Pangaea or Pangea ( )
Origin of the concept
The name "Pangaea" is derived from
Ancient Greek pan (, "all, entire, whole") and
Gaia or Gaea (, "
Mother goddess, land").
The first to suggest that the continents were once joined and later separated may have been
Abraham Ortelius in 1596. The concept that the continents once formed a contiguous land mass was hypothesised, with corroborating evidence, by
Alfred Wegener, the originator of the scientific theory of continental drift, in three 1912 academic journal articles written in German titled
Die Entstehung der Kontinente (
The Origin of Continents).
[Alfred Wegener: Die Entstehung der Kontinente. Dr. A. Petermann's Mitteilungen aus Justus Perthes' Geographischer Anstalt, 58(1): Gotha 1912] He expanded upon his hypothesis in his 1915 book of the same title, in which he postulated that, before breaking up and drifting to their present locations, all the continents had formed a single
supercontinent that he called the
Urkontinent.
Wegener used the name "Pangaea" once in the 1920 edition of his book, referring to the ancient supercontinent as "the Pangaea of the Carboniferous".[See:
]
-
Wegener, Alfred, Die Entstehung der Kontinente und Ozeane, 2nd ed. (Braunschweig, Germany: F. Vieweg, 1920), p. 120: "Schon die Pangäa der Karbonzeit hatte so einen Vorderrand ... " Already (In the 1922 edition, see p. 130.)
-
Wegener, A.; Krause, R.; Thiede, J. (2005). "Kontinental-Verschiebungen: Originalnotizen und Literaturauszüge"(Continental drift: the original notes and quotations). Berichte zur Polar- und Meeresforschung (Reports on Polar and Marine Research) 516. Alfred-Wegener-Institut: Bremerhaven, p. 4, n. 2
He used the Germanized form Pangäa, but the name entered German and English scientific literature (in 1922[Willem A. J. M. van Waterschoot van der Gracht (and 13 other authors): Theory of Continental Drift: a Symposium of the Origin and Movements of Land-masses of both Inter-Continental and Intra-Continental, as proposed by Alfred Wegener. X + 240 S., Tulsa, Oklahoma, United States, The American Association of Petroleum Geologists & London, Thomas Murby & Co.]
Wegener originally proposed that the breakup of Pangaea was caused by centripetal forces from Earth's rotation acting on the high continents. However, this mechanism was easily shown to be physically implausible, which delayed acceptance of the Pangaea hypothesis.
Evidence of existence
The geography of the continents bordering the Atlantic Ocean was the first evidence suggesting the existence of Pangaea. The seemingly close fit of the coastlines of North and South America with Europe and Africa was remarked on almost as soon as these coasts were charted. Careful reconstructions showed that the mismatch at the contour was less than , and it was argued that this was much too similar to be attributed to coincidence.
Additional evidence for Pangaea is found in the geology of adjacent continents, including matching geological trends between the eastern coast of South America and the western coast of Africa. The polar ice cap of the Carboniferous covered the southern end of Pangaea. Glacial deposits, specifically till, of the same age and structure are found on many separate continents that would have been together in the continent of Pangaea.[Murck, Barbara W. and Skinner, Brian J. (1999) Geology Today: Understanding Our Planet, Study Guide, Wiley, ] The continuity of mountain chains provides further evidence, such as the Appalachian Mountains chain extending from the southeastern United States to the Scandinavian Caledonides of Europe;[Merali, Zeeya and Skinner, Brian J. (2009) Visualizing Earth Science, Wiley, ] these are now believed to have formed a single chain, the Central Pangean Mountains.
Fossil evidence for Pangaea includes the presence of similar and identical species on continents that are now great distances apart. For example, fossils of the therapsid Lystrosaurus have been found in South Africa, India and Antarctica, alongside members of the Glossopteris flora, whose distribution would have ranged from the polar circle to the equator if the continents had been in their present position; similarly, the freshwater reptile Mesosaurus has been found only in localized regions of the coasts of Brazil and West Africa.[Benton, M.J. (2005) Vertebrate Palaeontology. Third edition, Oxford, p. 25.]
Geologists can also determine Plate tectonics by examining the orientation of Paleomagnetism. When rocks are formed, they take on the magnetic orientation of the Earth, showing which direction the poles lie relative to the rock; this determines latitudes and orientations (though not longitudes). Magnetic differences between samples of sedimentary rock and intrusive igneous rock whose age varies by millions of years is due to a combination of magnetic polar wander (with a cycle of a few thousand years) and the drifting of continents over millions of years. The polar wander component, which is identical for all contemporaneous samples, can be subtracted, leaving the portion that shows continental drift and can be used to help reconstruct earlier continental latitudes and orientations.
Formation
Pangaea is the most recent supercontinent reconstructed from the geologic record and therefore is by far the best understood. The formation of supercontinents and their breakup appears to be cyclical through Earth's history. There may have been several others before Pangaea.
Paleomagnetic measurements help geologists determine the latitude and orientation of ancient continental blocks, and newer techniques may help determine longitudes.
Previous supercontinents
The fourth-last supercontinent, called Columbia or Nuna, appears to have assembled in the period 2.0–1.8 billion years ago (Ga).
Columbia/Nuna broke up, and the next supercontinent,
Rodinia, formed from the accretion and assembly of its fragments. Rodinia lasted from about 1.3 billion years ago until about 750 million years ago, but its configuration and geodynamic history are not nearly as well understood as those of the later supercontinents,
Pannotia and Pangaea.
According to one reconstruction,
Most of these landmasses coalesced again to form the relatively short-lived supercontinent Pannotia, which included large areas of land near the poles and a small strip connecting the polar masses near the equator. Pannotia lasted until 540 Megaannum, near the beginning of the Cambrian and then broke up, giving rise to the continents of Laurentia, Baltica, and the southern supercontinent Gondwana.
Formation of Euramerica (Laurussia)
In the Cambrian, Laurentia—which would later become
North America—sat on the
equator with three bordering oceans: the Panthalassic Ocean to the north and west, the Iapetus Ocean to the south, and the
Khanty Ocean to the east. In the early
Ordovician, around 480 Ma, the microcontinent
Avalonia—a landmass incorporating fragments of what would become eastern Newfoundland, the southern
British Isles, and parts of
Belgium, northern
France,
Nova Scotia,
New England, South Iberia, and northwest Africa—broke free from Gondwana and began its journey to Laurentia.
Baltica, Laurentia, and Avalonia all came together by the end of the Ordovician to form a landmass called
Euramerica or Laurussia, closing the Iapetus Ocean. The collision resulted in the formation of the northern Appalachians. Siberia sat near Euramerica, with the Khanty Ocean between the two continents. While all this was happening, Gondwana drifted slowly towards the South Pole. This was the first step of the formation of Pangaea.
Collision of Gondwana with Euramerica
The second step in the formation of Pangaea was the collision of Gondwana with Euramerica. By the middle of the
Silurian, 430 Ma, Baltica had already collided with Laurentia, forming Euramerica, an event called the Caledonian orogeny. As Avalonia inched towards Laurentia, the seaway between them, a remnant of the Iapetus Ocean, was slowly shrinking. Meanwhile,
southern Europe broke off from Gondwana and began to move towards Euramerica across the
Rheic Ocean. It collided with southern Baltica in the Devonian.
By the late Silurian, Annamia (Indochina)
The Variscan orogeny raised the Central Pangaean Mountains, which were comparable to the modern Himalayas in scale.
Formation of Laurasia
Western Kazakhstania collided with Baltica in the late Carboniferous, closing the
Ural Ocean and the western Proto-Tethys (
Uralian orogeny), causing the formation of the
Ural Mountains and
Laurasia. This was the last step of the formation of Pangaea. Meanwhile, South America had collided with southern Laurentia, closing the Rheic Ocean and completing the Variscian orogeny with the formation of the southernmost part of the Appalachians and Ouachita Mountains. By this time, Gondwana was positioned near the South Pole, and glaciers formed in Antarctica, India, Australia, southern Africa, and South America. The North China Craton collided with Siberia by the
Jurassic, completely closing the Proto-Tethys Ocean.
By the Cisuralian, the Cimmerian plate split from Gondwana and moved towards Laurasia, thus closing the Paleo-Tethys Ocean and forming the Tethys Ocean in its southern end. Most of the landmasses were all in one. By the Triassic, Pangaea rotated a little, and the Cimmerian plate was still travelling across the shrinking Paleo-Tethys until the Middle Jurassic. By the Late Triassic, the Paleo-Tethys had closed from west to east, creating the Cimmerian Orogeny. Pangaea, which looked like a C, with the Tethys Ocean inside the C, had rifted by the Middle Jurassic.
Paleogeography
Geography during the Carboniferous
Pangaea, having formed recently during the late Carboniferous period, had two major landmasses —
Gondwana in the south and
Laurussia in the north west with
Siberia and
Amur plate lying north of
Laurussia.
To the east of
Siberia —
Kazakhstania, North China and South China formed the northern margin of the
Paleo-Tethys sea, with Annamia in the south, in together resembling a circle with the
superocean Panthalassa lying beyond.
This period is also marked by the formation of the Central Pangaean Mountains.
Geography during the Permian
By the
Permian, Pangaea had consolidated in its extent, reaching from the
equator to both of the
polar regions. Its immense expanse thus had a major influence on the ocean currents of its surrounding water bodies — the
superocean Panthalassa and the
Paleo-Tethys in addition to the new
Neotethys Ocean forming to its south.
The early Permian also saw the Cimmerian plate being rifted and detached from the Gondwanan shores of the Paleo-Tethys, forming the Cimmerian terranes.
The Central Pangaean Mountains reached their maximum elevation during the early Permian (295 Mya) comparable to the present day Himalayan mountain range. These mountains underwent immense physical and mechanical weathering, creating deep valleys and reducing the mountains to half their original elevation by the Lopingian.
By the end of the Permian period, the North China Craton, the South China Block and Indochina fused together and with Pangaea.
Geography during the Triassic
Pangaea experienced widespread faulting during the Triassic, also accompanied by a substantial reduction of the Central Pangean Mountains by the
Middle Triassic.
The Cimmerian terranes, that had detached from Gondwana in the early Permian drifted northwards during the Triassic, increasing the expanse of the Neo-Tethys Ocean which had formed from this event while shrinking the Paleo-Tethys.
Geography during the Jurassic
By the
Early Jurassic, Pangaea began to
rift and break-up into northern
Laurasia and southern
Gondwana with the Central Pangean Mountains having practically disintegrated.
The supercontinent finally broke up by the
Middle Jurassic period.
Paleoclimate
Since Pangaea existed for a span of millions of years, from the late
Carboniferous period up until the early
Jurassic period, its climate varied across these periods.
Due to its geographic extent, it experienced significant climatic variations.
Interior climate
The inner parts of the
supercontinent were, in comparison to its
, significantly
arid and cooler, likely forming one of the most extensive desert systems in Earth's geological history with extreme variations of heat and cold (continental climate),
though several paleoclimatologists have found evidence of short rainy seasons in the interior regions.
Oceanic influences
Pangaea's
climate was also influenced by the water bodies of that
Mesozoic (the
superocean Panthalassa, the Paleo Tethys and the
Tethys Ocean seas). The Paleo Tethys and
Tethys Ocean , surrounded on their peripheries by various parts of Pangaea together formed an immense warm water sea and isolated the equatorial waters of
Panthalassa from cold
ocean currents. This warm-water system also influenced the supercontinent's
climate by bringing tropical moisture laden-air from the surrounding seas over the land, henceforth causing rainfall.
Monsoons and rainfall
-
During the late Carboniferous, regions of present day Europe and Eastern North America experienced significant wetter, swamp like conditions due to the Central Pangean Mountains forming a perennial monsoon climate in that area,
-
During the Permian period, the landmass received seasonal rainfall in contrast to the aforementioned dryness.
-
During the Triassic period, the monsoons reached their maximum extent, such that the previously dry conditions of the Colorado Plateau were alleviated and it started to receive moisture due to the changing wind directions. In contrast, the regions of present day Australia were at higher latitudes and experienced much drier and seasonal conditions around the same time.
-
During the Jurassic, the megamonsoon declined and the regions of Gondwana and southern Laurasia experienced dry conditions.
Post-breakup
When Pangaea finally broke apart by the middle
Mesozoic era, the megamonsoon fell apart completely.
The breakup could have also contributed to an increase in polar temperatures as colder waters mixed with warmer waters.
Life
Pangaea existed as a supercontinent for 160 million years, from its assembly around 335 Ma (Early Carboniferous) to its breakup 175 Ma (Middle Jurassic).
During this interval, important developments in the evolution of life took place. The seas of the Early Carboniferous were dominated by
rugose corals,
,
,
, and the first
bony fish. Life on land was dominated by
lycopsid forests inhabited by
and other
and the first
.
By the time Pangaea broke up, in the Middle Jurassic, the seas swarmed with
(particularly
),
, sharks and rays, and the first ray-finned bony fishes, while life on land was dominated by forests of
and
in which
flourished and in which the first true
had appeared.
The evolution of life in this time reflected the conditions created by the assembly of Pangaea. The union of most of the continental crust into one landmass reduced the extent of sea coasts. Increased erosion from uplifted continental crust increased the importance of floodplain and delta environments relative to shallow marine environments. Continental assembly and uplift also meant increasingly arid land climates, favoring the evolution of amniotes animals and , whose eggs and seeds were better adapted to dry climates.
Coal forest typically form in perpetually wet regions close to the equator. The assembly of Pangaea disrupted the Intertropical Convergence Zone and created an extreme monsoon climate that reduced the deposition of coal to its lowest level in the last 300 million years. During the Permian, coal deposition was largely restricted to the North and South China microcontinents, which were among the few areas of continental crust that had not joined with Pangaea.
The lack of oceanic barriers is thought to have favored cosmopolitanism, in which successful species attain wide geographical distribution. Cosmopolitanism was also driven by Extinction event, including the Permian–Triassic extinction event, the most severe in the fossil record, and also the Triassic–Jurassic extinction event. These events resulted in disaster fauna showing little diversity and high cosmopolitanism, including Lystrosaurus, which opportunistically spread to every corner of Pangaea following the Permian–Triassic extinction event.
Mass extinctions
The tectonics and geography of Pangaea may have worsened the Permian–Triassic extinction event or other mass extinctions. For example, the reduced area of continental shelf environments may have left marine species vulnerable to extinction.
However, no evidence for a species-area effect has been found in more recent and better characterized portions of the geologic record.
Another possibility is that reduced seafloor spreading associated with the formation of Pangaea, and the resulting cooling and subsidence of
oceanic crust, may have reduced the number of islands that could have served as refugia for marine species. Species diversity may have already been reduced prior to mass extinction events due to mingling of species possible when formerly separate continents were merged. However, there is strong evidence that climate barriers continued to separate ecological communities in different parts of Pangaea. The eruptions of the
Emeishan Traps may have eliminated South China, one of the few continental areas not merged with Pangaea, as a refugium.
Rifting and break-up
There were three major phases in the break-up of Pangaea.
Opening of the Atlantic
The Atlantic Ocean did not open uniformly;
began in the north-central Atlantic. The first breakup of Pangaea is proposed for the late
Ladinian (230 Ma) with initial spreading in the opening central Atlantic. Then the rifting proceeded along the eastern margin of North America, the northwest African margin and the
High Atlas,
Saharan Atlas and Tunisian
Atlas Mountains.
[Antonio Schettino, Eugenio Turco: Breakup of Pangaea and plate kinematics of the central Atlantic and Atlas regions. In: Geophysical Journal International, Band 178, Ausgabe 2, August 2009, S. 1078–1097.]
Another phase began in the Early-Middle Jurassic (about 175 Ma), when Pangaea began to rift from the Tethys Ocean in the east to the Pacific Ocean in the west. The rifting that took place between North America and Africa produced multiple failed rifts. One rift resulted in the North Atlantic Ocean.
Break-up of Gondwana
second major phase in the break-up of Pangaea began in the Early Cretaceous (150–140 Ma), when Gondwana separated into multiple continents (Africa, South America, India, Antarctica, and Australia). The subduction at
Tethyan Trench probably caused Africa, India and Australia to move northward, causing the opening of a "South Indian Ocean". In the Early Cretaceous,
Atlantica, today's South America and Africa, separated from eastern Gondwana. Then in the Middle Cretaceous, Gondwana fragmented to open up the South Atlantic Ocean as South America started to move westward away from Africa. The South Atlantic did not develop uniformly; rather, it rifted from south to north.
Also, at the same time, Madagascar and
Insular India began to separate from Antarctica and moved northward, opening up the Indian Ocean. Madagascar and India separated from each other 100–90 Ma in the Late Cretaceous. India continued to move northward toward Eurasia at 15 centimeters (6 in) per year (a plate tectonic record), closing the eastern Tethys Ocean, while Madagascar stopped and became locked to the
African Plate.
New Zealand,
New Caledonia and the rest of
Zealandia began to separate from Australia, moving eastward toward the Pacific and opening the
Coral Sea and
Tasman Sea.
Opening of the Norwegian Sea and break-up of Australia and Antarctica
The third major and final phase of the break-up of Pangaea occurred in the early Cenozoic (
Paleocene to
Oligocene). Laurasia split when Laurentia broke from Eurasia, opening the
Norwegian Sea about 60–55 Ma. The Atlantic and Indian Oceans continued to expand, closing the Tethys Ocean.
Meanwhile, Australia split from Antarctica and moved quickly northward, just as India had done more than 40 million years before. Australia is currently on a collision course with eastern Asia. Both Australia and India are currently moving northeast at 5–6 centimeters (2–3 in) per year. Antarctica has been near or at the South Pole since the formation of Pangaea about 280 Ma. India started to collide with Asia beginning about 35 Ma, forming the Himalayan orogeny and closing the Tethys Ocean; this collision continues today. The African Plate started to change directions, from west to northwest toward Europe, and South America began to move in a northward direction, separating it from Antarctica and allowing complete oceanic circulation around Antarctica for the first time. This motion, together with decreasing atmospheric carbon dioxide concentrations, caused a rapid cooling of Antarctica and allowed to form. This glaciation eventually coalesced into the kilometers-thick ice sheets seen today.
Climate change after Pangaea
The breakup of Pangaea was accompanied by outgassing of large quantities of carbon dioxide from continental rifts. This produced a Mesozoic CO
2 high that contributed to the very warm climate of the
Early Cretaceous.
The opening of the Tethys Ocean also contributed to the warming of the climate. The very active
mid-ocean ridges associated with the breakup of Pangaea raised sea levels to the highest in the geological record, flooding much of the continents.
The expansion of the temperate climate zones that accompanied the breakup of Pangaea may have contributed to the diversification of the angiosperms.
See also
External links
