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Rodinia

January 10, 2024

Not to be confused with Rhodinia, a genus of moth.
For the genus of metalmark butterflies, see Rodinia (butterfly).

Rodinia (from the Russian родина, rodina, meaning "motherland, birthplace"[1][2][3]) was a Mesoproterozoic and Neoproterozoic supercontinent that assembled 1.26–0.90 billion years ago[4] and broke up 750–633 million years ago.[5]Valentine & Moores 1970 were probably the first to recognise a Precambrian supercontinent, which they named 'Pangaea I'.[5] It was renamed 'Rodinia' by McMenamin & McMenamin 1990 who also were the first to produce a reconstruction and propose a temporal framework for the supercontinent.[6]

Rodinia formed at c. 1.23 Ga by accretion and collision of fragments produced by breakup of an older supercontinent, Columbia, assembled by global-scale 2.0–1.8 Ga collisional events.[7]

Rodinia broke up in the Neoproterozoic with its continental fragments reassembled to form Pannotia 633–573 million years ago. In contrast with Pannotia, little is known yet about the exact configuration and geodynamic history of Rodinia. Paleomagnetic evidence provides some clues to the paleolatitude of individual pieces of the Earth's crust, but not to their longitude, which geologists have pieced together by comparing similar geologic features, often now widely dispersed.

The extreme cooling of the global climate around 717–635 million years ago (the so-called Snowball Earth of the Cryogenian period) and the rapid evolution of primitive life during the subsequent Ediacaran and Cambrian periods are thought to have been triggered by the breaking up of Rodinia or to a slowing down of tectonic processes.[8]

Geodynamics edit

Paleogeographic reconstructions edit

 
Rodinia at 900 Ma. "Consensus" reconstruction of Li et al. 2008.

The idea that a supercontinent existed in the early Neoproterozoic arose in the 1970s, when geologists determined that orogens of this age exist on virtually all cratons.[9][failed verification] Examples are the Grenville orogeny in North America and the Dalslandian orogeny in Europe.

Since then, many alternative reconstructions have been proposed for the configuration of the cratons in this supercontinent. Most of these reconstructions are based on the correlation of the orogens on different cratons.[10] Though the configuration of the core cratons in Rodinia is now reasonably well known, recent reconstructions still differ in many details. Geologists try to decrease the uncertainties by collecting geological and paleomagnetical data.

Most reconstructions show Rodinia's core formed by the North American craton (the later paleocontinent of Laurentia), surrounded in the southeast with the East European craton (the later paleocontinent of Baltica), the Amazonian craton ("Amazonia") and the West African craton; in the south with the Río de la Plata and São Francisco cratons; in the southwest with the Congo and Kalahari cratons; and in the northeast with Australia, India and eastern Antarctica. The positions of Siberia and North and South China north of the North American craton differ strongly depending on the reconstruction:[11][12][13]

  • SWEAT-Configuration (Southwest US-East Antarctica craton): Antarctica is on the Southwest of Laurentia and Australia is at the North of Antarctica.[14]
  • AUSWUS-Configuration (Australia-western US): Australia is at the West of Laurentia.
  • AUSMEX-Configuration (Australia-Mexico): Australia is at the location of current day Mexico relative to Laurentia.
  • The "Missing-link" model by Li et al. 2008 which has South China between Australia and the west coast of Laurentia.[15] A revised "Missing-link" model is proposed in which Tarim Block serves as an extended or alternative missing-link between Australia and Laurentia.[16]
  • Siberia attached to the western US (via the Belt Supergroup), as in Sears & Price 2000.[17]
  • Rodinia of Scotese.[18]

Little is known about the paleogeography before the formation of Rodinia. Paleomagnetic and geologic data are only definite enough to form reconstructions from the breakup of Rodinia[17] onwards. Rodinia is considered to have formed between 1.3 and 1.23 billion years ago and broke up again before 750 million years ago.[19] Rodinia was surrounded by the superocean geologists call Mirovia (from Russian мировой, mirovoy, meaning "global").

According to J.D.A. Piper, Rodinia is one of two models for the configuration and history of the continental crust in the latter part of Precambrian times. The other is Paleopangea, Piper's own concept.[20] Piper proposes an alternative hypothesis for this era and the previous ones. This idea rejects that Rodinia ever existed as a transient supercontinent subject to progressive break-up in the latter part of Proterozoic times and instead that this time and earlier times were dominated by a single, persistent "Paleopangaea" supercontinent. As evidence, he suggests an observation that the palaeomagnetic poles from the continental crust assigned to this time conform to a single path between 825 and 633 million years ago and latterly to a near-static position between 750 and 633 million years.[8] This latter solution predicts that break-up was confined to the Ediacaran period and produced the dramatic environmental changes that characterised the transition between Precambrian and Phanerozoic times. However, this theory has been widely criticized, as incorrect applications of paleomagnetic data have been pointed out.[21]

Breakup edit

In 2009 UNESCO's IGCP project 440, named 'Rodinia Assembly and Breakup', concluded that Rodinia broke up in four stages between 825 and 550 Ma:[22]

  • The breakup was initiated by a superplume around 825–800 Ma whose influence—such as crustal arching, intense bimodal magmatism, and accumulation of thick rift-type sedimentary successions—have been recorded in South Australia, South China, Tarim, Kalahari, India, and the Arabian-Nubian Craton.
  • Rifting progressed in the same cratons 800–750 Ma and spread into Laurentia and perhaps Siberia. India (including Madagascar) and the Congo–São Francisco Craton were either detached from Rodinia during this period or simply never were part of the supercontinent.
  • As the central part of Rodinia reached the Equator around 750–700 Ma, a new pulse of magmatism and rifting continued the disassembly in western Kalahari, West Australia, South China, Tarim, and most margins of Laurentia.
  • 650–550 Ma several events coincided: the opening of the Iapetus Ocean; the closure of the Braziliano, Adamastor, and Mozambique oceans; and the Pan-African orogeny. The result was the formation of Gondwana.

The Rodinia hypothesis assumes that rifting did not start everywhere simultaneously. Extensive lava flows and volcanic eruptions of Neoproterozoic age are found on most continents, evidence for large scale rifting about 750 million years ago.[1] As early as 850 and 800 million years ago,[19] a rift developed between the continental masses of present-day Australia, East Antarctica, India and the Congo and Kalahari cratons on one side and later Laurentia, Baltica, Amazonia and the West African and Rio de la Plata cratons on the other.[23] This rift developed into the Adamastor Ocean during the Ediacaran.

Around 550 million years ago, near the boundary between the Ediacaran and Cambrian, the first group of cratons eventually fused again with Amazonia, West Africa and the Rio de la Plata cratons.[24] This tectonic phase is called the Pan-African orogeny. It created a configuration of continents that would remain stable for hundreds of millions of years in the form of the continent Gondwana.

In a separate rifting event about 610 million years ago (halfway into the Ediacaran period), the Iapetus Ocean formed. The eastern part of this ocean formed between Baltica and Laurentia, the western part between Amazonia and Laurentia. Because the exact moments of this separation and the partially contemporaneous Pan-African orogeny are hard to correlate, it might be that all continental mass was again joined in one supercontinent between roughly 600 and 550 million years ago. This hypothetical supercontinent is called Pannotia.

Influence on paleoclimate and life edit

Unlike later supercontinents, Rodinia would have been entirely barren. Rodinia existed before complex life colonized dry land. Based on sedimentary rock analysis Rodinia's formation happened when the ozone layer was not as extensive as it is today. Ultraviolet light discouraged organisms from inhabiting its interior. Nevertheless, its existence did significantly influence the marine life of its time.

In the Cryogenian period the Earth experienced large glaciations, and temperatures were at least as cool as today. Substantial areas of Rodinia may have been covered by glaciers or the southern polar ice cap.

Low temperatures may have been exaggerated during the early stages of continental rifting. Geothermal heating peaks in crust about to be rifted; and since warmer rocks are less dense, the crustal rocks rise up relative to their surroundings. This rising creates areas of higher altitude, where the air is cooler and ice is less likely to melt with changes in season, and it may explain the evidence of abundant glaciation in the Ediacaran period.[1]

The eventual rifting of the continents created new oceans and seafloor spreading, which produces warmer, less dense oceanic lithosphere. Due to its lower density, hot oceanic lithosphere will not lie as deep as old, cool oceanic lithosphere. In periods with relatively large areas of new lithosphere, the ocean floors come up, causing the eustatic sea level to rise. The result was a greater number of shallower seas.

The increased evaporation from the larger water area of the oceans may have increased rainfall, which, in turn, increased the weathering of exposed rock. By inputting data on the ratio of stable isotopes 18O:16O[failed verification] into computer models, it has been shown that, in conjunction with quick weathering of volcanic rock, this increased rainfall may have reduced greenhouse gas levels to below the threshold required to trigger the period of extreme glaciation known as Snowball Earth.[25]

Increased volcanic activity also introduced into the marine environment biologically active nutrients, which may have played an important role in the development of the earliest animals.

See also edit

References edit

Citations edit

  1. ^ a b c McMenamin & McMenamin 1990, chapter: The Rifting of Rodinia
  2. ^ Redfern 2001, p. 335
  3. ^ Taube, Aleksandr M., R. S. Daglish (1993) 'Russko-angliiskii Slovar' =: Russian-English Dictionary. Moscow: Russkii iazyk ISBN 5-200-01883-8
  4. ^ Kee, Weon-Seo; Kim, Sung Won; Kwon, Sanghoon; Santosh, M.; Ko, Kyoungtae; Jeong, Youn-Joong (1 December 2019). "Early Neoproterozoic (ca. 913–895 Ma) arc magmatism along the central–western Korean Peninsula: Implications for the amalgamation of Rodinia supercontinent". Precambrian Research. 335. doi:10.1016/j.precamres.2019.105498. S2CID 210298156. Retrieved 9 November 2022.
  5. ^ a b Li et al. 2008
  6. ^ Meert 2012, Supercontinents in Earth history, p. 998
  7. ^ Zhao et al. 2002; Zhao et al. 2004
  8. ^ a b Piper 2013
  9. ^ Dewey & Burke 1973; the name 'Rodinia' was first used in McMenamin & McMenamin 1990
  10. ^ See for example the correlation between the North American Grenville and European Dalslandian orogenies in Ziegler 1990, p. 14; for the correlation between the Australian Musgrave orogeny and the Grenville orogeny see Wingate, Pisarevsky & Evans 2002, Implications for Rodinia reconstructions, pp. 124–126; fig. 5, p. 127
  11. ^ For a comparison of the SWEAT, AUSWUS, AUSMEX, and Missing-link reconstructions see Li et al. 2008, Fig. 2, p. 182. For a comparison between the "consensus" Rodinia of Li et al. 2008 and the original proposal of McMenamin & McMenamin 1990 see Nance, Murphy & Santosh 2014, Fig. 11, p. 9.
  12. ^ Examples of reconstructions can be found in Stanley 1999, pp. 336–337; Weil et al. 1998, Fig. 6, p. 21; Torsvik 2003, Fig. 'Rodinia old and new', p. 1380; Dalziel 1997, Fig. 11, p. 31; Scotese 2009, Fig. 1, p. 69
  13. ^ Wang, Chong; Peng, Peng; Wang, Xinping; Yang, Shuyan (October 2016). "Nature of three Proterozoic (1680 Ma, 1230 Ma and 775 Ma) mafic dyke swarms in North China: Implications for tectonic evolution and paleogeographic reconstruction". Precambrian Research. 285: 109–126. Bibcode:2016PreR..285..109W. doi:10.1016/j.precamres.2016.09.015. Retrieved 17 December 2022.
  14. ^ Moores 1991; Goodge et al. 2008
  15. ^ Li et al. 2008, Fig. 4, p. 188; fig. 8, p. 198
  16. ^ Wen, Bin; Evans, David A. D.; Li, Yong-Xiang (2017-01-15). "Neoproterozoic paleogeography of the Tarim Block: An extended or alternative "missing-link" model for Rodinia?". Earth and Planetary Science Letters. 458: 92–106. Bibcode:2017E&PSL.458...92W. doi:10.1016/j.epsl.2016.10.030.
  17. ^ a b "Other Reconstructions for Rodinia based on sources for Mojavia". Department of Geological Sciences, University of Colorado Boulder. May 2002. Retrieved 20 September 2010.
  18. ^ Scotese 2009; Torsvik, Gaina & Redfield 2008
  19. ^ a b Torsvik 2003, p. 1380
  20. ^ Piper 2010
  21. ^ Z.X, Li (October 2009). "How not to build a supercontinent: A reply to J.D.A. Piper". Precambrian Research. 174 (1–2): 208–214. Bibcode:2009PreR..174..208L. doi:10.1016/j.precamres.2009.06.007.
  22. ^ Bogdanova, Pisarevsky & Li 2009, Breakup of Rodinia (825–700 Ma), pp. 266–267
  23. ^ Torsvik 2003, Fig. 'Rodinia old and new', p. 1380
  24. ^ See for example reconstructions in Pisarevsky et al. 2008, Fig. 4, p. 19
  25. ^ Donnadieu et al. 2004[page needed]

General bibliography edit

  • Bogdanova, S. V.; Pisarevsky, S. A.; Li, Z. X. (2009). "Assembly and Breakup of Rodinia (Some Results of IGCP Project 440)". Stratigraphy and Geological Correlation. 17 (3): 259–274. Bibcode:2009SGC....17..259B. doi:10.1134/S0869593809030022. ISSN 0869-5938. S2CID 129254610. Retrieved 7 February 2016.
  • Dalziel, I. W. (1997). "Neoproterozoic-Paleozoic geography and tectonics: Review, hypothesis, environmental speculation". Geological Society of America Bulletin. 109 (1): 16–42. Bibcode:1997GSAB..109...16D. doi:10.1130/0016-7606(1997)109<0016:ONPGAT>2.3.CO;2. S2CID 129800903.
  • Dewey, J. F.; Burke, K. C. (1973). "Tibetan, Variscan, and Precambrian basement reactivation: products of continental collision". Journal of Geology. 81 (6): 683–692. Bibcode:1973JG.....81..683D. doi:10.1086/627920. JSTOR 30058995. S2CID 128770759.
  • Donnadieu, Y.; Goddéris, Y.; Ramstein, G.; Nédélec, A.; Meert, J. G. (2004). "A 'snowball Earth' climate triggered by continental break-up through changes in runoff". Nature. 428 (6980): 303–306. Bibcode:2004Natur.428..303D. doi:10.1038/nature02408. PMID 15029192. S2CID 4393545. Retrieved 29 January 2016.
  • Goodge, J. W.; Vervoort, J. D.; Fanning, C. M.; Brecke, D. M.; Farmer, G. L.; Williams, I. S.; Myrow, P. M.; DePaolo, D. J. (2008). "A positive test of East Antarctica–Laurentia juxtaposition within the Rodinia supercontinent" (PDF). Science. 321 (5886): 235–240. Bibcode:2008Sci...321..235G. doi:10.1126/science.1159189. ISSN 0036-8075. PMID 18621666. S2CID 11799613. Retrieved 4 February 2016.
  • Li, Z. X.; Bogdanova, S. V.; Collins, A. S.; Davidson, A.; De Waele, B.; Ernst, R. E.; Fitzsimons, I. C. W.; Fuck, R. A.; Gladkochub, D. P.; Jacobs, J.; Karlstrom, K. E.; Lul, S.; Natapov, L. M.; Pease, V.; Pisarevsky, S. A.; Thrane, K.; Vernikovsky, V. (2008). "Assembly, configuration, and break-up history of Rodinia: A synthesis" (PDF). Precambrian Research. 160 (1–2): 179–210. Bibcode:2008PreR..160..179L. doi:10.1016/j.precamres.2007.04.021. Retrieved 6 February 2016.
  • Loewy, S. L.; Dalziel, I. W. D.; Pisarevsky, S.; Connelly, J. N.; Tait, J.; Hanson, R. E.; Bullen, D. (2011). "Coats Land crustal block, East Antarctica: A tectonic tracer for Laurentia?". Geology. 39 (9): 859–862. Bibcode:2011Geo....39..859L. doi:10.1130/G32029.1. Retrieved 24 January 2016.
  • McMenamin, M. A.; McMenamin, D. L. (1990). The emergence of animals: the Cambrian breakthrough. Columbia University Press. ISBN 978-0-231-06647-1.
  • Meert, J.G. (2012). "What's in a name? The Columbia (Paleopangaea/Nuna) supercontinent" (PDF). Gondwana Research. 21 (4): 987–993. Bibcode:2012GondR..21..987M. doi:10.1016/j.gr.2011.12.002. Retrieved 6 February 2016.
  • Meert, J.G.; Torsvik, T.H. (2003). (PDF). Tectonophysics. 375 (1–4): 261–288. Bibcode:2003Tectp.375..261M. doi:10.1016/S0040-1951(03)00342-1. Archived from the original (PDF) on 2011-07-23.
  • Moores, E. M. (1991). "Southwest US-East Antarctic (SWEAT) connection: a hypothesis". Geology. 19 (5): 425–428. Bibcode:1991Geo....19..425M. doi:10.1130/0091-7613(1991)019<0425:SUSEAS>2.3.CO;2.
  • Nance, R. D.; Murphy, J. B.; Santosh, M. (2014). "The supercontinent cycle: a retrospective essay". Gondwana Research. 25 (1): 4–29. Bibcode:2014GondR..25....4N. doi:10.1016/j.gr.2012.12.026. Retrieved 6 February 2016.
  • Piper, J. D. A. (2010). "Palaeopangaea in Meso-Neoproterozoic times: The palaeomagnetic evidence and implications to continental integrity, supercontinent form and Eocambrian break-up". Journal of Geodynamics. 50 (3): 191–223. Bibcode:2010JGeo...50..191P. doi:10.1016/j.jog.2010.04.004. Retrieved 24 January 2016.
  • Piper, J. D. A. (2013). "A planetary perspective on Earth evolution: lid tectonics before plate tectonics". Tectonophysics. 589: 44–56. Bibcode:2013Tectp.589...44P. doi:10.1016/j.tecto.2012.12.042. Retrieved 1 February 2016.
  • Pisarevsky, S. A.; Murphy, J. B.; Cawood, P. A.; Collins, A. S. (2008). "Late Neoproterozoic and Early Cambrian palaeogeography: models and problems". Geological Society of London, Special Publications. 294 (1): 9–31. Bibcode:2008GSLSP.294....9P. doi:10.1144/SP294.2. S2CID 128498460. Retrieved 6 February 2016.
  • Redfern, R. (2001). Origins: The Evolution of Continents, Oceans and Life. University of Oklahoma Press. ISBN 978-0-8061-3359-1. Retrieved 6 February 2016.
  • Scotese, C. R. (2009). "Late Proterozoic plate tectonics and palaeogeography: a tale of two supercontinents, Rodinia and Pannotia". Geological Society of London, Special Publications. 326 (1): 67–83. Bibcode:2009GSLSP.326...67S. doi:10.1144/SP326.4. S2CID 128845353. Retrieved 29 November 2015.
  • http://www.scotese.com/Rodinia3.htm
  • Sears, J. W.; Price, R. A. (2000). "New look at the Siberian connection: No SWEAT". Geology. 28 (5): 423–426. Bibcode:2000Geo....28..423S. doi:10.1130/0091-7613(2000)28<423:NLATSC>2.0.CO;2. ISSN 0091-7613.
  • Stanley, S. M. (1999). Earth System History. W. H. Freeman & Co. ISBN 978-0-7167-2882-5.
  • Torsvik, T. H. (2003). "The Rodinia Jigsaw Puzzle" (PDF). Science. 300 (5624): 1379–1381. doi:10.1126/science.1083469. PMID 12775828. S2CID 129275224. Retrieved 24 January 2016.
  • Torsvik, T. H.; Gaina, C.; Redfield, T. F. (2008). (PDF). In Cooper, A. K.; Barrett, P. J.; Stagg, H.; Storey, B.; Stump, E.; Wise, W. (eds.). Antarctica: A Keystone in a Changing World. Proceedings of the 10th International Symposium on Antarctic Earth Sciences. Washington, DC: The National Academies Press. pp. 125–140. doi:10.3133/of2007-1047.kp11 (inactive 1 August 2023). Archived from the original (PDF) on 23 July 2011. Retrieved 30 January 2016.{{cite conference}}: CS1 maint: DOI inactive as of August 2023 (link)
  • Valentine, J. W.; Moores, E. M. (1970). "Plate-tectonic Regulation of Faunal Diversity and Sea Level: a Model". Nature. 228 (5272): 657–659. Bibcode:1970Natur.228..657V. doi:10.1038/228657a0. PMID 16058645. S2CID 4220816.
  • Weil, A. B.; Van der Voo, R.; Mac Niocaill, C.; Meert, J. G. (1998). "The Proterozoic supercontinent Rodinia: paleomagnetically derived reconstructions for 1100 to 800 Ma". Earth and Planetary Science Letters. 154 (1): 13–24. Bibcode:1998E&PSL.154...13W. doi:10.1016/S0012-821X(97)00127-1. Retrieved 6 February 2016.
  • Wingate, M. T. D.; Pisarevsky, S. A.; Evans, D. A. D. (2002). "Rodinia connections between Australia and Laurentia: no SWEAT, no AUSWUS?" (PDF). Terra Nova. 14 (2): 121–128. Bibcode:2002TeNov..14..121W. doi:10.1046/j.1365-3121.2002.00401.x. Retrieved 1 February 2016.
  • Ziegler, P. A. (1990). Geological Atlas of Western and Central Europe (2nd ed.). Shell Internationale Petroleum Maatschappij BV. ISBN 978-90-6644-125-5.
  • Zhao, G.; Cawood, P. A.; Wilde, S. A.; Sun, M. (2002). "Review of global 2.1–1.8 Ga orogens: implications for a pre-Rodinia supercontinent". Earth-Science Reviews. 59 (1): 125–162. Bibcode:2002ESRv...59..125Z. doi:10.1016/S0012-8252(02)00073-9. Retrieved 3 February 2016.
  • Zhao, G.; Sun, M.; Wilde, S. A.; Li, S. (2004). "A Paleo-Mesoproterozoic supercontinent: assembly, growth and breakup". Earth-Science Reviews. 67 (1): 91–123. Bibcode:2004ESRv...67...91Z. doi:10.1016/j.earscirev.2004.02.003. Retrieved 3 February 2016.

External links edit

 
Look up Rodinia in Wiktionary, the free dictionary.
  • Scotese Animation: Breakup of Rodinia & Formation of Pacific Ocean
  • "Dance of the Giant Continents: Washington's Earliest History"
  • mapping Proterozoic supercontinents, including Rodinia
  • Paleomap Project: Plate Tectonic Animations (java)

January 10, 2024
rodinia, confused, with, rhodinia, genus, moth, genus, metalmark, butterflies, butterfly, from, russian, родина, rodina, meaning, motherland, birthplace, mesoproterozoic, neoproterozoic, supercontinent, that, assembled, billion, years, broke, million, years, v. Not to be confused with Rhodinia a genus of moth For the genus of metalmark butterflies see Rodinia butterfly Rodinia from the Russian rodina rodina meaning motherland birthplace 1 2 3 was a Mesoproterozoic and Neoproterozoic supercontinent that assembled 1 26 0 90 billion years ago 4 and broke up 750 633 million years ago 5 Valentine amp Moores 1970 were probably the first to recognise a Precambrian supercontinent which they named Pangaea I 5 It was renamed Rodinia by McMenamin amp McMenamin 1990 who also were the first to produce a reconstruction and propose a temporal framework for the supercontinent 6 Rodinia formed at c 1 23 Ga by accretion and collision of fragments produced by breakup of an older supercontinent Columbia assembled by global scale 2 0 1 8 Ga collisional events 7 Rodinia broke up in the Neoproterozoic with its continental fragments reassembled to form Pannotia 633 573 million years ago In contrast with Pannotia little is known yet about the exact configuration and geodynamic history of Rodinia Paleomagnetic evidence provides some clues to the paleolatitude of individual pieces of the Earth s crust but not to their longitude which geologists have pieced together by comparing similar geologic features often now widely dispersed The extreme cooling of the global climate around 717 635 million years ago the so called Snowball Earth of the Cryogenian period and the rapid evolution of primitive life during the subsequent Ediacaran and Cambrian periods are thought to have been triggered by the breaking up of Rodinia or to a slowing down of tectonic processes 8 Contents 1 Geodynamics 1 1 Paleogeographic reconstructions 1 2 Breakup 2 Influence on paleoclimate and life 3 See also 4 References 4 1 Citations 4 2 General bibliography 5 External linksGeodynamics editPaleogeographic reconstructions edit nbsp Rodinia at 900 Ma Consensus reconstruction of Li et al 2008 The idea that a supercontinent existed in the early Neoproterozoic arose in the 1970s when geologists determined that orogens of this age exist on virtually all cratons 9 failed verification Examples are the Grenville orogeny in North America and the Dalslandian orogeny in Europe Since then many alternative reconstructions have been proposed for the configuration of the cratons in this supercontinent Most of these reconstructions are based on the correlation of the orogens on different cratons 10 Though the configuration of the core cratons in Rodinia is now reasonably well known recent reconstructions still differ in many details Geologists try to decrease the uncertainties by collecting geological and paleomagnetical data Most reconstructions show Rodinia s core formed by the North American craton the later paleocontinent of Laurentia surrounded in the southeast with the East European craton the later paleocontinent of Baltica the Amazonian craton Amazonia and the West African craton in the south with the Rio de la Plata and Sao Francisco cratons in the southwest with the Congo and Kalahari cratons and in the northeast with Australia India and eastern Antarctica The positions of Siberia and North and South China north of the North American craton differ strongly depending on the reconstruction 11 12 13 SWEAT Configuration Southwest US East Antarctica craton Antarctica is on the Southwest of Laurentia and Australia is at the North of Antarctica 14 AUSWUS Configuration Australia western US Australia is at the West of Laurentia AUSMEX Configuration Australia Mexico Australia is at the location of current day Mexico relative to Laurentia The Missing link model by Li et al 2008 which has South China between Australia and the west coast of Laurentia 15 A revised Missing link model is proposed in which Tarim Block serves as an extended or alternative missing link between Australia and Laurentia 16 Siberia attached to the western US via the Belt Supergroup as in Sears amp Price 2000 17 Rodinia of Scotese 18 Little is known about the paleogeography before the formation of Rodinia Paleomagnetic and geologic data are only definite enough to form reconstructions from the breakup of Rodinia 17 onwards Rodinia is considered to have formed between 1 3 and 1 23 billion years ago and broke up again before 750 million years ago 19 Rodinia was surrounded by the superocean geologists call Mirovia from Russian mirovoj mirovoy meaning global According to J D A Piper Rodinia is one of two models for the configuration and history of the continental crust in the latter part of Precambrian times The other is Paleopangea Piper s own concept 20 Piper proposes an alternative hypothesis for this era and the previous ones This idea rejects that Rodinia ever existed as a transient supercontinent subject to progressive break up in the latter part of Proterozoic times and instead that this time and earlier times were dominated by a single persistent Paleopangaea supercontinent As evidence he suggests an observation that the palaeomagnetic poles from the continental crust assigned to this time conform to a single path between 825 and 633 million years ago and latterly to a near static position between 750 and 633 million years 8 This latter solution predicts that break up was confined to the Ediacaran period and produced the dramatic environmental changes that characterised the transition between Precambrian and Phanerozoic times However this theory has been widely criticized as incorrect applications of paleomagnetic data have been pointed out 21 Breakup edit In 2009 UNESCO s IGCP project 440 named Rodinia Assembly and Breakup concluded that Rodinia broke up in four stages between 825 and 550 Ma 22 The breakup was initiated by a superplume around 825 800 Ma whose influence such as crustal arching intense bimodal magmatism and accumulation of thick rift type sedimentary successions have been recorded in South Australia South China Tarim Kalahari India and the Arabian Nubian Craton Rifting progressed in the same cratons 800 750 Ma and spread into Laurentia and perhaps Siberia India including Madagascar and the Congo Sao Francisco Craton were either detached from Rodinia during this period or simply never were part of the supercontinent As the central part of Rodinia reached the Equator around 750 700 Ma a new pulse of magmatism and rifting continued the disassembly in western Kalahari West Australia South China Tarim and most margins of Laurentia 650 550 Ma several events coincided the opening of the Iapetus Ocean the closure of the Braziliano Adamastor and Mozambique oceans and the Pan African orogeny The result was the formation of Gondwana The Rodinia hypothesis assumes that rifting did not start everywhere simultaneously Extensive lava flows and volcanic eruptions of Neoproterozoic age are found on most continents evidence for large scale rifting about 750 million years ago 1 As early as 850 and 800 million years ago 19 a rift developed between the continental masses of present day Australia East Antarctica India and the Congo and Kalahari cratons on one side and later Laurentia Baltica Amazonia and the West African and Rio de la Plata cratons on the other 23 This rift developed into the Adamastor Ocean during the Ediacaran Around 550 million years ago near the boundary between the Ediacaran and Cambrian the first group of cratons eventually fused again with Amazonia West Africa and the Rio de la Plata cratons 24 This tectonic phase is called the Pan African orogeny It created a configuration of continents that would remain stable for hundreds of millions of years in the form of the continent Gondwana In a separate rifting event about 610 million years ago halfway into the Ediacaran period the Iapetus Ocean formed The eastern part of this ocean formed between Baltica and Laurentia the western part between Amazonia and Laurentia Because the exact moments of this separation and the partially contemporaneous Pan African orogeny are hard to correlate it might be that all continental mass was again joined in one supercontinent between roughly 600 and 550 million years ago This hypothetical supercontinent is called Pannotia Influence on paleoclimate and life editUnlike later supercontinents Rodinia would have been entirely barren Rodinia existed before complex life colonized dry land Based on sedimentary rock analysis Rodinia s formation happened when the ozone layer was not as extensive as it is today Ultraviolet light discouraged organisms from inhabiting its interior Nevertheless its existence did significantly influence the marine life of its time In the Cryogenian period the Earth experienced large glaciations and temperatures were at least as cool as today Substantial areas of Rodinia may have been covered by glaciers or the southern polar ice cap Low temperatures may have been exaggerated during the early stages of continental rifting Geothermal heating peaks in crust about to be rifted and since warmer rocks are less dense the crustal rocks rise up relative to their surroundings This rising creates areas of higher altitude where the air is cooler and ice is less likely to melt with changes in season and it may explain the evidence of abundant glaciation in the Ediacaran period 1 The eventual rifting of the continents created new oceans and seafloor spreading which produces warmer less dense oceanic lithosphere Due to its lower density hot oceanic lithosphere will not lie as deep as old cool oceanic lithosphere In periods with relatively large areas of new lithosphere the ocean floors come up causing the eustatic sea level to rise The result was a greater number of shallower seas The increased evaporation from the larger water area of the oceans may have increased rainfall which in turn increased the weathering of exposed rock By inputting data on the ratio of stable isotopes 18O 16O failed verification into computer models it has been shown that in conjunction with quick weathering of volcanic rock this increased rainfall may have reduced greenhouse gas levels to below the threshold required to trigger the period of extreme glaciation known as Snowball Earth 25 Increased volcanic activity also introduced into the marine environment biologically active nutrients which may have played an important role in the development of the earliest animals See also editColumbia for one possible reconstruction of an earlier supercontinent Supercontinent cycleReferences editCitations edit a b c McMenamin amp McMenamin 1990 chapter The Rifting of Rodinia Redfern 2001 p 335 Taube Aleksandr M R S Daglish 1993 Russko angliiskii Slovar Russian English Dictionary Moscow Russkii iazyk ISBN 5 200 01883 8 Kee Weon Seo Kim Sung Won Kwon Sanghoon Santosh M Ko Kyoungtae Jeong Youn Joong 1 December 2019 Early Neoproterozoic ca 913 895 Ma arc magmatism along the central western Korean Peninsula Implications for the amalgamation of Rodinia supercontinent Precambrian Research 335 doi 10 1016 j precamres 2019 105498 S2CID 210298156 Retrieved 9 November 2022 a b Li et al 2008 Meert 2012 Supercontinents in Earth history p 998 Zhao et al 2002 Zhao et al 2004 a b Piper 2013 Dewey amp Burke 1973 the name Rodinia was first used in McMenamin amp McMenamin 1990 See for example the correlation between the North American Grenville and European Dalslandian orogenies in Ziegler 1990 p 14 for the correlation between the Australian Musgrave orogeny and the Grenville orogeny see Wingate Pisarevsky amp Evans 2002 Implications for Rodinia reconstructions pp 124 126 fig 5 p 127 For a comparison of the SWEAT AUSWUS AUSMEX and Missing link reconstructions see Li et al 2008 Fig 2 p 182 For a comparison between the consensus Rodinia of Li et al 2008 and the original proposal of McMenamin amp McMenamin 1990 see Nance Murphy amp Santosh 2014 Fig 11 p 9 Examples of reconstructions can be found in Stanley 1999 pp 336 337 Weil et al 1998 Fig 6 p 21 Torsvik 2003 Fig Rodinia old and new p 1380 Dalziel 1997 Fig 11 p 31 Scotese 2009 Fig 1 p 69 Wang Chong Peng Peng Wang Xinping Yang Shuyan October 2016 Nature of three Proterozoic 1680 Ma 1230 Ma and 775 Ma mafic dyke swarms in North China Implications for tectonic evolution and paleogeographic reconstruction Precambrian Research 285 109 126 Bibcode 2016PreR 285 109W doi 10 1016 j precamres 2016 09 015 Retrieved 17 December 2022 Moores 1991 Goodge et al 2008 Li et al 2008 Fig 4 p 188 fig 8 p 198 Wen Bin Evans David A D Li Yong Xiang 2017 01 15 Neoproterozoic paleogeography of the Tarim Block An extended or alternative missing link model for Rodinia Earth and Planetary Science Letters 458 92 106 Bibcode 2017E amp PSL 458 92W doi 10 1016 j epsl 2016 10 030 a b Other Reconstructions for Rodinia based on sources for Mojavia Department of Geological Sciences University of Colorado Boulder May 2002 Retrieved 20 September 2010 Scotese 2009 Torsvik Gaina amp Redfield 2008 a b Torsvik 2003 p 1380 Piper 2010 Z X Li October 2009 How not to build a supercontinent A reply to J D A Piper Precambrian Research 174 1 2 208 214 Bibcode 2009PreR 174 208L doi 10 1016 j precamres 2009 06 007 Bogdanova Pisarevsky amp Li 2009 Breakup of Rodinia 825 700 Ma pp 266 267 Torsvik 2003 Fig Rodinia old and new p 1380 See for example reconstructions in Pisarevsky et al 2008 Fig 4 p 19 Donnadieu et al 2004 page needed General bibliography edit Bogdanova S V Pisarevsky S A Li Z X 2009 Assembly and Breakup of Rodinia Some Results of IGCP Project 440 Stratigraphy and Geological Correlation 17 3 259 274 Bibcode 2009SGC 17 259B doi 10 1134 S0869593809030022 ISSN 0869 5938 S2CID 129254610 Retrieved 7 February 2016 Dalziel I W 1997 Neoproterozoic Paleozoic geography and tectonics Review hypothesis environmental speculation Geological Society of America Bulletin 109 1 16 42 Bibcode 1997GSAB 109 16D doi 10 1130 0016 7606 1997 109 lt 0016 ONPGAT gt 2 3 CO 2 S2CID 129800903 Dewey J F Burke K C 1973 Tibetan Variscan and Precambrian basement reactivation products of continental collision Journal of Geology 81 6 683 692 Bibcode 1973JG 81 683D doi 10 1086 627920 JSTOR 30058995 S2CID 128770759 Donnadieu Y Godderis Y Ramstein G Nedelec A Meert J G 2004 A snowball Earth climate triggered by continental break up through changes in runoff Nature 428 6980 303 306 Bibcode 2004Natur 428 303D doi 10 1038 nature02408 PMID 15029192 S2CID 4393545 Retrieved 29 January 2016 Goodge J W Vervoort J D Fanning C M Brecke D M Farmer G L Williams I S Myrow P M DePaolo D J 2008 A positive test of East Antarctica Laurentia juxtaposition within the Rodinia supercontinent PDF Science 321 5886 235 240 Bibcode 2008Sci 321 235G doi 10 1126 science 1159189 ISSN 0036 8075 PMID 18621666 S2CID 11799613 Retrieved 4 February 2016 Li Z X Bogdanova S V Collins A S Davidson A De Waele B Ernst R E Fitzsimons I C W Fuck R A Gladkochub D P Jacobs J Karlstrom K E Lul S Natapov L M Pease V Pisarevsky S A Thrane K Vernikovsky V 2008 Assembly configuration and break up history of Rodinia A synthesis PDF Precambrian Research 160 1 2 179 210 Bibcode 2008PreR 160 179L doi 10 1016 j precamres 2007 04 021 Retrieved 6 February 2016 Loewy S L Dalziel I W D Pisarevsky S Connelly J N Tait J Hanson R E Bullen D 2011 Coats Land crustal block East Antarctica A tectonic tracer for Laurentia Geology 39 9 859 862 Bibcode 2011Geo 39 859L doi 10 1130 G32029 1 Retrieved 24 January 2016 McMenamin M A McMenamin D L 1990 The emergence of animals the Cambrian breakthrough Columbia University Press ISBN 978 0 231 06647 1 Meert J G 2012 What s in a name The Columbia Paleopangaea Nuna supercontinent PDF Gondwana Research 21 4 987 993 Bibcode 2012GondR 21 987M doi 10 1016 j gr 2011 12 002 Retrieved 6 February 2016 Meert J G Torsvik T H 2003 The making and unmaking of a Supercontinent Rodinia revisited PDF Tectonophysics 375 1 4 261 288 Bibcode 2003Tectp 375 261M doi 10 1016 S0040 1951 03 00342 1 Archived from the original PDF on 2011 07 23 Moores E M 1991 Southwest US East Antarctic SWEAT connection a hypothesis Geology 19 5 425 428 Bibcode 1991Geo 19 425M doi 10 1130 0091 7613 1991 019 lt 0425 SUSEAS gt 2 3 CO 2 Nance R D Murphy J B Santosh M 2014 The supercontinent cycle a retrospective essay Gondwana Research 25 1 4 29 Bibcode 2014GondR 25 4N doi 10 1016 j gr 2012 12 026 Retrieved 6 February 2016 Piper J D A 2010 Palaeopangaea in Meso Neoproterozoic times The palaeomagnetic evidence and implications to continental integrity supercontinent form and Eocambrian break up Journal of Geodynamics 50 3 191 223 Bibcode 2010JGeo 50 191P doi 10 1016 j jog 2010 04 004 Retrieved 24 January 2016 Piper J D A 2013 A planetary perspective on Earth evolution lid tectonics before plate tectonics Tectonophysics 589 44 56 Bibcode 2013Tectp 589 44P doi 10 1016 j tecto 2012 12 042 Retrieved 1 February 2016 Pisarevsky S A Murphy J B Cawood P A Collins A S 2008 Late Neoproterozoic and Early Cambrian palaeogeography models and problems Geological Society of London Special Publications 294 1 9 31 Bibcode 2008GSLSP 294 9P doi 10 1144 SP294 2 S2CID 128498460 Retrieved 6 February 2016 Redfern R 2001 Origins The Evolution of Continents Oceans and Life University of Oklahoma Press ISBN 978 0 8061 3359 1 Retrieved 6 February 2016 Scotese C R 2009 Late Proterozoic plate tectonics and palaeogeography a tale of two supercontinents Rodinia and Pannotia Geological Society of London Special Publications 326 1 67 83 Bibcode 2009GSLSP 326 67S doi 10 1144 SP326 4 S2CID 128845353 Retrieved 29 November 2015 http www scotese com Rodinia3 htm Sears J W Price R A 2000 New look at the Siberian connection No SWEAT Geology 28 5 423 426 Bibcode 2000Geo 28 423S doi 10 1130 0091 7613 2000 28 lt 423 NLATSC gt 2 0 CO 2 ISSN 0091 7613 Stanley S M 1999 Earth System History W H Freeman amp Co ISBN 978 0 7167 2882 5 Torsvik T H 2003 The Rodinia Jigsaw Puzzle PDF Science 300 5624 1379 1381 doi 10 1126 science 1083469 PMID 12775828 S2CID 129275224 Retrieved 24 January 2016 Torsvik T H Gaina C Redfield T F 2008 Antarctica and Global Paleogeography From Rodinia through Gondwanaland and Pangea to the birth of the Southern Ocean and the opening of gateways PDF In Cooper A K Barrett P J Stagg H Storey B Stump E Wise W eds Antarctica A Keystone in a Changing World Proceedings of the 10th International Symposium on Antarctic Earth Sciences Washington DC The National Academies Press pp 125 140 doi 10 3133 of2007 1047 kp11 inactive 1 August 2023 Archived from the original PDF on 23 July 2011 Retrieved 30 January 2016 a href Template Cite conference html title Template Cite conference cite conference a CS1 maint DOI inactive as of August 2023 link Valentine J W Moores E M 1970 Plate tectonic Regulation of Faunal Diversity and Sea Level a Model Nature 228 5272 657 659 Bibcode 1970Natur 228 657V doi 10 1038 228657a0 PMID 16058645 S2CID 4220816 Weil A B Van der Voo R Mac Niocaill C Meert J G 1998 The Proterozoic supercontinent Rodinia paleomagnetically derived reconstructions for 1100 to 800 Ma Earth and Planetary Science Letters 154 1 13 24 Bibcode 1998E amp PSL 154 13W doi 10 1016 S0012 821X 97 00127 1 Retrieved 6 February 2016 Wingate M T D Pisarevsky S A Evans D A D 2002 Rodinia connections between Australia and Laurentia no SWEAT no AUSWUS PDF Terra Nova 14 2 121 128 Bibcode 2002TeNov 14 121W doi 10 1046 j 1365 3121 2002 00401 x Retrieved 1 February 2016 Ziegler P A 1990 Geological Atlas of Western and Central Europe 2nd ed Shell Internationale Petroleum Maatschappij BV ISBN 978 90 6644 125 5 Zhao G Cawood P A Wilde S A Sun M 2002 Review of global 2 1 1 8 Ga orogens implications for a pre Rodinia supercontinent Earth Science Reviews 59 1 125 162 Bibcode 2002ESRv 59 125Z doi 10 1016 S0012 8252 02 00073 9 Retrieved 3 February 2016 Zhao G Sun M Wilde S A Li S 2004 A Paleo Mesoproterozoic supercontinent assembly growth and breakup Earth Science Reviews 67 1 91 123 Bibcode 2004ESRv 67 91Z doi 10 1016 j earscirev 2004 02 003 Retrieved 3 February 2016 External links edit nbsp Look up Rodinia in Wiktionary the free dictionary Scotese Animation Breakup of Rodinia amp Formation of Pacific Ocean Dance of the Giant Continents Washington s Earliest History IGCP Special Project 440 mapping Proterozoic supercontinents including Rodinia Paleomap Project Plate Tectonic Animations java Retrieved from https en wikipedia org w index php title Rodinia amp oldid 1194352924, wikipedia, wiki, book, books, library,

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