having an important role in the ecosystem.[41]

Biodiversity edit

 
Papery burnupena in False Bay

There are at least 12,914 marine species in South Africa, but small bodied species are poorly documented and the abyssal zone is almost completely unexplored. Almost a quarter of South Africa's coast line is protected, excluding deeper water.[40] A third of the marine species are endemic to South Africa (though poor levels of taxonomic research in adjoining countries probably affects the apparent endemism.) The degree of endemism varies considerably among taxa: Bryozoa 64%, Mollusca 56%, Echinodermata 3.6%, Porifera 8.8%, Amphipoda 33%, Isopoda 85%, or Cumacea 71%.[42] Fisheries are one of the major threats to the biodiversity of the Agulhas Bank.[41]

Crustaceans edit

Copepods comprise 90% of the zooplankton carbon on the Agulhas Bank, and are thus an important source of food for pelagic fish and juvenile squids. The population of Calanus agulhensis, a large species that dominates the copepod community in terms of biomass, has a center of distribution on the central Agulhas Bank. Since 1997 the copepod biomass on the central Agulhas Bank has declined significantly while the biomass of pelagic fish has increased significantly. While it is likely that predation has played an important role in the copepod decline, global warming (sea surface temperature and chlorophyll A abundance) is believed to have contributed to a smaller population.[43]

Fishes edit

 
A Great white shark near Dyer Island
See also: List of marine fishes of South Africa and Sardine run

The shelf edge along the bank's southern tip is subject to sporadic upwelling. This slope and its surrounding seamounts are the spawning ground for sardine, anchovy, and horse mackerel. Eddies help transport water inshore and link the spawning habitat with important nursery areas.[44] Eggs and larvae laid by the anchovy are transported via the Good Hope Jet to Africa's southwestern coast where they mature. Young anchovies then return to the Agulhas Bank to spawn.[3] Young sardine and anchovy congregate along the west coast between March and September before they migrate to their spawning grounds on the Agulhas Bank. Sardines of intermediate age are present on the western Agulhas Bank between January and April before migrating to KwaZulu-Natal for winter. The spawning on the Agulhas Bank takes place 30–130 km (19–81 mi) offshore from September to February.[45]

The bank is the spawning area of deep reef fish species, including the threatened endemic red steenbras (Petrus rupestris). Other species have been overexploited, including daggerhead seabream or dageraad (Chrysoblephus cristiceps), black musselcracker (Cymatoceps nasutus), and silver kob (Argyrosomus inodorus).[46]

57 species of sharks have been reported off the western coast of South Africa, of which 21 are squaloid sharks.[47]

Birds edit

 
Brown skua near Dyer Island
 
African penguins at Table Mountain National Park

The main food source for African penguins (Spheniscus demersus) is anchovy and sardine which they forage between Cape Columbine and the central Agulhas Bank. The birds have colonies on Dassen Island, on the South African west coast, and Bird Island, on the south coast.[48] African penguins breed opportunistically, following the anchovy and sardine: from February to September on the Western Cape but from January to July on St Croix Island off Eastern Cape. After breeding, the birds forage further offshore: 10–15 km (6.2–9.3 mi) off the western coast and up to 40 km (25 mi) from their colonies off Eastern Cape.[45]

In 2005, when Korean and Philippine vessels started longline fishing along the edges of the Agulhas Bank, seabird bycatch became a huge problem. Large numbers of albatrosses and petrels were killed — in average 0.6 birds per 1000 hooks, but up to 18 birds per 1000 hooks were reported.[49] Since 2007, however, more restrictive permit conditions for foreign-flagged fleets and the use of birds scaring lines have decreased the number of killed birds by 85%.[50]

Fur seals edit

 
A Cape fur seal diving off Cape Town

Cape fur seals are present along the South African coast. Fur seals are protected in South Africa since 1893 although a small number are occasionally culled to protect sea birds. Many seals are caught in fishery nets and boat propellers, but the seals are also regularly accused of stealing fish from the fisheries.[51] Sharks are known to prey on them, but in 2012 a cape fur seal was observed preying on and consuming a mid-sized blue shark.[52]

Cetaceans edit

 
A dusky dolphin on the Cape Peninsula west coast

51 species, or more than 50%, of the recognized species of cetaceans are present in the southern African subregion (between the equator and the Antarctic ice edge), of which 36 have been sighted in South African and Namibian waters.[53]

A vulnerable population of fish-eating killer whales are present offshore on the Agulhas Bank. Observations peak in January while few are sighted in April and May. The killer whales move in pods of 1-4 individuals and are mostly sited over the shelf edge off the south-east coast.[54] An analysis of killer whale mtDNA has shown that there was a peak inter-oceanic migration events during the Eemian interglacial period, 131-114 kya. This peak coincides with a period of maximal Agulhas leakage which promoted a rapid and episodic interchange of killer whale lineages. During this period killer whales and other marine top predators, such as the great white shark, colonised the North Atlantic and Mediterranean by following their prey — bluefin tuna and swordfish.[55]

A vagrant Commerson's dolphin — a species with two isolated populations, one along the southern coast of Argentina and the other around the Kerguelen Islands — was sighted on the Agulhas Bank in 2004. It is not known from which population the sighted individual stems. The Kerguelen Islands are located 4,200 km (2,600 mi) and South America 6,300 km (3,900 mi) from the Agulhas Bank, but the west-ward direction of the Antarctic Circumpolar Current would force the dolphin to swim against the current from the Kerguelen Islands.[56]

Fossil beaked whales have been recovered by trawling from the seafloor off South Africa.[57] Stranded pygmy sperm whales have been recorded on both the east and west coasts of South Africa.[58]

Conservation edit

There are several marine protected areas on the Agulhas Bank. These include:

Coastal MPAs:

Offshore MPAs:

References edit

Notes edit

  1. ^ Gyory et al. 2004
  2. ^ a b . Bayworld Centre For Research & Education. Archived from the original on 1 July 2017. Retrieved 12 November 2016.
  3. ^ a b c d e f Blanke et al. 2009, Introduction, pp. 1-2
  4. ^ a b c d e f Whittle 2012, Introduction
  5. ^ Sink et al. 2012, Fig. 4, pp. 50-51
  6. ^ Sink et al. 2012, Fig. 5, p. 53
  7. ^ Sink et al. 2012, pp. 66-67
  8. ^ a b Ruijter et al. 2003, p. 45
  9. ^ Jackson et al. 2012
  10. ^ Leber & Beal 2012
  11. ^ Leeuwen, Ruijter & Lutjeharms 2000, Abstract
  12. ^ Leeuwen, Ruijter & Lutjeharms 2000, Introduction
  13. ^ Ruijter et al. 2003, p. 46
  14. ^ Penven et al. 2001, Introduction, p. 1055
  15. ^ Penven et al. 2001, Conclusion, p. 1057
  16. ^ Franzese, Goldstein & Skrivanek 2012
  17. ^ Casal, Beal & Lumpkin 2006, Abstract, Introduction, pp. 1718-1719; Fig. 7, p. 1727
  18. ^ Sebille, Johns & Beal 2012, 3.1. Connectivity Between the DWBC and the Agulhas Region
  19. ^ "Agulhas Bank complex MPA". www.marineprotectedareas.org. from the original on 8 October 2023. Retrieved 15 January 2024.
  20. ^ "Exploring the last frontiers: Reef pinnacles on the Agulhas Bank". archive.saeon.ac.za. from the original on 15 January 2024. Retrieved 15 January 2024.
  21. ^ Department of Environmental Affairs (23 May 2019). "National Environmental Management: Protected Areas Act, 2003 (Act No. 57 of 2003). Regulations for the Management of the Agulhas Bank Complex Marine Protected Area" (PDF). Government Gazette. Pretoria: Government Printer.
  22. ^ Götz, Albrecht; Kerwath, Sven; Samaai, Toufiek (2010). "Exploring the depths". Quest. 6 (4): 28–30.
  23. ^ Durrheim 1987, Geological evolution of the Agulhas Bank, pp. 395-396
  24. ^ a b Parsiegla et al. 2009, Geological and Tectonic Background, pp. 2-4
  25. ^ Golonka & Bocharova 2000, Figs. 3-8
  26. ^ Gohl & Uenzelmann-Neben 2012, Figs. 1, 5
  27. ^ Uenzelmann-Neben & Gohl 2003, Abstract
  28. ^ Bird 2001, p. 152
  29. ^ Parsiegla et al. 2009, Introduction [3], p. 2; Geological and Tectonic Background [6], p. 3; Fig. 3, p.5
  30. ^ Parsiegla et al. 2009, The Diaz Marginal Ridge, pp. 12-14
  31. ^ Goodlad, Martin & Hartnay 1982
  32. ^ Parsiegla et al. 2009, Fig. 1
  33. ^ Dingle, R. V.; Gentle, R. I. (March 1972). "Early Tertiary volcanic rocks on the Agulhas Bank, South African Continental Shelf". Geological Magazine. 109 (2): 127–136. Bibcode:1972GeoM..109..127D. doi:10.1017/S0016756800039510. S2CID 129088205. from the original on 16 April 2021. Retrieved 16 April 2021 – via Cambridge University Press, published online 01 May 2009.
  34. ^ Uenzelmann-Neben & Huhn 2009, pp. 66, 76
  35. ^ Marean 2011, pp. 421–423
  36. ^ Marean 2011, pp. 423–425
  37. ^ Compton 2011, p. 508
  38. ^ a b "Assessment of Offshore Benthic Biodiversity on the Agulhas Bank and the Potential Role of Petroleum". WWF. November 2008. Archived from the original on 2015-01-25. Retrieved 12 November 2016.
  39. ^ Jury 2011, pp. 1–2
  40. ^ a b Griffith et al. 2010, p. 1
  41. ^ a b Grantham et al. 2011, p. 2
  42. ^ Griffith et al. 2010, pp. 6, 8
  43. ^ Huggett et al. 2012
  44. ^ Sink et al. 2012b
  45. ^ a b Crawford et al. 2006, Introduction
  46. ^ Sink et al. 2012a
  47. ^ Ebert, Compagno & Cowley 1992, Introduction
  48. ^ Harding 2013, Abstract
  49. ^ Ryan 2006
  50. ^ "Albatross Task Force". BirdLife South Africa. from the original on 28 October 2016. Retrieved 12 November 2016.
  51. ^ "South African Fur Seal". Seal Conservation Society. 2011. from the original on 7 November 2016. Retrieved 12 November 2016.
  52. ^ Nuwer, Rachel (March 2015). "Fur Seals Caught Preying on Sharks Off South Africa". Smithsonian Magazine. from the original on 31 January 2017. Retrieved 12 November 2016.
  53. ^ Elwen et al. 2011, p. 470
  54. ^ Williams et al. 2009, Abstract
  55. ^ Foote et al. 2011, p. 5
  56. ^ Bruyn, Hofmeyr & Villiers 2006
  57. ^ Bianucci, Lambert & Post 2007, Abstract
  58. ^ Elwen et al. 2013, Introduction
  59. ^ a b c d e f "Meet South Africa's new Marine Protected Areas". www.marineprotectedareas.org.za. from the original on 19 January 2019. Retrieved 18 January 2019.
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January 01, 1970
agulhas, bank, from, portuguese, cape, agulhas, cabo, agulhas, cape, needles, broad, shallow, part, southern, african, continental, shelf, which, extends, south, cape, agulhas, before, falling, steeply, abyssal, plain, centred, outeniqua, basinecologyrealmtemp. The Agulhas Bank e ˈ ɡ ʌ l e s from Portuguese for Cape Agulhas Cabo das Agulhas Cape of Needles 1 is a broad shallow part of the southern African continental shelf which extends up to 250 km 160 mi south of Cape Agulhas before falling steeply to the abyssal plain Agulhas BankMap of the Agulhas Bank centred on the Outeniqua BasinEcologyRealmTemperate Southern AfricaGeographyArea116 000 km2 45 000 sq mi CountrySouth AfricaElevation 50 to 200 mCoordinates34 42 33 1 S 22 28 12 4 E 34 709194 S 22 470111 E 34 709194 22 470111Oceans or seasAtlantic Ocean Indian Ocean It is the ocean region where the warm Indian Ocean and the cold Atlantic Ocean meet This convergence leads to treacherous sailing conditions accounting for numerous wrecked ships in the area over the years However the meeting of the oceans here also fuels the nutrient cycle for marine life making it one of the best fishing grounds in South Africa Contents 1 Extent and characteristics 2 Oceanography 2 1 Agulhas Current 2 1 1 Upwellings 2 1 2 Agulhas meanders and Natal pulses 2 1 3 Agulhas leakage and rings 2 2 Benguela Current 2 3 Deep water eddies 2 4 Alphard Banks 2 5 Dalgleish Bank 3 Geology 3 1 Gondwana breakup 3 2 Pliocene 4 Human evolution 5 Commercial importance 5 1 Fishery 6 Biodiversity 6 1 Crustaceans 6 2 Fishes 6 3 Birds 6 4 Fur seals 6 5 Cetaceans 7 Conservation 8 References 8 1 Notes 8 2 SourcesExtent and characteristics edit nbsp The South African marine bioregions from the 2004 classification nbsp South African marine ecoregions from the 2011 classification Further information Marine ecoregions of the South African exclusive economic zone The Agulhas Bank stretches approximately 800 km 500 mi along the African coast 2 from off Cape Peninsula 18 E to Port Alfred 26 E 3 and up to 250 km 160 mi from it The bank slopes down relatively steeply from the coast to about 50 m 160 ft deep and reaches 200 m 660 ft before dropping steeply to 1 000 m 3 300 ft on its southern edge 2 The shelf spans an area of 116 000 km2 45 000 sq mi with a mean depth slightly over 100 m 330 ft 4 It is entirely within the exclusive economic zone of South Africa The National Spatial Biodiversity Assessment 2004 recognised 34 biozones nested within 9 bioregions of which four were offshore The National Biodiversity Assessment 2011 replaced these ecozones and biozones with the terms ecoregions and ecozones In 2011 the Agulhas Ecoregion was divided into four distinct ecozones Agulhas inshore Agulhas inner shelf Agulhas outer shelf and Agulhas shelf edge 5 33 different benthic habitats types were identified on the Agulhas Bank 6 There are dozens of warm temperate reefs along the coast of the Agulhas Ecoregion spanning from 5 30 m 16 98 ft below sea level Many rocky sub tidal reefs are of aeolianite or sandstone origin but granite quartzite and siltstone reefs are also present The Agulhas reefs are very heterogeneous and include several possible different sub types Some of the reefs are within protected areas but only a few of those protected areas include protection from fishing 7 Oceanography editThe Agulhas Bank is a natural boundary between ocean currents from the Atlantic Ocean Indian Ocean and Southern Ocean resulting in one of the most turbulent waters of the world oceans 8 Agulhas Current edit nbsp Eddies of the Agulhas Current meanders past the Agulhas Bank leaking warm and salty water into the South Atlantic before retroflecting back into the Indian Ocean Main article Agulhas Current The Agulhas Current flows south along the African east coast and along the south eastern edge of the bank It then retroflects back into the Indian Ocean south west of the bank This retroflection results in intense eddy activities such as meanders eddies and filaments 3 In upper layer water the Agulhas rings and eddies move warm and salty water into the large South Atlantic gyre which exports it to the tropics In the lower ocean layers water is transported in the opposite direction 8 Upwellings edit Cyclonic eddies is another source of edge upwelling west of Port Elisabeth Plumes of warm surface water migrate onto the bank along its eastern edge providing subtropical surface water from the Indian Ocean 4 In summer easterly winds can intermittently drive coastal upwelling along the South African south coast 4 The Agulhas Bank is dominated by westerly winds and most of the upwelling on the bank is related to the interaction of the Agulhas Current on the eastern edge but easterly winds do occur especially in summer and fall and can generate local upwelling cells 3 As the current is diverged away from the coast dynamic processes draws an onshore Ekman layer of cold water from below the warm shelf edge flow In spring and summer at a depth of 100 m 330 ft a semi permanent ridge of cold water is present on the eastern and central shelf 4 In summer there is mixture of subtropical water separated by thermoclines from cool waters but there is a considerable seasonal variation On the shelf bottom waters exhibit characteristics of the central Indian Ocean in the east and central Atlantic Ocean waters in the west 4 Agulhas meanders and Natal pulses edit 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 9 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 10 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 move 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 11 Agulhas leakage and rings edit nbsp Light blue plankton in a 150 km 93 mi wide anti cyclonic counter clockwise Agulhas ring 800 km 500 mi off the coast of South Africa Such eddies among the largest in the world are peeled off the Agulhas Current on the eastern edge of the Agulhas Bank Agulhas rings are large anticyclonic eddies or warm core rings of ocean water that are pinched off the Agulhas Current along the eastern edge of the Agulhas Bank from where they move into the South Atlantic As the Agulhas Current reaches the east coast of South Africa large solitary meanders known as Natal pulses form at irregular intervals 165 days after the appearance of a Natal pulse an Agulhas ring is formed off Durban The Agulhas rings are among the largest eddies in the world and play an important role in the Agulhas Leakage the transport of warm water from the Indian Ocean to the Atlantic Ocean which affects the global climate 12 The average diameter of the Agulhas rings is 320 km 200 mi but they can reach 500 km They extend down to the ocean floor circulate at 0 3 1 5 m s 0 98 4 92 ft s and move into the South Atlantic at 4 8 km 2 5 5 0 mi day Only half of the Agulhas eddies that leave the Cape Basin manage to cross the Walvis Ridge and those that do tend to lose half their energy before reaching the ridge within six months The Agulhas rings transport an estimated 1 5 Sv millions m2 s of water from the Indian Ocean to the South Atlantic 13 The Agulhas rings are thought to be of global climatic importance Their delivery of warm water from the Indian to the Atlantic Ocean can control the rate of thermohaline overturning of the entire Atlantic Other factors contribute to various degrees to the inter ocean exchanges in the region including filaments from the Agulhas Current and intrusions of water from Antarctica Cold cyclonic eddies have been observed in the southwestern Atlantic 14 Based on model simulations researchers have found that the interaction of the Agulhas Current and the eastern edge of the bank can result in the Agulhas rings 15 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 Analyses of cores in the South Atlantic deposited during the Last Glacial Maximum LGM 20 000 years ago show that the Agulhas leakage shedding of Agulhas rings was significantly reduced It has been hypothesised that the reason for this was that the Agulhas Current was stronger which resulted in a more eastward retroflection and therefore less leakage However analyses of such cores south of Africa show that the trajectory of the current was the same during the LGM and that the reduced leakage must be explained by a weaker current Consequently it can be predicted that a stronger Agulhas Current will result in its retroflection occurring more eastward and an increased Agulhas leakage 16 Benguela Current edit Main article Benguela Current Compared to the Agulhas Current the Benguela Current on the west and south west coast of Africa is more intense and steadier Its dynamic southern upwelling system is driven by the prevailing northward winds that produce an intense off shore Ekman transport Most of this upwelling is concentrated to a few upwelling cells in the southern region Namaqua 30 S Cape Columbine 32 5 S and Cape Peninsula 34 S The wind is most intense from October to February and the contrast in sea surface temperature between the open sea and the shelf is most prominent during summer 3 Coastal upwelling is also common on the western bank but the more stable atmospheric condition results in larger cold water plumes that sometimes merge to form a continuous upwelling regime along the South African south west coast This upwelling zone is the southernmost extension of the Benguela Current Large Maritime Ecosystem The Agulhas Current regularly flows around the southern tip of the bank and brings warm water to the western bank along the bank s western edge 4 Regularly the mesoscale eddies from the east interact with the Benguela upwelling system on the African west coast 3 Deep water eddies edit Flowing south along the South American continental slope the Deep Western Boundary Current DWBC carries North Atlantic Deep Water NADW into the South Atlantic At about 8 S and at a depth of 2 200 3 500 m 7 200 11 500 ft the DWBC breaks into anticyclonic eddies during periods of strong meridional overturning circulation One such NADW eddy was observed in 2003 and the researchers speculated that a deeply penetrating Agulhas ring pinched it off the NADW slope current Spinning at 20 cm s 7 9 in s these deep water eddies move around the southern tip of the Agulhas Bank and into the Indian Ocean Most of the NADW flow more than 7 Sv meanders east around the Agulhas Plateau together with the surface Agulhas Return Current but a smaller portion 3 Sv continues north along the African east coast as the Agulhas Undercurrent 17 Of 89 5 Sv released from the North Atlantic 3 6 Sv leaves the South Atlantic south of the Agulhas Bank However 0 9 Sv recirculate in the basin north of the Walvis Ridge for centuries of which 50 90 end up flowing south of the Agulhas Bank within 300 years increasing the net inter oceanic exchange with 4 1 4 5 Sv 18 Alphard Banks edit nbsp Juvenile Cape knifejaw and kelp forest at Alphard Banks The Alphard Banks are a small group of long extinct volcanic seamounts on the Agulhas Bank south of Cape Agulhas They rise from the bottom at about 80 m to about 14 m on the top They are the southernmost recreational diving sites on the African continental shelf and are seldom dived due to the distance offshore The Alpard banks are in the Alphard Banks Controlled Pelagic Linefish Zone of the Agulhas Bank Complex Marine Protected Area 19 20 21 The habitats are depth and profile related with the shallower flatter areas of the pinnacle tops dominated by spiny kelp Ecklonia radiata and encrusting invertebrates and the deeper steeper areas below 30 m having little kelp and a more upright invertebrate community 22 This section needs expansion You can help by adding to it June 2020 Dalgleish Bank edit nbsp Dalgleish sea fan at Dalgleish Bank Dalgleish Bank is a relatively shallow area of rocky reef about 11 km offshore of Buffelsbaai or 15 5 km about 8 3 nautical miles bearing 218 T from Knysna Heads Maximum depth in the immediate vicinity is about 80 m and the shallowest part of the reef is about 29 m This section needs expansion You can help by adding to it January 2024 Geology edit nbsp The Agulhas Bank relative to the Agulhas Ridge Basin and Plateau nbsp As Gondwana formed 500 mya a rift appeared which eventually developed into the Agulhas Sea This sea filled with sediments that were to become the Cape Supergroup which subsequently were folded into the Cape Fold Belt See also Marine geology of the Cape Peninsula and False Bay The oldest rock found along the coastline of the Agulhas Bank are eugeosynclinal clarification needed sediments of the up to 3 km 1 9 mi thick Kaaimans Group deposited during continental rifting some 900 million years ago Mya The proto South Atlantic closed during the Saldanian orogeny to form part of the supercontinent Gondwana 700 600 Mya The Cape granites were emplaced and the Kaaimans Group rocks were folded and thermally metamorphosed during this period The formation of the main basin in the Cape Province commenced 570 Mya and lasted for 200 My The Table Mountain Group is 4 km 2 5 mi thick and an erosional unconformity marking its base is composed of both terrestrial and marine sediments Synclines along the coast of the southern Cape contains sediments from the Bokkveld Group 23 The Cape Fold Belt CFB rocks and the Karoo Basin were deposited 450 Mya the Cape Supergroup 450 300 Mya during a series of transgression regression cycles Pan African thrusts were reactivated 270 215 Mya to form the CFB which was then part of a continuous fold belt that developed during the Gondwanide orogeny together with Sierra de la Ventana Argentina Pensacola Mountains East Antarctica and Ellsworth Mountains West Antarctica In the late Carboniferous and early Jurassic the Karoo Supergroup was deposited in the Karoo Basin north of where the CFB is located today and covering nearly two thirds of present day South Africa 24 Gondwana breakup edit Basaltic lavas were extruded 183 Mya to form the Karoo large igneous province a volcanism caused by the Bouvet hotspot which is linked to the Gondwana break up 24 The Bouvet hotspot was located in or near present day South Africa from the late Triassic 220 mya and until the Africa Antarctica breakup 120 mya 25 The Bouvet hotspot track stretches south east from the African continent near the South Africa Mozambique border and east of the AFFZ down to Bouvet Island Bouvet Triple Junction in the South Atlantic 100 Mya the region where the triple junction was located passed over the hotspot resulting in a continuous eruption that lasted to about 94 Mya and the seafloor spreading that still separates Antarctica Africa and South America 26 The Agulhas Falkland Fracture Zone AFFZ stretches 1 200 kilometres 750 mi across the South Atlantic It is one of the largest and most spectacular fracture zones on Earth It developed during the Early Cretaceous as West Gondwana South America broke up from Africa The AFFZ is characterized by a pronounced topographic anomaly the Agulhas Ridge 41 S 16 E 43 S 9 E which rises more than 2 km above the surrounding sea floor The only equivalent in size are the neighbouring Diaz Ridge and the Falkland Escarpment The Agulhas Ridge is unique because it was not formed during the continental breakup during the Cretaceous and because it separates oceanic crusts of different age and not oceanic crust 14 km thick from continental crust 25 km thick 27 28 North of the AFFZ is the Outeniqua Basin which is a complex system of sub basins separated from each other by faults and basement arches there are several smaller fault bounded sub basins in the north Bredasdorp Infanta Pletmos Gamtoos and Algoa and a distinctively deeper sub basin in the south the South Outeniqua Basin The sedimentary fill of these basins developed as the northern edge of the Falkland Plateau separated from the South African southern margin during the early Cretaceous 29 The Diaz Marginal Ridge DMR separates these basins from the AFFZ The DMR is buried under 200 250 m 660 820 ft of sediments and sedimentary rocks and 150 200 m 490 660 ft of this sedimentary material is undisturbed Cretaceous sediments younger than the oldest Cretaceous sedimentary rocks in the Southern Outeniqua Basin The DMR must therefore have formed after the initial West Gondwana breakup 130 90 Mya The DMR probably formed when new hot oceanic crust slid past old cold continental crust and the contrast in temperatures induced a thermal uplift 30 As West Gondwana drifted away from Africa roughly 125 Myr the South Atlantic seafloor formed between them and magnetic anomalies north of the AFFZ reflects phase of the seafloor spreading South of the AFFZ traces can be found of how the Falkland Plateau and the Agulhas Bank moved relative to each other On a modern map the Falkland Plateau can still be rotated and fitted into the Natal Valley in the Indian Ocean east of South Africa 31 The Agulhas Plateau is located southeast of the shelf separated from it by the Agulhas Passage through which the Agulhas Current flows 32 Pliocene edit The Alphard Tertiary Igneous Province includes Palaeocene tuffs trachybasalts aegirine augite trachytes and aegirine augite phonolitic trachytes which have been radiometrically dated at about 58 million years old The intrusions appear to be tectonic effects 33 One of the largest known slumps occurred on the south eastern edge of the Agulhas Bank in the Pliocene or more recently Stretching from a depth of 190 700 m 620 2 300 ft the so called Agulhas slump is 750 km 470 mi long 106 km 66 mi wide and has a volume of 20 000 km3 4 800 cu mi It is a composite slump with proximal and distal allochthonous sediment masses separated by a large glide plane scar In the western part the sediments are dammed by basement ridges but in the eastern part they have spread into the Transkei Basin A series of slump scarps along the western edge of the shelf are 18 2 Mya but covered by younger sediments brought there by the Benguela upwelling 34 This section needs expansion You can help by adding to it June 2020 Human evolution editSee also Pinnacle Point and Southern Dispersal Anatomically modern humans evolved around 200 kya The genetic diversity in the human lineage is relatively low which indicate one or several population bottlenecks late in our lineage It has been estimated that the population was limited to perhaps 600 individuals during the MIS 6 glacial stage 195 125 kya one of the longest cold periods in the Quaternary of Africa A technological and behavioural revolution that occurred globally about 50 kya led to a cultural complexity which happened in South Africa around 120 70 kya 35 The Cape Floral Region is a thin coastal strip and a botanic hotspot which developed at the confluence of the Benguela Upwelling and Agulhas Current According to what professor Curtis Marean calls the Cape Floral Region South Coast Model for the origins of modern humans the early hunter gatherers survived on shellfish as well as geophytes fur seal fish seabirds and wash ups found on the exposed Agulhas Bank The bank slopes into the sea and a reconstruction of how the coastline has changed over 440 kya shows that the coast during the Pleistocene was located as far as 90 km 56 mi from the present coast 36 The present South African southern coastal plain SCP is still separated from the rest of Africa by the Cape Fold Belt During glacial maxima the sea level dropped 120 metres 390 ft This not only left large parts of the Agulhas Bank exposed which greatly expanded the area of the SCP but it also reconnected the SCP to the rest of Africa by the shallow water shelves which broke the isolation of the SCP Modern humans evolved on the SCP and the fluctuation in sea levels would have resulted in a significant variation in selective pressure No fossil records are known from the now submerged shelf but a series of key fossil sites along the coastal margin of the present SCP provide earliest traces of anatomically modern humans and the use of marine resources 37 Commercial importance editSouth Africa began oil exploration on the Agulhas Bank in the 1980s Of more than 200 offshore wells in South Africa most are found on Bredasdorp Basin on the Agulhas Bank 38 Fishery edit The Agulhas Bank is also significant for fisheries who use demersal trawling demersal longline fishing and midwater trawl fishing on the bank Squid and small pelagic fishes are also caught Before the introduction of the EEZ foreign fisheries used roch hopper gear trawling on the bank 38 Most of the catches are short lived shelf zone pelagic species and more long lived deep water species The large populations of sardine and anchovy also present on the shelf follow an annual cycle Anchovy spawn on the western Agulhas Bank in early summer while the sardines span over a broader season and area eggs are transported by currents to the nursery area in the St Helena Bay on the South African west coast from where juvenile then migrate back to the Agulhas Bank to spawn 39 South Africa has a relatively large fishing industry mostly catching pelagic pilchard and anchovy and demersal hake on the south and western coasts Though the east coast has fewer commercial fisheries the large human population along there has resulted in overexploitation of coastal fish and invertebrate stocks by recreational and subsistence fishers A small aquaculture industry produces mussels and oysters offshore 40 Several pelagic species are heavily harvested by the commercial fleet purse seine fishery is used to catch sardines anchovies and round herring mid water trawl fishery to catch horse mackerel and chub mackerel pelagic longline and pole fishery to catch tunas and swordfish while hook and line are used inshore to catch squid and teleost species including snoek and geelbek All these species are relatively common and are considered having an important role in the ecosystem 41 Biodiversity edit nbsp Papery burnupena in False Bay There are at least 12 914 marine species in South Africa but small bodied species are poorly documented and the abyssal zone is almost completely unexplored Almost a quarter of South Africa s coast line is protected excluding deeper water 40 A third of the marine species are endemic to South Africa though poor levels of taxonomic research in adjoining countries probably affects the apparent endemism The degree of endemism varies considerably among taxa Bryozoa 64 Mollusca 56 Echinodermata 3 6 Porifera 8 8 Amphipoda 33 Isopoda 85 or Cumacea 71 42 Fisheries are one of the major threats to the biodiversity of the Agulhas Bank 41 Crustaceans edit Copepods comprise 90 of the zooplankton carbon on the Agulhas Bank and are thus an important source of food for pelagic fish and juvenile squids The population of Calanus agulhensis a large species that dominates the copepod community in terms of biomass has a center of distribution on the central Agulhas Bank Since 1997 the copepod biomass on the central Agulhas Bank has declined significantly while the biomass of pelagic fish has increased significantly While it is likely that predation has played an important role in the copepod decline global warming sea surface temperature and chlorophyll A abundance is believed to have contributed to a smaller population 43 Fishes edit nbsp A Great white shark near Dyer Island See also List of marine fishes of South Africa and Sardine run The shelf edge along the bank s southern tip is subject to sporadic upwelling This slope and its surrounding seamounts are the spawning ground for sardine anchovy and horse mackerel Eddies help transport water inshore and link the spawning habitat with important nursery areas 44 Eggs and larvae laid by the anchovy are transported via the Good Hope Jet to Africa s southwestern coast where they mature Young anchovies then return to the Agulhas Bank to spawn 3 Young sardine and anchovy congregate along the west coast between March and September before they migrate to their spawning grounds on the Agulhas Bank Sardines of intermediate age are present on the western Agulhas Bank between January and April before migrating to KwaZulu Natal for winter The spawning on the Agulhas Bank takes place 30 130 km 19 81 mi offshore from September to February 45 The bank is the spawning area of deep reef fish species including the threatened endemic red steenbras Petrus rupestris Other species have been overexploited including daggerhead seabream or dageraad Chrysoblephus cristiceps black musselcracker Cymatoceps nasutus and silver kob Argyrosomus inodorus 46 57 species of sharks have been reported off the western coast of South Africa of which 21 are squaloid sharks 47 Birds edit nbsp Brown skua near Dyer Island nbsp African penguins at Table Mountain National Park The main food source for African penguins Spheniscus demersus is anchovy and sardine which they forage between Cape Columbine and the central Agulhas Bank The birds have colonies on Dassen Island on the South African west coast and Bird Island on the south coast 48 African penguins breed opportunistically following the anchovy and sardine from February to September on the Western Cape but from January to July on St Croix Island off Eastern Cape After breeding the birds forage further offshore 10 15 km 6 2 9 3 mi off the western coast and up to 40 km 25 mi from their colonies off Eastern Cape 45 In 2005 when Korean and Philippine vessels started longline fishing along the edges of the Agulhas Bank seabird bycatch became a huge problem Large numbers of albatrosses and petrels were killed in average 0 6 birds per 1000 hooks but up to 18 birds per 1000 hooks were reported 49 Since 2007 however more restrictive permit conditions for foreign flagged fleets and the use of birds scaring lines have decreased the number of killed birds by 85 50 Fur seals edit nbsp A Cape fur seal diving off Cape Town Cape fur seals are present along the South African coast Fur seals are protected in South Africa since 1893 although a small number are occasionally culled to protect sea birds Many seals are caught in fishery nets and boat propellers but the seals are also regularly accused of stealing fish from the fisheries 51 Sharks are known to prey on them but in 2012 a cape fur seal was observed preying on and consuming a mid sized blue shark 52 Cetaceans edit nbsp A dusky dolphin on the Cape Peninsula west coast 51 species or more than 50 of the recognized species of cetaceans are present in the southern African subregion between the equator and the Antarctic ice edge of which 36 have been sighted in South African and Namibian waters 53 A vulnerable population of fish eating killer whales are present offshore on the Agulhas Bank Observations peak in January while few are sighted in April and May The killer whales move in pods of 1 4 individuals and are mostly sited over the shelf edge off the south east coast 54 An analysis of killer whale mtDNA has shown that there was a peak inter oceanic migration events during the Eemian interglacial period 131 114 kya This peak coincides with a period of maximal Agulhas leakage which promoted a rapid and episodic interchange of killer whale lineages During this period killer whales and other marine top predators such as the great white shark colonised the North Atlantic and Mediterranean by following their prey bluefin tuna and swordfish 55 A vagrant Commerson s dolphin a species with two isolated populations one along the southern coast of Argentina and the other around the Kerguelen Islands was sighted on the Agulhas Bank in 2004 It is not known from which population the sighted individual stems The Kerguelen Islands are located 4 200 km 2 600 mi and South America 6 300 km 3 900 mi from the Agulhas Bank but the west ward direction of the Antarctic Circumpolar Current would force the dolphin to swim against the current from the Kerguelen Islands 56 Fossil beaked whales have been recovered by trawling from the seafloor off South Africa 57 Stranded pygmy sperm whales have been recorded on both the east and west coasts of South Africa 58 Conservation editThere are several marine protected areas on the Agulhas Bank These include Coastal MPAs Addo Elephant National Park Marine Protected Area Marine conservation area in the Eastern Cape in South Africa Nelson Mandela Bay Port Elizabeth Eastern Cape 2019 59 Betty s Bay Marine Protected Area Marine conservation area in the Western Cape in South Africa Western Cape 2000 60 Bird Island Marine Protected Area Marine conservation area in the Eastern Cape in South Africa Eastern Cape 2004 60 Browns Bank Corals Marine Protected Area Marine conservation area on the continental slope of South Africa South of Cape Town Western Cape 2019 59 De Hoop Marine Protected Area Marine conservation area on the coast of South Africa Western Cape 2000 60 Goukamma Marine Protected Area Marine conservation area the Western Cape in South Africa Western Cape 2000 60 Helderberg Marine Protected Area Marine conservation area in the Western Cape in South Africa Western Cape 2000 60 Hluleka Marine Protected Area Marine conservation area in the Eastern Cape in South Africa Eastern Cape 2000 60 Robberg Marine Protected Area Conservation area at the Robberg peninsula in South AfricaPages displaying short descriptions of redirect targets Western Cape 2000 60 Sardinia Bay Marine Protected Area Marine conservation area in the Eastern Cape in South Africa Eastern Cape 2000 60 Table Mountain National Park Marine Protected Area Marine conservation area around the Cape Peninsula in South Africa Western Cape 2004 partly in the area which may be considered part of the Agulhas Bank 60 Tsitsikamma Marine Protected Area Marine conservation area on the south coast of South Africa Eastern Cape 2000 60 Walker Bay Whale Sanctuary Marine conservation area in the Western Cape province in South Africa Western Cape 2001 seasonal 60 Offshore MPAs Agulhas Bank Complex Marine Protected Area Offshore marine conservation area south of Cape Agulhas in South Africa South of Cape Agulhas Western Cape 2019 59 Agulhas Front Marine Protected Area Offshore marine conservation area off the Eastern Cape in South Africa s EEZ South of Port Elizabeth Eastern Cape 2019 59 Agulhas Muds Marine Protected Area Marine conservation area offshore of the Western Cape in South Africa South of Cape Agulhas Western Cape 2019 59 Port Elizabeth Corals Marine Protected Area Marine conservation area off the Eastern Cape in South Africa Offshore of Port Elizabeth Eastern Cape 2019 59 References editNotes edit Gyory et al 2004 a b Sea Atlas Agulhas Bank Bayworld Centre For Research amp Education Archived from the original on 1 July 2017 Retrieved 12 November 2016 a b c d e f Blanke et al 2009 Introduction pp 1 2 a b c d e f Whittle 2012 Introduction Sink et al 2012 Fig 4 pp 50 51 Sink et al 2012 Fig 5 p 53 Sink et al 2012 pp 66 67 a b Ruijter et al 2003 p 45 Jackson et al 2012 Leber amp Beal 2012 Leeuwen Ruijter amp Lutjeharms 2000 Abstract Leeuwen Ruijter amp Lutjeharms 2000 Introduction Ruijter et al 2003 p 46 Penven et al 2001 Introduction p 1055 Penven et al 2001 Conclusion p 1057 Franzese Goldstein amp Skrivanek 2012 Casal Beal amp Lumpkin 2006 Abstract Introduction pp 1718 1719 Fig 7 p 1727 Sebille Johns amp Beal 2012 3 1 Connectivity Between the DWBC and the Agulhas Region Agulhas Bank complex MPA www marineprotectedareas org Archived from the original on 8 October 2023 Retrieved 15 January 2024 Exploring the last frontiers Reef pinnacles on the Agulhas Bank archive saeon ac za Archived from the original on 15 January 2024 Retrieved 15 January 2024 Department of Environmental Affairs 23 May 2019 National Environmental Management Protected Areas Act 2003 Act No 57 of 2003 Regulations for the Management of the Agulhas Bank Complex Marine Protected Area PDF Government Gazette Pretoria Government Printer Gotz Albrecht Kerwath Sven Samaai Toufiek 2010 Exploring the depths Quest 6 4 28 30 Durrheim 1987 Geological evolution of the Agulhas Bank pp 395 396 a b Parsiegla et al 2009 Geological and Tectonic Background pp 2 4 Golonka amp Bocharova 2000 Figs 3 8 Gohl amp Uenzelmann Neben 2012 Figs 1 5 Uenzelmann Neben amp Gohl 2003 Abstract Bird 2001 p 152 Parsiegla et al 2009 Introduction 3 p 2 Geological and Tectonic Background 6 p 3 Fig 3 p 5 Parsiegla et al 2009 The Diaz Marginal Ridge pp 12 14 Goodlad Martin amp Hartnay 1982 Parsiegla et al 2009 Fig 1 Dingle R V Gentle R I March 1972 Early Tertiary volcanic rocks on the Agulhas Bank South African Continental Shelf Geological Magazine 109 2 127 136 Bibcode 1972GeoM 109 127D doi 10 1017 S0016756800039510 S2CID 129088205 Archived from the original on 16 April 2021 Retrieved 16 April 2021 via Cambridge University Press published online 01 May 2009 Uenzelmann Neben amp Huhn 2009 pp 66 76 Marean 2011 pp 421 423 Marean 2011 pp 423 425 Compton 2011 p 508 a b Assessment of Offshore Benthic Biodiversity on the Agulhas Bank and the Potential Role of Petroleum WWF November 2008 Archived from the original on 2015 01 25 Retrieved 12 November 2016 Jury 2011 pp 1 2 a b Griffith et al 2010 p 1 a b Grantham et al 2011 p 2 Griffith et al 2010 pp 6 8 Huggett et al 2012 Sink et al 2012b a b Crawford et al 2006 Introduction Sink et al 2012a Ebert Compagno amp Cowley 1992 Introduction Harding 2013 Abstract Ryan 2006 Albatross Task Force BirdLife South Africa Archived from the original on 28 October 2016 Retrieved 12 November 2016 South African Fur Seal Seal Conservation Society 2011 Archived from the original on 7 November 2016 Retrieved 12 November 2016 Nuwer Rachel March 2015 Fur Seals Caught Preying on Sharks Off South Africa Smithsonian Magazine Archived from the original on 31 January 2017 Retrieved 12 November 2016 Elwen et al 2011 p 470 Williams et al 2009 Abstract Foote et al 2011 p 5 Bruyn Hofmeyr amp Villiers 2006 Bianucci Lambert amp Post 2007 Abstract Elwen et al 2013 Introduction a b c d e f Meet South Africa s new Marine Protected Areas www marineprotectedareas org za Archived from the original on 19 January 2019 Retrieved 18 January 2019 a b c d e f g h i j k Declarations Pretoria Government Printer 31 August 1998 Archived from the original on 19 January 2019 Retrieved 18 January 2019 via Centre for Environmental rights Sources edit Bianucci G Lambert O Post K 2007 A high diversity in fossil beaked whales Mammalia Odontoceti Ziphiidae recovered by trawling from the sea floor off South Africa PDF Biodiversitas 29 4 Archived from the original PDF on 8 February 2015 Retrieved 8 February 2015 Bird D 2001 Shear margins Continent ocean transform and fracture zone boundaries PDF The Leading Edge 20 2 150 159 Bibcode 2001LeaEd 20 150B doi 10 1190 1 1438894 Retrieved 4 January 2015 Blanke B Penven P Roy C Chang N Kokoszka F 2009 Ocean variability over the Agulhas Bank and its dynamical connection with the southern Benguela upwelling system PDF Journal of Geophysical Research 114 C12028 C12028 Bibcode 2009JGRC 11412028B doi 10 1029 2009JC005358 Retrieved 2 January 2015 Bruyn P J N de Hofmeyr G J G Villiers M S de 2006 First record of a vagrant Commerson s dolphin Cephalorhynchus commersonii at the southern African continental shelf PDF African Zoology 41 1 Retrieved 15 February 2015 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Casal T G D Beal L M Lumpkin R 2006 A North Atlantic deep water eddy in the Agulhas Current system Deep Sea Research Part I 53 10 1718 1728 Bibcode 2006DSRI 53 1718C doi 10 1016 j dsr 2006 08 007 Compton J S 2011 Pleistocene sea level fluctuations and human evolution on the southern coastal plain of South Africa PDF Quaternary Science Reviews 30 5 506 527 Bibcode 2011QSRv 30 506C doi 10 1016 j quascirev 2010 12 012 Retrieved 10 January 2015 Crawford R J M Hemming M Kemper J Klage N T W Randall R M Underhill L G Venter A D Wolfaardt A C 2006 S24 2 Molt of the African penguin Spheniscus demersus in relation to its breeding season and food availability PDF Acta Zoologica Sinica 52 Supplement 444 447 Archived from the original PDF on 5 November 2016 Retrieved 1 March 2015 Durrheim R J 1987 Seismic reflection and refraction studies of the deep structure of the Agulhas Bank Geophysical Journal International 89 1 395 398 Bibcode 1987GeoJ 89 395D doi 10 1111 j 1365 246X 1987 tb04437 x Ebert D A Compagno L J V Cowley P D 1992 A preliminary investigation of the feeding ecology of squaloid sharks off the west coast of southern Africa South African Journal of Marine Science 12 1 601 609 doi 10 2989 02577619209504727 Elwen S H Findlay K P Kiszka J Weir C R 2011 Cetacean research in the southern African subregion a review of previous studies and current knowledge PDF African Journal of Marine Science 33 3 469 493 Bibcode 2011AfJMS 33 469E doi 10 2989 1814232x 2011 637614 hdl 2263 19661 S2CID 42374365 Retrieved 28 March 2015 Elwen S H Gridley T Roux J P Best P B Smale M J 2013 Records of kogiid whales in Namibia including the first 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Retrieved 4 February 2015 Golonka J Bocharova N Y 2000 Hot spot activity and the break up of Pangea Palaeogeography Palaeoclimatology Palaeoecology 161 1 2 49 69 Bibcode 2000PPP 161 49G doi 10 1016 s0031 0182 00 00117 6 Retrieved 15 February 2015 Goodlad S W Martin A K Hartnay C J H 1982 Mesozoic magnetic anomalies in the southern Natal Valley Nature 295 25 686 688 Bibcode 1982Natur 295 686G doi 10 1038 295686a0 S2CID 4313176 Retrieved 6 April 2015 Grantham H S Game E T Lombard A T Hobday A J Richardson A J Beckley L E Pressey R L Huggett J A Coetzee J C van der Lingen C D Petersen S L Merkle D Possingham H P 2011 Accommodating Dynamic Oceanographic Processes and Pelagic Biodiversity in Marine Conservation Planning PLOS ONE 6 2 e16552 Bibcode 2011PLoSO 616552G doi 10 1371 journal pone 0016552 PMC 3032775 PMID 21311757 Griffith C L Robinson T B Lange L Mead A 2010 Marine Biodiversity in South Africa An Evaluation of Current States of Knowledge PLOS ONE 5 8 e12008 Bibcode 2010PLoSO 512008G doi 10 1371 journal pone 0012008 PMC 2914023 PMID 20689849 Gyory J Beal L M Bischof B Mariano A J Ryan E H 2004 The Agulhas Current Rosenstiel School of Marine Atmospheric and Earth Science Retrieved 4 April 2015 Harding C T 2013 Tracking African penguins Spheniscus demersus outside of the breeding season Regional effects and fishing pressure during the pre moult period MSc Percy FitzPatrick Institute of African Ornithology University of Cape Town Retrieved 1 March 2015 Huggett J Lamont T Coetzee J Lingen Carl van der 2012 Are Changes in the Copepod Community on the Agulhas Bank over the Last Two Decades Mediated by Environmental factors or Predation PDF American Geophysical Union Chapman Conference Retrieved 15 February 2015 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help CS1 maint multiple names authors list link 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 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Jury Mark R 2011 Environmental Influences on South African Fish Catch South Coast Transition International Journal of Oceanography 2011 920414 1 10 doi 10 1155 2011 920414 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 4 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 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Marean C W 2011 Coastal South Africa and the Coevolution of the Modern Human Lineage and the Coastal Adaptation PDF In Bicho N F Haws J A Davis L G eds Trekking the Shore Changing Coastlines and the Antiquity of Coastal Settlement Interdisciplinary Contributions to Archaeology Springer pp 421 440 ISBN 978 1 4419 8219 3 Retrieved 6 January 2015 Parsiegla N Stankiewicz J Gohl K Ryberg T Uenzelmann Neben G 2009 Southern African continental margin Dynamic processes of a transform margin PDF Geochemistry Geophysics Geosystems 10 3 Q03007 Bibcode 2009GGG 10 3007P doi 10 1029 2008GC002196 Penven P Lutjeharms J R E Marchesiello P Roy C Weeks S J 2001 Generation of cyclonic eddies by the Agulhas Current in the lee of the Agulhas Bank Geophysical Research Letters 28 6 1055 1058 Bibcode 2001GeoRL 28 1055P doi 10 1029 2000gl011760 Ruijter W P M de Cunningham S A Gordon A L Lutjeharms J R E Matano R P Piola A R 2003 On the South Atlantic Climate Observing System SACOS PDF Report of the CLIVAR OOPC IAI Workshop Retrieved 4 January 2015 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Ryan P 2006 The long haul a decade of conserving albatrosses and petrels PDF Africa Birds and Birding 11 2 52 59 Archived from the original PDF on 2 April 2015 Retrieved 29 March 2015 Sebille Erik van Johns W E Beal L M 2012 Does the vorticity flux from Agulhas rings control the zonal pathway of NADW across the South Atlantic Journal of Geophysical Research 117 C5 C05037 Bibcode 2012JGRC 117 5037V doi 10 1029 2011JC007684 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Sink K Holness S Harris L Majiedt P Atkinson L Robinson T Kirkman S Hutchings L Leslie R Lamberth S Kerwath S von der Heyden S Lombard A Attwood C Branch G Fairweather T Taljaard S Weerts S Cowley P Awad A Halpern B Grantham H Wolf T 2012 National Biodiversity Assessment 2011 Technical Report PDF Report Vol 4 Marine and Coastal Component Pretoria South African National Biodiversity Institute Retrieved 29 March 2015 Sink K Leslie R Samaal T Attwood C 2012a Agulhas Bank South Africa PDF Southern Indian Ocean Regional Workshop to Facilitate the Description of Ecologically or Biologically Significant Marine Areas EBSAs Retrieved 29 March 2015 Sink K Leslie R Samaal T Attwood C 2012b Agulhas slope and seamounts PDF Southern Indian Ocean Regional Workshop to Facilitate the Description of Ecologically or Biologically Significant Marine Areas EBSAs Retrieved 29 March 2015 Uenzelmann Neben G Gohl K 2003 Agulhas Ridge South Atlantic the peculiar structure of a transform fault Workshop on East West Antarctic Tectonics and Gondwana Breakup 60W to 60E as Part of the 9th International Symposium on Antarctic Earth Sciences ISAES 836 Bibcode 2003EAEJA 836U hdl 10013 epic 19692 Uenzelmann Neben G Huhn K 2009 Sedimentary deposits on the southern South African continental margin Slumping versus non deposition or erosion by oceanic currents PDF Marine Geology 266 1 4 65 79 Bibcode 2009MGeol 266 65U doi 10 1016 j margeo 2009 07 011 Whittle C P 2012 Characterization of Agulhas Bank upwelling variability from satellite derived sea surface temperature and ocean colour products PDF American Geophysical Union Chapman Conference Retrieved 2 January 2015 Williams A J Petersen S L Goren M Watkins B P 2009 Sightings of killer whales Orcinus orca from longline vessels in South African waters and consideration of the regional conservation status African Journal of Marine Science 31 1 81 86 Bibcode 2009AfJMS 31 81W doi 10 2989 AJMS 2009 31 1 7 778 S2CID 86031606 Retrieved from https en wikipedia org w index php title Agulhas Bank amp oldid 1218535766, wikipedia, wiki, book, books, library,

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