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Panthalassa, also known as the Panthalassic Ocean or Panthalassan Ocean (from Greek πᾶν "all" and θάλασσα "sea"),[1] was the vast superocean that encompassed planet Earth and surrounded the supercontinent Pangaea, the latest in a series of supercontinents in the history of Earth. During the PaleozoicMesozoic transition (c. 250 Ma), the ocean occupied almost 70% of Earth's surface, with the supercontinent Pangaea taking up less than half. The original, ancient ocean floor has now completely disappeared because of the continuous subduction along the continental margins on its circumference.[2] Panthalassa is also referred to as the Paleo-Pacific ("old Pacific") or Proto-Pacific because the Pacific Ocean is a direct continuation of Panthalassa.

The Panthalassa superocean 250 million years ago
The supercontinent Pangaea in the early Mesozoic (at 200 Ma) surrounded by Panthalassa.
The Pacific Plate began forming when the triple junction at the center of Panthalassa destabilized about 190 million years ago.

Formation

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The supercontinent Rodinia began to break up 870–845 Ma probably as a consequence of a superplume caused by mantle slab avalanches along the margins of the supercontinent. In a second episode c. 750 Ma the western half of Rodinia started to rift apart: western Kalahari and South China broke away from the western margins of Laurentia; and by 720 Ma Australia and East Antarctica had also separated.[3] In the Early Jurassic the Pacific Plate opened originating from a triple junction between the Panthalassic Farallon, Phoenix, and Izanagi plates. Panthalassa can be reconstructed based on magnetic lineations and fracture zones preserved in the western Pacific.[4]

Reconstruction of ocean basin

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Most of the oceanic plates that formed the ocean floor of Panthalassa have been subducted and so traditional plate tectonic reconstructions based on magnetic anomalies can therefore be used only for remains from the Cretaceous and later. The former margins of the ocean, however, contain allochthonous terranes with preserved Triassic–Jurassic intra-Panthalassic volcanic arcs, including Kolyma–Omolon (northeast Asia), Anadyr–Koryak (east Asia), Oku–Niikappu (Japan), and Wrangellia and Stikinia (western North America). Furthermore, seismic tomography is being used to identify subducted slabs in the mantle from which the location of former Panthalassic subduction zones can be derived. A series of such subduction zones, called Telkhinia, defines two separate oceans or systems of oceanic plates—the Pontus and Thalassa oceans.[5] Named marginal oceans or oceanic plates include (clockwise) Mongol-Okhotsk (now a suture between Mongolia and Sea of Okhotsk), Oimyakon (between Asian craton and Kolyma-Omolon), Slide Mountain Ocean (British Columbia),[6] and Mezcalera (western Mexico).

Eastern margin

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The western margin (modern coordinates) of Laurentia originated during the Neoproterozoic break-up of Rodinia. The North American Cordillera is an accretionary orogen, which grew by the progressive addition of allochthonous terranes along this margin from the Late Palaeozoic. Devonian back-arc volcanism reveals how this eastern Panthalassic margin developed into the active margin it still is in the mid-Palaeozoic. Most of the continental fragments, volcanic arcs, and ocean basins added to Laurentia this way contained faunas of Tethyan or Asian affinity. Similar terranes added to the northern Laurentia, in contrast, have affinities with Baltica, Siberia, and the northern Caledonies. The latter terranes were probably accreted along the eastern Panthalassa margin by a CaribbeanScotia-style subduction system.[7]

Western margin

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The evolution of the Panthalassa–Tethys boundary is poorly known because little oceanic crust is preserved—both the Izanagi and the conjugate Pacific Ocean floor is subducted and the ocean ridge that separated them probably subducted c. 60–55 Ma. Today, the region is dominated by the collision of the Australian Plate with a complex network of plate boundaries in south-east Asia, including the Sundaland block. Spreading along the Pacific-Phoenix ridge ended 83 Ma at the Osbourn Trough at the Tonga-Kermadec Trench.[4]

During the Permian, atolls developed near the Equator on the mid-Panthalassic seamounts. As Panthalassa subducted along its western margin during the Triassic and Early Jurassic, those seamounts and palaeo-atolls were accreted as allochthonous limestone blocks and fragments along the Asian margin.[8] One such migrating atoll complex now form a two-kilometre-long (1.2 mi) and 100-to-150-metre-wide (330–490 ft) body of limestone in central Kyushu, south-west Japan.[9]

Fusuline foraminifera, a now extinct order of single-celled organisms, diversified extensively and developed gigantism—the genus Eopolydiexodina, for example, reached up to 16 cm (6.3 in) in size—and structural sophistication, including symbiont relationships with photosynthesising algae, during the Late Carboniferous and Permian,[10] in what is known as the Carboniferous-Earliest Permian Biodiversification Event.[11] The Capitanian mass extinction event c. 260 Ma, however, put an end to that development, with only dwarf taxa persisting throughout the Permian until the final fusuline extinction in the Great Dying c. 252 Ma. Permian fusulines also developed a remarkable provincialism by which fusulines can be grouped into six domains.[12] Because of the large size of Panthalassa, a hundred million years could separate the accretion of different groups of fusulines. Assuming a minimum accretion rate of 3 centimetres per year (1.2 in/year), the seamount chains on which those groups evolved would be separated by at least 3,000 km (1,900 mi). Those groups apparently evolved in completely different environments.[13]

A significant sea-level drop at the end of the Permian led to the end-Capitanian extinction event. The cause for the extinction is disputed, but a likely candidate is an episode of global cooling, which transformed a large amount of sea-water into continental ice.[14]

Seamounts accreted in eastern Australia as parts of the New England orogen reveal the hotspot history of Panthalassa.[15] From the Late Devonian to the Carboniferous, Gondwana and Panthalassa converged along the eastern margin of Australia along a west-dipping subduction system, which produced (west to east) a magmatic arc, a forearc basin, and an accretionary wedge. Subduction ceased along that margin in the Late Carboniferous and jumped eastward. From the Late Carboniferous to the Early Permian the New England orogen was dominated by an extensional setting related to a subduction to strike-slip transition. Subduction was re-initiated in the Permian and the granitic rocks of the New England Batholith were produced by a magmatic arc, indicating the presence of an active plate margin along most of the orogen. Permian to Cretaceous remains of the convergent margin, preserved as fragments in Zealandia (New Zealand, New Caledonia, and the Lord Howe Rise), were rifted off Australia during the Late Cretaceous to Early Tertiary break-up of eastern Gondwana and the opening of the Tasman Sea.[16]

The Cretaceous Junction Plate, located north of Australia, separated the eastern Tethys from Panthalassa.[17]

Palaeo-oceanography

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Panthalassa was a hemisphere-sized ocean, much larger than the modern Pacific. It could be expected that the large size would result in relatively simple ocean current circulation patterns, such as a single gyre in each hemisphere, and a mostly stagnant and stratified ocean. Modelling studies, however, suggest that an east–west sea surface temperature (SST) gradient was present in which the coldest water was brought to the surface by upwelling in the east while the warmest water extended west into the Tethys Ocean. Subtropical gyres dominated the circulation pattern. The two hemispherical belts were separated by the undulating Intertropical Convergence Zone (ITCZ).[18]

In northern Panthalassa, there were mid-latitude westerlies north of 60°N with easterlies between 60°N and the Equator. Atmospheric circulation north of 30°N is associated with the North Panthalassa High, which created Ekman convergence between 15°N and 50°N and Ekman divergence between 5°N and 10°N. A pattern developed that resulted in Sverdrup transport that went northward in divergence regions and southward in convergence regions. Western boundary currents resulted in an anti-cyclonic subtropical North Panthalassa gyre at mid-latitudes and a meridional anti-cyclonic circulation centred on 20°N.[18]

In tropical northern Panthalassa, trade winds created westward flows while equatorward flows were created by westerlies at higher latitudes. Consequently, trade winds moved water away from Gondwana towards Laurasia in the northern Panthalassa Equatorial Current. When the western margins of Panthalassa were reached, intense western boundary currents would form the Eastern Laurasia Current. At mid-latitudes, the North Panthalassa Current would bring the water back east where a weak Northwestern Gondwana Current would finally close the gyre. The accumulation of water along the western margin, coupled with the Coriolis effect, would have created a Panthalassa Equatorial Counter Current.[18]

In the southern Panthalassa, the four currents of the subtropical gyre, the South Panthalassa Gyre, rotated counterclockwise. The South Equatorial Panthalassa Current flowed westward between the Equator and 10°S into the western, intense South Panthalassa Current. The South Polar Current then completed the gyre as the Southwestern Gondwana Current. Near the poles easterlies created a subpolar gyre that rotated clockwise.[18]

See also

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  • Ring of Fire – Region around the rim of the Pacific Ocean where many volcanic eruptions and earthquakes occur
  • Paleontology – Study of life before the Holocene epoch
  • Plate tectonics – Movement of Earth's lithosphere

References

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  1. ^ "Panthalassa". Online Etymology Dictionary.
  2. ^ Isozaki 2014, Permo–Triassic Boundary Superanoxia and Extinction, pp. 290–291
  3. ^ Li et al. 2008, Superplume events, continental rifting, and the prolonged break-up process of Rodinia (ca. 860–570 Ma), pp. 199–201
  4. ^ a b Seton & Müller 2008, Introduction, p. 263
  5. ^ Van der Meer et al. 2012, p. 215
  6. ^ Nokleberg et al. 2000
  7. ^ Colpron & Nelson 2009, pp. 273–275
  8. ^ Kani, Hisanabe & Isozaki 2013, Geologic setting, p. 213
  9. ^ Kasuya, Isozaki & Igo 2012, Geological Setting, p. 612
  10. ^ Groves, John R.; Yue, Wang (1 September 2009). "Foraminiferal diversification during the late Paleozoic ice age". Paleobiology. 35 (3): 367–392. Bibcode:2009Pbio...35..367G. doi:10.1666/0094-8373-35.3.367. S2CID 130097035. Retrieved 4 September 2022.
  11. ^ Shi, Yukun; Wang, Xiangdong; Fan, Junxuan; Huang, Hao; Xu, Huiqing; Zhao, Yingying; Shen, Shuzhong (September 2021). "Carboniferous-earliest Permian marine biodiversification event (CPBE) during the Late Paleozoic Ice Age". Earth-Science Reviews. 220: 103699. Bibcode:2021ESRv..22003699S. doi:10.1016/j.earscirev.2021.103699. Retrieved 4 September 2022.
  12. ^ Kasuya, Isozaki & Igo 2012, Introduction, pp. 611–612
  13. ^ Kasuya, Isozaki & Igo 2012, Migrating seamounts and fusuline territories in Panthalassa, pp. 620–621
  14. ^ Kofukuda, Isozaki & Igo 2014, Global cooling as a possible cause, p. 64
  15. ^ Flood 1999, Abstract
  16. ^ Waschbusch, Beaumont & Korsch 1999, Tectonic setting of the New England orogen and adjacent basins, pp. 204–206
  17. ^ Talsma et al. 2010
  18. ^ a b c d Arias 2008, The Panthalassa Ocean, pp. 3–5

Sources

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  • "Early Triassic". Paleomap project. 24 January 2001. Retrieved 27 December 2016.