fbpx
Wikipedia

Cimmeria (continent)

May 06, 2023

Cimmeria was an ancient continent, or, rather, a string of microcontinents or terranes,[3] that rifted from Gondwana in the Southern Hemisphere and was accreted to Eurasia in the Northern Hemisphere. It consisted of parts of present-day Turkey, Iran, Afghanistan, Pakistan, Tibet, China, Myanmar, Thailand, and Malaysia.[4][5] Cimmeria rifted from the Gondwanan shores of the Paleo-Tethys Ocean during the Early Permian[6] and as the Neo-Tethys Ocean opened behind it, during the Permian, the Paleo-Tethys closed in front of it.[7] Because the different chunks of Cimmeria drifted northward at different rates, a Meso-Tethys Ocean formed between the different fragments during the Cisuralian.[8] Cimmeria rifted off Gondwana from east to west, from Australia to the eastern Mediterranean.[9] It stretched across several latitudes and spanned a wide range of climatic zones.[10]

Tectonic history of Cimmeria
Cimmeria rifted off Gondwana's north-eastern shores around 250 Ma.[1]
As Cimmeria migrated from Gondwana to Eurasia the Paleo-Tethys closed and the Neo-Tethys opened.[2]
After 150 million years Cimmeria collided with Eurasia and the Cimmerian orogeny closed the Paleo-Tethys. As the break-up of Gondwana began in the south, the opening of the Indian Ocean initiated the closure of the Neo-Tethys.[1]

History of the concept

First concepts

A "large, ancient Mediterranean Sea" was first proposed by Austrian palaeontologist Melchior Neumayr in 1883.[11] Studying the distribution of Jurassic faunas, he concluded that an equatorial ocean stretching from India to Central America must have separated a large continent in the northern hemisphere from one in the southern hemisphere. Austrian geologist Eduard Suess named this Mesozoic ocean the Tethys, a mythical ocean which separated a mythical continent – Gondwanaland, home of the tongue-shaped flora – from a boreal continent.[12] German geophysicist Alfred Wegener, in contrast, developed a concept of a single, global continent – the supercontinent Pangea – which, in his view, left no room for an equatorial ocean. A wedge-shaped, east-facing Tethys within Pangea was, nevertheless, proposed by Australian geologist Samuel Warren Carey in 1958.[13] This ocean was later identified as a succession of oceans separated by north-migrating terranes or continental blocks, one of which was Cimmeria.

Iranian microcontinent

In 1974, after extensive field work in the Middle East, Swiss geologist Jovan Stöcklin identified the northern foot of the Alborz Range in northern Iran as the suture which in the Paleozoic was the northern shore of Gondwana and the remains of the Paleo-Tethys Ocean. Stöcklin also noted that an early Mesozoic or late Paleozoic rift separated the Iranian Plate from the Arabian Plate, and that another southern suture must be the remains of the Neo-Tethys Ocean. The opening of this later ocean, Stöcklin realized, must have transformed Iran into a microcontinent. Those observations made Stöcklin the first to identify a small part of what would later be known as Cimmeria.[14]

Stöcklin also noted that his proposal resembled the old concept of the world in which there were two continents, Angaraland in the north and Gondwana in the south, separated by an elongated ocean, the Tethys. Iran belonged to neither continent but was part of the realm of Tethys.[14] Stöcklin's southern suture was later confirmed by observations of the evolution of microflora in Iran, which had a Gondwanan affinity during the Carboniferous but a Eurasian affinity during the Late Triassic – Iran had clearly drifted from Gondwana to Laurasia.[15]

Eurasian superterrane

 
The Alpide belt is a system of sutures stretching across Eurasia within which the Cimmerian blocks are now located.

In the 1980s Turkish geologist Celâl Şengör finally extended Stöcklin's Iranian microcontinent further west to Turkey and further east to Tibet and the Far East.[16] Şengör also reused the name introduced by Suess in 1901, the "Kimmerisches Gebirge" – the "Crimean" or "Cimmerian Mountains".[15][17][18]

In the mountain range that now stretches from the Alps to Indonesia Şengör identified, using a simplified scheme, two distinct but superimposed orogenic systems containing a large number of anastomosing sutures: the older Cimmerides and the younger Alpides together forming what Şengör called the Tethysides super-orogenic system. These two orogenic systems are thus associated with two major periods of ocean closure: the earlier, northern, and much larger Cimmerides, and the later, southern, and smaller Alpides. Cimmeria was the long continental "archipelago" that separated the two oceans before the Paleo-Tethys closed.[18]

This realm of Tethys thus covers most of Eurasia and a large time span (from north to south):[18]

  • Laurasia, Permian to Cretaceous
  • Palaeo-Tethys, Early Carboniferous to Middle Jurassic
  • Cimmeria, Triassic to Middle Jurassic
  • Neo-Tethys, Permian or Triassic to Eocene, locally still extant
  • Gondwana, Ordovician to Jurassic

This simple scheme, however, partly obscures the complex nature of the Tethyan cycles and terms such as "Eocimmerian" and "Neocimmerian" is often used for Late Triassic and Late Jurassic events respectively.[19] Furthermore, a distinction is often made between two more recent Tethyan domains: the Alpine Tethys and the Neo-Tethys. The Alpine Tethys, the western domain in this scheme, separated south-western Europe from north-western Africa and was connected to the Central Atlantic. It is now completely closed and its suture encompasses the Maghrebids (stretching from Gibraltar to Sicily) as well as the Apennines and the Alps. The Neo-Tethys, the eastern domain, opened between Arabia and the Cimmerian terranes. The East Mediterranean Basin and the Gulf of Oman are considered relics of the Neo-Tethys which is thus still closing. These two domains were connected east of Sicily until the end of the Jurassic.[20]

Tectonic history

In the Late Paleozoic, when the Cimmerian blocks were still located on the northern margin of Gondwana, they were far away from any active margins and orogenic belts, but they had been affected by thermal subsidence since the Siluran opening of Paleo-Tethys. Carboniferous to Permian ophiolites along suture zones in Tibet and north-eastern Iran indicate that the active margin of Paleo-Tethys was located here.[21] It was slab-pull forces in the Paleo-Tethys that detached Cimmeria from Gondwana and opened the Neo-Tethys. The mid-ocean ridge in the Paleo-Tethys subducted under Eurasia, as evidenced by Permian MORB (mid-ocean ridge basalt) in Iran. Slab roll-back in the Paleo-Tethys opened a series of back-arc basins along the Eurasian margin and resulted in the collapse of the Variscan cordillera. As the Paleo-Tethys subducted under the Eurasian southern margin, back-arc oceans formed from Austria to China. Some of these back-arcs closed during the Cimmerian orogeny (e.g. the Karakaya-Küre sequence of back-arc oceans in Turkey), others remained open (e.g. the Meliata-Maliac-Pindos back-arc oceans in the eastern Mediterranean) leading to the formation of younger back-arc oceans.[9]

Turkey

See also: Geology of Turkey
 
Geological map of Turkey

Turkey is an assemblage of continental blocks that during the Permian were part of the northern margin of Gondwana. During the Permian-Triassic, as the Paleo-Tethys subducted under this margin (in what is today northern Turkey) a marginal sea opened and quickly filled with sediments (today the basement of the Sakarya Composite Terrane in the Pontides). During the Late Triassic the Neo-Tethys began opening behind Cimmeria when the Eastern Mediterranean and its two eastern branches opened into the Bitlis-Zagros ocean (the southern branch of the Neo-Tethys).[22]

During Early Jurassic Cimmeria began to disintegrate behind the Paleo-Tethyan volcanic arc. This opened the northern branch in the Neo-Tethys — the Intra-Pontide, Izmh[citation needed]-Ankara, and the Inner Tauride oceans. The closure of the Paleo-Tethys in the Middle Jurassic reduced the Cimmerian archipelago in Anatolia. South of the Cimmerian blocks there were now two branches of the Neo-Tethys, a northern, larger and more complex, and a southern, more reduced; the Anatolide-Tauride continent separated them, the small Sakarya continent was located within the northern branch. The Apulian continent was connected to the Anatolide-Tauride continent.[22]

These Neo-Tethyan branches reached their maximum width during the Early Cretaceous, after which subduction under Eurasia gradually consumed them. During the Middle-Late Cretaceous this subduction opened a back-arc basin, the Western Black Sea Basin, which stretched west into the Balkans north of the Rhodope-Pontide island arc there.[23] In the Cretaceous, this basin pushed the Istanbul terrane (near today's Istanbul) southward in front of it, from the Odesa Shelf in the north-western Black Sea. In the Eocene, the terrane finally collided with Cimmeria thereby ending the extension in the western Black Sea. Contemporaneously, the East Black Sea Basin opened when the East Black Sea Block was rotated counter-clockwise towards Caucasus.[24]

In the late Cretaceous northwards intra-oceanic subduction within the Neotethys gave way to the obduction of ophiolitic nappes over the Arabian platform from Turkey to Oman region. North of this subduction zone, remnants of the Neotethys ocean started to subduct northwards and led to the collision of Tauride Block with the Arabian plate during post-Oligocene times. North of these systems, the Tauride block collided with the southern margin of Eurasia by the end of the Cretaceous. Convergence continued until the end of Oligocene. The Arabian-Eurasian collision in eastern Turkey during the Late Eocene closed the two basins.[22]

During the Paleogene Neo-Tethyan oceanic crust attached to the African Plate subducted along the Crete and Cyprus trenches. The Anatolide-Tauride continent collided with the Pontide and Kırşehir blocks in the Late Paleocene-Early Eocene. This closed the Ankara-Erzincan branches of the northern Neo-Tethys. During this closure, slab roll-back and break-off in the Eocene resulted in inversion in the Pontides and widespread magmatism in northern Turkey. Extension and upwelling followed, resulting in melting of lithospheric material beneath the Pontides.[25]

In southern Turkey the northward subduction of the Neo-tethys along the Bitlis-Zagros subduction zone resulted in magmatism in the Maden-Helete arc (south-eastern Turkey) during the Late Cretaceous-Eocene and back-arc magmatism in the Taurides. The Bitlis-Zagros subduction zone finally closed in the Miocene and throughout the Oligocene-Neogene and Quaternary volcanism became increasingly localised. In the Late Oligocene, slab roll-back in the Hellenic Trench resulted in extension in the Aegean and western Turkey.[25]

Iran

See also: Geology of Iran

The subduction of western Neo-Tethys under Eurasia resulted in extensive magmatism in what is now northern Iran. In the Early Jurassic this magmatism had produced a slab pull force which contributed to the break-up of Pangea and the initial opening of the Atlantic. During the Late Jurassic-Early Cretaceous the subduction of the Neo-Tethys mid-ocean ridge contributed to the break-up of Gondwana, including the detachment of the Argo-Burma terrane from Australia.[9] The Central-East Iranian Microcontinent (CEIM) sutured with Eurasia in the Late Triassic during the regional "Eocimmerian" orogenic event in northern Iran, but Iran is made of several continental blocks and the area must have seen a number of ocean closures in the Late Paleozoic and Early Mesozoic.[26]

Caucasus

The Greater and Lesser Caucasus has a complicated geological history involving the accretion of a series of terranes and microcontinents from the Late Precambrian to the Jurassic within the Tethyan framework. These include the Greater Caucasian, Black Sea-Central Transcaucasian, Baiburt-Sevanian, and Iran-Afghanistan terranes and island arcs.[27] In the Caucasus region remnants of the Paleo-Tethys suture can be found in the Dzirula Massif which outcrops Early Jurassic sequences in central Georgia. It consists of Early Cambrian oceanic rocks and the possible remnants of a magmatic arc; their geometry suggests that suturing was followed by strike-slip faulting. Ophiolites also outcrop in the Khrami Massif in southern Georgia and another possible segment of the suture is present in the Svanetia region. The suture is older east of the Caucasus (northern Iran–Turkmenistan) but younger both west of the Caucasus and further east in Afghanistan and the northern Pamirs.[28]

Sibumasu

The easternmost part of Cimmeria, the Sibumasu terrane, remained attached to north-western Australia until 295–290 Ma when it began to drift northward, as supported by paleomagnetic and biogeographic data. The Qiangtang terrane was located west of Sibumasu and contiguous with it. Lower Permian layers in Sibumasu contain glacial-marine diamictites and Gondwanan faunas and floras which then developed independently before Sibumasu docked with Cathaysia. Sibumasu's rapid northern journey is especially evident in the development of brachiopods and fusulinids.[29]

The Baoshan terrane in western Yunnan, China, forms the northern part of Sibumasu. It is separated from the Burma Block by the Gaoligong Suture Zone to the west, and from the South China and Indochina continents in the east by the Chongshan Suture Zone and Changning-Menglian Belt. Like other parts of eastern Cimmeria, it was highly deformed by the intra-continental strike-slip faulting that followed the India-Asia collision.[30]

Paleomagnetic data indicate South China and Indochina moved from near Equator to 20°N from the Early Permian to Late Triassic. Baoshan, in contrast, moved from 42°S in the Early Permian to 15°N in the Late Triassic. These blocks and terranes occupied similar paleo-latitudes during Late Triassic to Jurassic which indicates that they probably collided in the Late Triassic. This is also supported by geological evidence: 200–230 Ma granite in Lincang, near the Changning-Menglian suture, indicate a continent-continent collision occurred there in the Late Triassic; pelagic sediments in the Changning-Menglian-Inthanon ophiolite belt (between Sibumasu and Indochina) ranges in age from Middle Devonian to Middle Triassic, while, in the Inthanon suture, in contrast, Middle to Late Triassic rocks are non-pelagic with radiolarian cherts and turbidic clastics indicating the two blocks had at least approached each other by that time; volcanic sequences from the Lancangjiang igneous zone indicate a post-collisional setting had developed before the eruptions there around 210 Ma; and, the Sibumasu fauna developed from a non-marine peri-Gondwanan assemblage in the early Permian, to an endemic Sibumasu fauna in the Middle Permian, and to an Equatorial-Cathaysian in the Late Permian.[31]

During the Early and Middle Palaeozoic Cimmeria was located at an Andean-style active margin. Glacial deposits and paleomagnetic data indicate that Qiangtang and Shan Thai-Malaya were still located far south adjacent to Gondwana during the Carboniferous. The equatorial fauna and flora of China indicate that it was separated from Gondwana during the Carboniferous.[4]

Lhasa

The Lhasa terrane has been interpreted as part of Cimmeria and, if this is the case, must have rifted from Gondwana together with Sibumasu and Qiantang. The timing of Lhasa's northward drift is still controversial, however, and paleomagnetic data is extremely scarce. Sedimentological and stratigraphical evidence, for example, suggest that it separated from Gondwana in the Late Triassic when Qiantang was already being accreted to Eurasia.[32] This proposed Late Triassic rifting of Lhasa has also been documented along the north-western shelf of Australia where the Western Burma and Woyla terranes eventually separated from Gondwana in the Late Jurassic.[33]

Today the Bangong suture separates the Lhasa terrane from the Qiangtang terrane.

Economic importance

The present remains of Cimmeria, as a result of the massive uplifting of its continental crust, are unusually rich in a number of rare chalcophile elements. Apart from the Altiplano in Bolivia, almost all the world's deposits of antimony as stibnite are found in Cimmeria, with the major mines being in Turkey, Yunnan and Thailand. The major deposits of tin are also found in Malaysia and Thailand, whilst Turkey also has major deposits of chromite ore.

See also

References

Notes

  1. ^ a b Reconstruction from Dèzes 1999, p. 16
  2. ^ Reconstruction from Stampfli & Borel 2002, p. 27
  3. ^ Cheng, Jian-Bo; Li, Ya-Lin; Li, Shuai; Xiao, Si-Qi; Bi, Wen-Jun; Zou, Yu (December 2022). "Reconstruction of the South Qiangtang–Zhongba–Tethyan Himalaya continental margin system along the northern Indian Plate: Insights from the paleobiogeography of the Zhongba microterrane". Journal of Asian Earth Sciences. 240: 105376. Bibcode:2022JAESc.24005376C. doi:10.1016/j.jseaes.2022.105376. S2CID 252703613. Retrieved 2 April 2023.
  4. ^ a b Scotese & McKerrow 1990, pp. 4, 5, 17
  5. ^ Ruban, Al-Husseini & Iwasaki 2007, pp. 37, 40, 43
  6. ^ Wang, X.-D; Ueno, K.; Mizuno, Y.; Sugiyama, T. (15 June 2001). "Late Paleozoic faunal, climatic, and geographic changes in the Baoshan block as a Gondwana-derived continental fragment in southwest China". Palaeogeography, Palaeoclimatology, Palaeoecology. 170 (3–4): 197–218. Bibcode:2001PPP...170..197W. doi:10.1016/S0031-0182(01)00228-0. Retrieved 17 October 2022.
  7. ^ Golonka 2007, p. 182
  8. ^ Xu, Hai Peng; Zhang, Yi-chun; Yuan, Dong-xun; Shen, Shu Zhong (1 September 2022). "Quantitative palaeobiogeography of the Kungurian–Roadian brachiopod faunas in the Tethys: Implications of allometric drifting of Cimmerian blocks and opening of the Meso-Tethys Ocean". Palaeogeography, Palaeoclimatology, Palaeoecology. 601: 111078. Bibcode:2022PPP...601k1078X. doi:10.1016/j.palaeo.2022.111078.
  9. ^ a b c Stampfli & Borel 2002, pp. 24, 28
  10. ^ Metcalfe 2002, p. 556
  11. ^ Neumayr 1883
  12. ^ Suess 1893; Suess 1901
  13. ^ Hsü & Bernoulli 1978, Paleotethys, pp. 943–944 and references therein including Carey 1958
  14. ^ a b Stöcklin 1974, Introduction, p. 873
  15. ^ a b Stampfli 2000, Some definitions, pp. 1–2
  16. ^ Şengör 1984, Şengör 1987
  17. ^ Suess 1901, p. 22
  18. ^ a b c Şengör et al. 1988, pp. 119–120, 123
  19. ^ See for example Frizon de Lamotte et al. 2011, The Zagros Domain and Its Arabian Foreland, p. 4
  20. ^ Frizon de Lamotte et al. 2011, Introduction, pp. 1, 4
  21. ^ Stampfli et al. 2001, Initial Conditions, pp. 57–58
  22. ^ a b c Şengör & Yilmaz 1981, Abstract
  23. ^ Hippolyte, J.-C.; Müller, C.; Kaymakci, N.; Sangu, E. (2010). "Dating of the Black Sea Basin: new nannoplankton ages from its inverted margin in the Central Pontides (Turkey)" (PDF). Geological Society, London, Special Publications. 340 (1): 113–136. Bibcode:2010GSLSP.340..113H. doi:10.1144/SP340.7. hdl:11511/48215. S2CID 128968783.
  24. ^ Okay, Şengör & Görür 1994, Abstract; Fig. 3, p. 269
  25. ^ a b Richards 2015, Turkey, pp. 329–330
  26. ^ Buchs et al. 2013, Introduction, pp. 267–268
  27. ^ Gamkrelidze & Shengelia 2007, Introduction, p. 57
  28. ^ Şengör et al. 1988, pp. 139–140
  29. ^ Metcalfe 2002, p. 556; Position of the Sibumasu Terrane, pp. 562–563; Position of the Qiangtang Terrane, p. 563
  30. ^ Zhao et al. 2015, Geological setting and sampling, p. 3
  31. ^ Zhao et al. 2015, The closure of the East Paleotethys Ocean, pp. 10–11, 13
  32. ^ Metcalfe 2002, Position of the Lhasa Terrane, p. 563
  33. ^ Metcalfe 1996, Late Triassic to Late Jurassic rifting, pp. 104–105

Sources

  • Buchs, D. M.; Bagheri, S.; Martin, L.; Hermann, J.; Arculus, R. (2013). "Paleozoic to Triassic ocean opening and closure preserved in Central Iran: Constraints from the geochemistry of meta-igneous rocks of the Anarak area". Lithos. 172: 267–287. Bibcode:2013Litho.172..267B. doi:10.1016/j.lithos.2013.02.009. Retrieved 8 July 2016.
  • Carey, S. W. (1958). The tectonic approach to continental drift. Continental Drift – A Symposium. Geology Dept., Univ. of Tasmania.
  • Dèzes, P. (1999). Tectonic and metamorphic evolution of the central Himalayan domain in southeast Zanskar (Kashmir, India) (PDF) (Thesis). Section des Sciences de la Terre, Université de Lausanne. Retrieved 3 July 2016.
  • Frizon de Lamotte, D.; Raulin, C.; Mouchot, N.; Wrobel‐Daveau, J. C.; Blanpied, C.; Ringenbach, J. C. (2011). "The southernmost margin of the Tethys realm during the Mesozoic and Cenozoic: Initial geometry and timing of the inversion processes". Tectonics. 30 (3): n/a. Bibcode:2011Tecto..30.3002F. doi:10.1029/2010TC002691. S2CID 129242341. Retrieved 16 July 2016.
  • Golonka, J. (2007). "Phanerozoic paleoenvironment and paleolithofacies maps: late Paleozoic". Geologia. 33 (2): 145–209. Retrieved 26 June 2016.
  • Gamkrelidze, I. P.; Shengelia, D. M. (2007). "Pre-Alpine geodynamics of the Caucasus, suprasubduction regional metamorphism and granitoid magmatism" (PDF). Bull. Georg. Natl. Acad. Sci. 175: 57–65. Retrieved 8 July 2016.
  • Hsü, K. J.; Bernoulli, D. (1978). "Genesis of the Tethys and the Mediterranean" (PDF). US Government Printing Office. Retrieved 5 July 2016. {{cite journal}}: Cite journal requires |journal= (help)
  • Metcalfe, I. (1996). "Pre-Cretaceous evolution of SE Asian terranes" (PDF). Geological Society, London, Special Publications. 106 (1): 97–122. Bibcode:1996GSLSP.106...97M. doi:10.1144/gsl.sp.1996.106.01.09. S2CID 128478812. Retrieved 17 July 2016.[dead link]
  • Metcalfe, I. (2002). "Permian tectonic framework and palaeogeography of SE Asia". Journal of Asian Earth Sciences. 20 (6): 551–566. Bibcode:2002JAESc..20..551M. doi:10.1016/s1367-9120(02)00022-6. Retrieved 7 July 2016.
  • Neumayr, M. (1883). "Über klimatische Zonen während der Jura- und Kreidezeit". Denkschriften der Akademie der Wissenschaften in Wien — Mathematisch-Naturwissenschaftliche Classe (in German). Vol. 47. Wien: Kaiserlich-Königlichen Hof- und Staatsdruckerei. pp. 277–310. OCLC 604278105. Retrieved 5 July 2016.
  • Okay, A. I.; Şengör, A. M. C.; Görür, N. (1994). "Kinematic history of the opening of the Black Sea and its effect on the surrounding regions" (PDF). Geology. 22 (3): 267–270. Bibcode:1994Geo....22..267O. doi:10.1130/0091-7613(1994)022<0267:khotoo>2.3.co;2. Retrieved 20 July 2016.
  • Richards, J. P. (2015). "Tectonic, magmatic, and metallogenic evolution of the Tethyan orogen: From subduction to collision". Ore Geology Reviews. 70: 323–345. Bibcode:2015OGRv...70..323R. doi:10.1016/j.oregeorev.2014.11.009. Retrieved 18 July 2016.
  • Ruban, D.A.; Al-Husseini, M.I.; Iwasaki, Y. (2007). "Review of Middle East Paleozoic plate tectonics". GeoArabia. 12 (3): 35–56. doi:10.2113/geoarabia120335. S2CID 240264600.
  • Scotese, C. R.; McKerrow, W. S. (1990). "Revised world maps and introduction" (PDF). Geological Society, London, Memoirs. 12 (1): 1–21. doi:10.1144/gsl.mem.1990.012.01.01. S2CID 128779205. Retrieved 25 June 2016.
  • Şengör, A. M. C. (1984). "The Cimmeride orogenic system and the tectonics of Eurasia". Geological Society of America Special Papers. 195: 1–74. doi:10.1130/SPE195-p1. ISBN 9780813721958.
  • Şengör, A. M. C. (1987). "Tectonics of the Tethysides: orogenic collage development in a collisional setting". Annual Review of Earth and Planetary Sciences. 15: 213–244. Bibcode:1987AREPS..15..213C. doi:10.1146/annurev.ea.15.050187.001241.
  • Şengör, A. M. C.; Altıner, D.; Cin, A.; Ustaömer, T.; Hsü, K. J. (1988). "Origin and assembly of the Tethyside orogenic collage at the expense of Gondwana Land". Geological Society, London, Special Publications. 37 (1): 119–181. Bibcode:1988GSLSP..37..119S. doi:10.1144/gsl.sp.1988.037.01.09. S2CID 140718505. Retrieved 26 June 2016.
  • Şengör, A. M. C.; Yilmaz, Y. (1981). "Tethyan evolution of Turkey: a plate tectonic approach" (PDF). Tectonophysics. 75 (3): 181–241. Bibcode:1981Tectp..75..181S. doi:10.1016/0040-1951(81)90275-4. Retrieved 21 July 2016.
  • Stampfli, G. M. (2000). "Tethyan oceans" (PDF). Geological Society, London, Special Publications. 173 (1): 1–23. Bibcode:2000GSLSP.173....1S. doi:10.1144/gsl.sp.2000.173.01.01. S2CID 219202298. Retrieved 26 June 2016.
  • Stampfli, G. M.; Borel, G. D. (2002). (PDF). Earth and Planetary Science Letters. 196 (1): 17–33. Bibcode:2002E&PSL.196...17S. doi:10.1016/S0012-821X(01)00588-X. Archived from the original (PDF) on 2016-08-17. Retrieved 3 July 2016.
  • Stampfli, G. M.; Mosar, J.; Favre, P.; Pillevuit, A.; Vannay, J. C. (2001). "Permo-Mesozoic evolution of the western Tethys realm: The Neo-Tethys east Mediterranean basin connection". In Ziegler, P. A.; Cavalza, W.; Robertson, A. H. F.; Crasquin-Soleau, S. (eds.). Peri-Tethys Memoir 6: Peri-Tethyan Rift/Wrench Basins and Passive Margins. Mémoires du Muséum national d'histoire naturelle. Vol. 186. pp. 51–108. ISBN 2-85653-528-3. Retrieved 16 July 2016.
  • Stöcklin, J. (1974). "Possible Ancient Continental Margins in Iran". In Burk, C. A.; Drake, C. L. (eds.). The geology of continental margins. Springer Berlin Heidelberg. pp. 873–887. ISBN 9783662011416. Retrieved 26 June 2016.
  • Suess, E. (1893). "Are ocean depths permanent?". Natural Science: A Monthly Review of Scientific Progress. Vol. 2. London. pp. 180–187. Retrieved 18 October 2015.
  • Suess, E. (1901). "Der Antlitz der Erde" (in German). 3 (2). Wien F. Tempsky. Retrieved 26 June 2016. {{cite journal}}: Cite journal requires |journal= (help)
  • Zhao, J.; Huang, B.; Yan, Y.; Zhang, D. (2015). "Late Triassic paleomagnetic result from the Baoshan Terrane, West Yunnan of China: Implication for orientation of the East Paleotethys suture zone and timing of the Sibumasu-Indochina collision". Journal of Asian Earth Sciences. 111: 350–364. Bibcode:2015JAESc.111..350Z. doi:10.1016/j.jseaes.2015.06.033. Retrieved 23 July 2016.

May 06, 2023
cimmeria, continent, cimmeria, ancient, continent, rather, string, microcontinents, terranes, that, rifted, from, gondwana, southern, hemisphere, accreted, eurasia, northern, hemisphere, consisted, parts, present, turkey, iran, afghanistan, pakistan, tibet, ch. Cimmeria was an ancient continent or rather a string of microcontinents or terranes 3 that rifted from Gondwana in the Southern Hemisphere and was accreted to Eurasia in the Northern Hemisphere It consisted of parts of present day Turkey Iran Afghanistan Pakistan Tibet China Myanmar Thailand and Malaysia 4 5 Cimmeria rifted from the Gondwanan shores of the Paleo Tethys Ocean during the Early Permian 6 and as the Neo Tethys Ocean opened behind it during the Permian the Paleo Tethys closed in front of it 7 Because the different chunks of Cimmeria drifted northward at different rates a Meso Tethys Ocean formed between the different fragments during the Cisuralian 8 Cimmeria rifted off Gondwana from east to west from Australia to the eastern Mediterranean 9 It stretched across several latitudes and spanned a wide range of climatic zones 10 Tectonic history of CimmeriaCimmeria rifted off Gondwana s north eastern shores around 250 Ma 1 As Cimmeria migrated from Gondwana to Eurasia the Paleo Tethys closed and the Neo Tethys opened 2 After 150 million years Cimmeria collided with Eurasia and the Cimmerian orogeny closed the Paleo Tethys As the break up of Gondwana began in the south the opening of the Indian Ocean initiated the closure of the Neo Tethys 1 Contents 1 History of the concept 1 1 First concepts 1 2 Iranian microcontinent 1 3 Eurasian superterrane 2 Tectonic history 2 1 Turkey 2 2 Iran 2 3 Caucasus 2 4 Sibumasu 2 5 Lhasa 3 Economic importance 4 See also 5 References 5 1 Notes 5 2 SourcesHistory of the concept EditFirst concepts Edit A large ancient Mediterranean Sea was first proposed by Austrian palaeontologist Melchior Neumayr in 1883 11 Studying the distribution of Jurassic faunas he concluded that an equatorial ocean stretching from India to Central America must have separated a large continent in the northern hemisphere from one in the southern hemisphere Austrian geologist Eduard Suess named this Mesozoic ocean the Tethys a mythical ocean which separated a mythical continent Gondwanaland home of the tongue shaped flora from a boreal continent 12 German geophysicist Alfred Wegener in contrast developed a concept of a single global continent the supercontinent Pangea which in his view left no room for an equatorial ocean A wedge shaped east facing Tethys within Pangea was nevertheless proposed by Australian geologist Samuel Warren Carey in 1958 13 This ocean was later identified as a succession of oceans separated by north migrating terranes or continental blocks one of which was Cimmeria Iranian microcontinent Edit In 1974 after extensive field work in the Middle East Swiss geologist Jovan Stocklin identified the northern foot of the Alborz Range in northern Iran as the suture which in the Paleozoic was the northern shore of Gondwana and the remains of the Paleo Tethys Ocean Stocklin also noted that an early Mesozoic or late Paleozoic rift separated the Iranian Plate from the Arabian Plate and that another southern suture must be the remains of the Neo Tethys Ocean The opening of this later ocean Stocklin realized must have transformed Iran into a microcontinent Those observations made Stocklin the first to identify a small part of what would later be known as Cimmeria 14 Stocklin also noted that his proposal resembled the old concept of the world in which there were two continents Angaraland in the north and Gondwana in the south separated by an elongated ocean the Tethys Iran belonged to neither continent but was part of the realm of Tethys 14 Stocklin s southern suture was later confirmed by observations of the evolution of microflora in Iran which had a Gondwanan affinity during the Carboniferous but a Eurasian affinity during the Late Triassic Iran had clearly drifted from Gondwana to Laurasia 15 Eurasian superterrane Edit The Alpide belt is a system of sutures stretching across Eurasia within which the Cimmerian blocks are now located In the 1980s Turkish geologist Celal Sengor finally extended Stocklin s Iranian microcontinent further west to Turkey and further east to Tibet and the Far East 16 Sengor also reused the name introduced by Suess in 1901 the Kimmerisches Gebirge the Crimean or Cimmerian Mountains 15 17 18 In the mountain range that now stretches from the Alps to Indonesia Sengor identified using a simplified scheme two distinct but superimposed orogenic systems containing a large number of anastomosing sutures the older Cimmerides and the younger Alpides together forming what Sengor called the Tethysides super orogenic system These two orogenic systems are thus associated with two major periods of ocean closure the earlier northern and much larger Cimmerides and the later southern and smaller Alpides Cimmeria was the long continental archipelago that separated the two oceans before the Paleo Tethys closed 18 This realm of Tethys thus covers most of Eurasia and a large time span from north to south 18 Laurasia Permian to Cretaceous Palaeo Tethys Early Carboniferous to Middle Jurassic Cimmeria Triassic to Middle Jurassic Neo Tethys Permian or Triassic to Eocene locally still extant Gondwana Ordovician to JurassicThis simple scheme however partly obscures the complex nature of the Tethyan cycles and terms such as Eocimmerian and Neocimmerian is often used for Late Triassic and Late Jurassic events respectively 19 Furthermore a distinction is often made between two more recent Tethyan domains the Alpine Tethys and the Neo Tethys The Alpine Tethys the western domain in this scheme separated south western Europe from north western Africa and was connected to the Central Atlantic It is now completely closed and its suture encompasses the Maghrebids stretching from Gibraltar to Sicily as well as the Apennines and the Alps The Neo Tethys the eastern domain opened between Arabia and the Cimmerian terranes The East Mediterranean Basin and the Gulf of Oman are considered relics of the Neo Tethys which is thus still closing These two domains were connected east of Sicily until the end of the Jurassic 20 Tectonic history EditThis section needs expansion You can help by adding to it July 2016 In the Late Paleozoic when the Cimmerian blocks were still located on the northern margin of Gondwana they were far away from any active margins and orogenic belts but they had been affected by thermal subsidence since the Siluran opening of Paleo Tethys Carboniferous to Permian ophiolites along suture zones in Tibet and north eastern Iran indicate that the active margin of Paleo Tethys was located here 21 It was slab pull forces in the Paleo Tethys that detached Cimmeria from Gondwana and opened the Neo Tethys The mid ocean ridge in the Paleo Tethys subducted under Eurasia as evidenced by Permian MORB mid ocean ridge basalt in Iran Slab roll back in the Paleo Tethys opened a series of back arc basins along the Eurasian margin and resulted in the collapse of the Variscan cordillera As the Paleo Tethys subducted under the Eurasian southern margin back arc oceans formed from Austria to China Some of these back arcs closed during the Cimmerian orogeny e g the Karakaya Kure sequence of back arc oceans in Turkey others remained open e g the Meliata Maliac Pindos back arc oceans in the eastern Mediterranean leading to the formation of younger back arc oceans 9 Turkey Edit See also Geology of Turkey Geological map of Turkey Turkey is an assemblage of continental blocks that during the Permian were part of the northern margin of Gondwana During the Permian Triassic as the Paleo Tethys subducted under this margin in what is today northern Turkey a marginal sea opened and quickly filled with sediments today the basement of the Sakarya Composite Terrane in the Pontides During the Late Triassic the Neo Tethys began opening behind Cimmeria when the Eastern Mediterranean and its two eastern branches opened into the Bitlis Zagros ocean the southern branch of the Neo Tethys 22 During Early Jurassic Cimmeria began to disintegrate behind the Paleo Tethyan volcanic arc This opened the northern branch in the Neo Tethys the Intra Pontide Izmh citation needed Ankara and the Inner Tauride oceans The closure of the Paleo Tethys in the Middle Jurassic reduced the Cimmerian archipelago in Anatolia South of the Cimmerian blocks there were now two branches of the Neo Tethys a northern larger and more complex and a southern more reduced the Anatolide Tauride continent separated them the small Sakarya continent was located within the northern branch The Apulian continent was connected to the Anatolide Tauride continent 22 These Neo Tethyan branches reached their maximum width during the Early Cretaceous after which subduction under Eurasia gradually consumed them During the Middle Late Cretaceous this subduction opened a back arc basin the Western Black Sea Basin which stretched west into the Balkans north of the Rhodope Pontide island arc there 23 In the Cretaceous this basin pushed the Istanbul terrane near today s Istanbul southward in front of it from the Odesa Shelf in the north western Black Sea In the Eocene the terrane finally collided with Cimmeria thereby ending the extension in the western Black Sea Contemporaneously the East Black Sea Basin opened when the East Black Sea Block was rotated counter clockwise towards Caucasus 24 In the late Cretaceous northwards intra oceanic subduction within the Neotethys gave way to the obduction of ophiolitic nappes over the Arabian platform from Turkey to Oman region North of this subduction zone remnants of the Neotethys ocean started to subduct northwards and led to the collision of Tauride Block with the Arabian plate during post Oligocene times North of these systems the Tauride block collided with the southern margin of Eurasia by the end of the Cretaceous Convergence continued until the end of Oligocene The Arabian Eurasian collision in eastern Turkey during the Late Eocene closed the two basins 22 During the Paleogene Neo Tethyan oceanic crust attached to the African Plate subducted along the Crete and Cyprus trenches The Anatolide Tauride continent collided with the Pontide and Kirsehir blocks in the Late Paleocene Early Eocene This closed the Ankara Erzincan branches of the northern Neo Tethys During this closure slab roll back and break off in the Eocene resulted in inversion in the Pontides and widespread magmatism in northern Turkey Extension and upwelling followed resulting in melting of lithospheric material beneath the Pontides 25 In southern Turkey the northward subduction of the Neo tethys along the Bitlis Zagros subduction zone resulted in magmatism in the Maden Helete arc south eastern Turkey during the Late Cretaceous Eocene and back arc magmatism in the Taurides The Bitlis Zagros subduction zone finally closed in the Miocene and throughout the Oligocene Neogene and Quaternary volcanism became increasingly localised In the Late Oligocene slab roll back in the Hellenic Trench resulted in extension in the Aegean and western Turkey 25 Iran Edit See also Geology of Iran The subduction of western Neo Tethys under Eurasia resulted in extensive magmatism in what is now northern Iran In the Early Jurassic this magmatism had produced a slab pull force which contributed to the break up of Pangea and the initial opening of the Atlantic During the Late Jurassic Early Cretaceous the subduction of the Neo Tethys mid ocean ridge contributed to the break up of Gondwana including the detachment of the Argo Burma terrane from Australia 9 The Central East Iranian Microcontinent CEIM sutured with Eurasia in the Late Triassic during the regional Eocimmerian orogenic event in northern Iran but Iran is made of several continental blocks and the area must have seen a number of ocean closures in the Late Paleozoic and Early Mesozoic 26 Caucasus Edit The Greater and Lesser Caucasus has a complicated geological history involving the accretion of a series of terranes and microcontinents from the Late Precambrian to the Jurassic within the Tethyan framework These include the Greater Caucasian Black Sea Central Transcaucasian Baiburt Sevanian and Iran Afghanistan terranes and island arcs 27 In the Caucasus region remnants of the Paleo Tethys suture can be found in the Dzirula Massif which outcrops Early Jurassic sequences in central Georgia It consists of Early Cambrian oceanic rocks and the possible remnants of a magmatic arc their geometry suggests that suturing was followed by strike slip faulting Ophiolites also outcrop in the Khrami Massif in southern Georgia and another possible segment of the suture is present in the Svanetia region The suture is older east of the Caucasus northern Iran Turkmenistan but younger both west of the Caucasus and further east in Afghanistan and the northern Pamirs 28 Sibumasu Edit The easternmost part of Cimmeria the Sibumasu terrane remained attached to north western Australia until 295 290 Ma when it began to drift northward as supported by paleomagnetic and biogeographic data The Qiangtang terrane was located west of Sibumasu and contiguous with it Lower Permian layers in Sibumasu contain glacial marine diamictites and Gondwanan faunas and floras which then developed independently before Sibumasu docked with Cathaysia Sibumasu s rapid northern journey is especially evident in the development of brachiopods and fusulinids 29 The Baoshan terrane in western Yunnan China forms the northern part of Sibumasu It is separated from the Burma Block by the Gaoligong Suture Zone to the west and from the South China and Indochina continents in the east by the Chongshan Suture Zone and Changning Menglian Belt Like other parts of eastern Cimmeria it was highly deformed by the intra continental strike slip faulting that followed the India Asia collision 30 Paleomagnetic data indicate South China and Indochina moved from near Equator to 20 N from the Early Permian to Late Triassic Baoshan in contrast moved from 42 S in the Early Permian to 15 N in the Late Triassic These blocks and terranes occupied similar paleo latitudes during Late Triassic to Jurassic which indicates that they probably collided in the Late Triassic This is also supported by geological evidence 200 230 Ma granite in Lincang near the Changning Menglian suture indicate a continent continent collision occurred there in the Late Triassic pelagic sediments in the Changning Menglian Inthanon ophiolite belt between Sibumasu and Indochina ranges in age from Middle Devonian to Middle Triassic while in the Inthanon suture in contrast Middle to Late Triassic rocks are non pelagic with radiolarian cherts and turbidic clastics indicating the two blocks had at least approached each other by that time volcanic sequences from the Lancangjiang igneous zone indicate a post collisional setting had developed before the eruptions there around 210 Ma and the Sibumasu fauna developed from a non marine peri Gondwanan assemblage in the early Permian to an endemic Sibumasu fauna in the Middle Permian and to an Equatorial Cathaysian in the Late Permian 31 During the Early and Middle Palaeozoic Cimmeria was located at an Andean style active margin Glacial deposits and paleomagnetic data indicate that Qiangtang and Shan Thai Malaya were still located far south adjacent to Gondwana during the Carboniferous The equatorial fauna and flora of China indicate that it was separated from Gondwana during the Carboniferous 4 Lhasa Edit The Lhasa terrane has been interpreted as part of Cimmeria and if this is the case must have rifted from Gondwana together with Sibumasu and Qiantang The timing of Lhasa s northward drift is still controversial however and paleomagnetic data is extremely scarce Sedimentological and stratigraphical evidence for example suggest that it separated from Gondwana in the Late Triassic when Qiantang was already being accreted to Eurasia 32 This proposed Late Triassic rifting of Lhasa has also been documented along the north western shelf of Australia where the Western Burma and Woyla terranes eventually separated from Gondwana in the Late Jurassic 33 Today the Bangong suture separates the Lhasa terrane from the Qiangtang terrane Economic importance EditThis section does not cite any sources Please help improve this section by adding citations to reliable sources Unsourced material may be challenged and removed November 2016 Learn how and when to remove this template message The present remains of Cimmeria as a result of the massive uplifting of its continental crust are unusually rich in a number of rare chalcophile elements Apart from the Altiplano in Bolivia almost all the world s deposits of antimony as stibnite are found in Cimmeria with the major mines being in Turkey Yunnan and Thailand The major deposits of tin are also found in Malaysia and Thailand whilst Turkey also has major deposits of chromite ore See also EditAlpide belt Belt of Eurasian mountain ranges Cathaysia Late Paleozoic microcontinent Cimmerian Orogeny Panjal Traps Permian Triassic extinction event Earth s most severe extinction event South China Craton ancient continent that contained today s South and Southeast China Indochina and parts of Southeast AsiaPages displaying wikidata descriptions as a fallbackReferences EditNotes Edit a b Reconstruction from Dezes 1999 p 16 Reconstruction from Stampfli amp Borel 2002 p 27 Cheng Jian Bo Li Ya Lin Li Shuai Xiao Si Qi Bi Wen Jun Zou Yu December 2022 Reconstruction of the South Qiangtang Zhongba Tethyan Himalaya continental margin system along the northern Indian Plate Insights from the paleobiogeography of the Zhongba microterrane Journal of Asian Earth Sciences 240 105376 Bibcode 2022JAESc 24005376C doi 10 1016 j jseaes 2022 105376 S2CID 252703613 Retrieved 2 April 2023 a b Scotese amp McKerrow 1990 pp 4 5 17 Ruban Al Husseini amp Iwasaki 2007 pp 37 40 43 Wang X D Ueno K Mizuno Y Sugiyama T 15 June 2001 Late Paleozoic faunal climatic and geographic changes in the Baoshan block as a Gondwana derived continental fragment in southwest China Palaeogeography Palaeoclimatology Palaeoecology 170 3 4 197 218 Bibcode 2001PPP 170 197W doi 10 1016 S0031 0182 01 00228 0 Retrieved 17 October 2022 Golonka 2007 p 182 Xu Hai Peng Zhang Yi chun Yuan Dong xun Shen Shu Zhong 1 September 2022 Quantitative palaeobiogeography of the Kungurian Roadian brachiopod faunas in the Tethys Implications of allometric drifting of Cimmerian blocks and opening of the Meso Tethys Ocean Palaeogeography Palaeoclimatology Palaeoecology 601 111078 Bibcode 2022PPP 601k1078X doi 10 1016 j palaeo 2022 111078 a b c Stampfli amp Borel 2002 pp 24 28 Metcalfe 2002 p 556 Neumayr 1883 Suess 1893 Suess 1901 Hsu amp Bernoulli 1978 Paleotethys pp 943 944 and references therein including Carey 1958 a b Stocklin 1974 Introduction p 873 a b Stampfli 2000 Some definitions pp 1 2 Sengor 1984 Sengor 1987 Suess 1901 p 22 a b c Sengor et al 1988 pp 119 120 123 See for example Frizon de Lamotte et al 2011 The Zagros Domain and Its Arabian Foreland p 4 Frizon de Lamotte et al 2011 Introduction pp 1 4 Stampfli et al 2001 Initial Conditions pp 57 58 a b c Sengor amp Yilmaz 1981 Abstract Hippolyte J C Muller C Kaymakci N Sangu E 2010 Dating of the Black Sea Basin new nannoplankton ages from its inverted margin in the Central Pontides Turkey PDF Geological Society London Special Publications 340 1 113 136 Bibcode 2010GSLSP 340 113H doi 10 1144 SP340 7 hdl 11511 48215 S2CID 128968783 Okay Sengor amp Gorur 1994 Abstract Fig 3 p 269 a b Richards 2015 Turkey pp 329 330 Buchs et al 2013 Introduction pp 267 268 Gamkrelidze amp Shengelia 2007 Introduction p 57 Sengor et al 1988 pp 139 140 Metcalfe 2002 p 556 Position of the Sibumasu Terrane pp 562 563 Position of the Qiangtang Terrane p 563 Zhao et al 2015 Geological setting and sampling p 3 Zhao et al 2015 The closure of the East Paleotethys Ocean pp 10 11 13 Metcalfe 2002 Position of the Lhasa Terrane p 563 Metcalfe 1996 Late Triassic to Late Jurassic rifting pp 104 105 Sources Edit Buchs D M Bagheri S Martin L Hermann J Arculus R 2013 Paleozoic to Triassic ocean opening and closure preserved in Central Iran Constraints from the geochemistry of meta igneous rocks of the Anarak area Lithos 172 267 287 Bibcode 2013Litho 172 267B doi 10 1016 j lithos 2013 02 009 Retrieved 8 July 2016 Carey S W 1958 The tectonic approach to continental drift Continental Drift A Symposium Geology Dept Univ of Tasmania Dezes P 1999 Tectonic and metamorphic evolution of the central Himalayan domain in southeast Zanskar Kashmir India PDF Thesis Section des Sciences de la Terre Universite de Lausanne Retrieved 3 July 2016 Frizon de Lamotte D Raulin C Mouchot N Wrobel Daveau J C Blanpied C Ringenbach J C 2011 The southernmost margin of the Tethys realm during the Mesozoic and Cenozoic Initial geometry and timing of the inversion processes Tectonics 30 3 n a Bibcode 2011Tecto 30 3002F doi 10 1029 2010TC002691 S2CID 129242341 Retrieved 16 July 2016 Golonka J 2007 Phanerozoic paleoenvironment and paleolithofacies maps late Paleozoic Geologia 33 2 145 209 Retrieved 26 June 2016 Gamkrelidze I P Shengelia D M 2007 Pre Alpine geodynamics of the Caucasus suprasubduction regional metamorphism and granitoid magmatism PDF Bull Georg Natl Acad Sci 175 57 65 Retrieved 8 July 2016 Hsu K J Bernoulli D 1978 Genesis of the Tethys and the Mediterranean PDF US Government Printing Office Retrieved 5 July 2016 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Metcalfe I 1996 Pre Cretaceous evolution of SE Asian terranes PDF Geological Society London Special Publications 106 1 97 122 Bibcode 1996GSLSP 106 97M doi 10 1144 gsl sp 1996 106 01 09 S2CID 128478812 Retrieved 17 July 2016 dead link Metcalfe I 2002 Permian tectonic framework and palaeogeography of SE Asia Journal of Asian Earth Sciences 20 6 551 566 Bibcode 2002JAESc 20 551M doi 10 1016 s1367 9120 02 00022 6 Retrieved 7 July 2016 Neumayr M 1883 Uber klimatische Zonen wahrend der Jura und Kreidezeit Denkschriften der Akademie der Wissenschaften in Wien Mathematisch Naturwissenschaftliche Classe in German Vol 47 Wien Kaiserlich Koniglichen Hof und Staatsdruckerei pp 277 310 OCLC 604278105 Retrieved 5 July 2016 Okay A I Sengor A M C Gorur N 1994 Kinematic history of the opening of the Black Sea and its effect on the surrounding regions PDF Geology 22 3 267 270 Bibcode 1994Geo 22 267O doi 10 1130 0091 7613 1994 022 lt 0267 khotoo gt 2 3 co 2 Retrieved 20 July 2016 Richards J P 2015 Tectonic magmatic and metallogenic evolution of the Tethyan orogen From subduction to collision Ore Geology Reviews 70 323 345 Bibcode 2015OGRv 70 323R doi 10 1016 j oregeorev 2014 11 009 Retrieved 18 July 2016 Ruban D A Al Husseini M I Iwasaki Y 2007 Review of Middle East Paleozoic plate tectonics GeoArabia 12 3 35 56 doi 10 2113 geoarabia120335 S2CID 240264600 Scotese C R McKerrow W S 1990 Revised world maps and introduction PDF Geological Society London Memoirs 12 1 1 21 doi 10 1144 gsl mem 1990 012 01 01 S2CID 128779205 Retrieved 25 June 2016 Sengor A M C 1984 The Cimmeride orogenic system and the tectonics of Eurasia Geological Society of America Special Papers 195 1 74 doi 10 1130 SPE195 p1 ISBN 9780813721958 Sengor A M C 1987 Tectonics of the Tethysides orogenic collage development in a collisional setting Annual Review of Earth and Planetary Sciences 15 213 244 Bibcode 1987AREPS 15 213C doi 10 1146 annurev ea 15 050187 001241 Sengor A M C Altiner D Cin A Ustaomer T Hsu K J 1988 Origin and assembly of the Tethyside orogenic collage at the expense of Gondwana Land Geological Society London Special Publications 37 1 119 181 Bibcode 1988GSLSP 37 119S doi 10 1144 gsl sp 1988 037 01 09 S2CID 140718505 Retrieved 26 June 2016 Sengor A M C Yilmaz Y 1981 Tethyan evolution of Turkey a plate tectonic approach PDF Tectonophysics 75 3 181 241 Bibcode 1981Tectp 75 181S doi 10 1016 0040 1951 81 90275 4 Retrieved 21 July 2016 Stampfli G M 2000 Tethyan oceans PDF Geological Society London Special Publications 173 1 1 23 Bibcode 2000GSLSP 173 1S doi 10 1144 gsl sp 2000 173 01 01 S2CID 219202298 Retrieved 26 June 2016 Stampfli G M Borel G D 2002 A plate tectonic model for the Paleozoic and Mesozoic constrained by dynamic plate boundaries and restored synthetic oceanic isochrons PDF Earth and Planetary Science Letters 196 1 17 33 Bibcode 2002E amp PSL 196 17S doi 10 1016 S0012 821X 01 00588 X Archived from the original PDF on 2016 08 17 Retrieved 3 July 2016 Stampfli G M Mosar J Favre P Pillevuit A Vannay J C 2001 Permo Mesozoic evolution of the western Tethys realm The Neo Tethys east Mediterranean basin connection In Ziegler P A Cavalza W Robertson A H F Crasquin Soleau S eds Peri Tethys Memoir 6 Peri Tethyan Rift Wrench Basins and Passive Margins Memoires du Museum national d histoire naturelle Vol 186 pp 51 108 ISBN 2 85653 528 3 Retrieved 16 July 2016 Stocklin J 1974 Possible Ancient Continental Margins in Iran In Burk C A Drake C L eds The geology of continental margins Springer Berlin Heidelberg pp 873 887 ISBN 9783662011416 Retrieved 26 June 2016 Suess E 1893 Are ocean depths permanent Natural Science A Monthly Review of Scientific Progress Vol 2 London pp 180 187 Retrieved 18 October 2015 Suess E 1901 Der Antlitz der Erde in German 3 2 Wien F Tempsky Retrieved 26 June 2016 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Zhao J Huang B Yan Y Zhang D 2015 Late Triassic paleomagnetic result from the Baoshan Terrane West Yunnan of China Implication for orientation of the East Paleotethys suture zone and timing of the Sibumasu Indochina collision Journal of Asian Earth Sciences 111 350 364 Bibcode 2015JAESc 111 350Z doi 10 1016 j jseaes 2015 06 033 Retrieved 23 July 2016 Retrieved from https en wikipedia org w index php title Cimmeria continent amp oldid 1148792498, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.