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Kenorland is a hypothetical Neoarchean supercontinent. If it existed, it would have been one of the earliest known supercontinents on Earth. It is thought to have formed during the Neoarchaean Era c. 2.72 billion years ago (2.72 Ga) by the accretion of Neoarchaean cratons and the formation of new continental crust. It comprised what later became Laurentia (the core of today's North America and Greenland), Baltica (today's Scandinavia and Baltic), Western Australia and Kalaharia.[1]
Historical continent | |
---|---|
Formed | 2.72 Ga |
Type | Supercontinent |
Today part of | [1] |
Swarms of volcanic dikes and their paleomagnetic orientation as well as the existence of similar stratigraphic sequences permit this reconstruction. The core of Kenorland, the Baltic/Fennoscandian Shield, traces its origins back to over 3.1 Ga. The Yilgarn Craton (present-day Western Australia) contains zircon crystals in its crust that date back to 4.4 Ga.
Kenorland was named after the Kenoran orogeny (also called the Algoman orogeny),[2] which in turn was named after the town of Kenora, Ontario.[3]
Formation
editKenorland was formed around 2.72 billion years ago (2.72 Ga) as a result of a series of accretion events and the formation of new continental crust.[4]
The accretion events are recorded in the greenstone belts of the Yilgarn Craton as metamorphosed basalt belts and granitic domes accreted around the high grade metamorphic core of the Western Gneiss Terrane, which includes elements of up to 3.2 Ga in age and some older portions, for example the Narryer Gneiss Terrane.
Breakup or disassembly
editPaleomagnetic studies show Kenorland was in generally low latitudes until tectonic magma-plume rifting began to occur between 2.48 Ga and 2.45 Ga. At 2.45 Ga the Baltic Shield was over the equator and was joined to Laurentia (the Canadian Shield) and both the Kola and Karelia cratons.[5] The protracted breakup of Kenorland during the Late Neoarchaean and early Paleoproterozoic Era 2.48 to 2.10 Gya, during the Siderian and Rhyacian periods, is manifested by mafic dikes and sedimentary rift-basins and rift-margins on many continents.[1] On early Earth, this type of bimodal deep mantle plume rifting was common in Archaean and Neoarchaean crust and continent formation.
The geological time period surrounding the breakup of Kenorland is thought by many geologists to be the beginning of the transition point from the deep-mantle-plume method of continent formation in the Hadean to Early Archean (before the final formation of the Earth's inner core) to the subsequent two-layer core-mantle plate tectonics convection theory. However, the findings of an earlier continent, Ur, and a supercontinent of around 3.1 Gya, Vaalbara, indicate this transition period may have occurred much earlier.
The Kola and Karelia cratons began to drift apart around 2.45 Gya, and by 2.4 Gya the Kola craton was at about 30 degrees south latitude and the Karelia craton was at about 15 degrees south latitude. Paleomagnetic evidence shows that at 2.45 Gya the Yilgarn craton (now the bulk of Western Australia) was not connected to Fennoscandia-Laurentia and was at about ~5 degrees south latitude.[citation needed]
This implies that at 2.515 Gya an ocean existed between the Kola and Karelia cratons, and that by 2.45 Gya there was no longer a supercontinent. Also, there is speculation based on the rift margin spatial arrangements of Laurentia, that at some time during the breakup, the Slave and Superior cratons were not part of the supercontinent Kenorland, but, by then may have been two different Neoarchaean landmasses (supercratons) on opposite ends of a very large Kenorland. This is based on how drifting assemblies of various constituent pieces should flow reasonably together toward the amalgamation of the new subsequent continent. The Slave and Superior cratons now constitute the northwest and southeast portions of the Canadian Shield, respectively.
The breakup of Kenorland was contemporary with the Huronian glaciation which persisted for up to 60 million years. The banded iron formations (BIF) show their greatest extent at this period, thus indicating a massive increase in oxygen build-up from an estimated 0.1% of the atmosphere to 1%. The rise in oxygen levels caused the virtual disappearance of the greenhouse gas methane (oxidized into carbon dioxide and water).
The simultaneous breakup of Kenorland generally increased continental rainfall everywhere, thus increasing erosion and further reducing the other greenhouse gas, carbon dioxide. With the reduction in greenhouse gases, and with solar output being less than 85% its current power, this led to a runaway Snowball Earth scenario, where average temperatures planet-wide plummeted to below freezing. Despite the anoxia indicated by the BIF, photosynthesis continued, stabilizing climates at new levels during the second part of the Proterozoic Era.
References
edit- ^ a b c Pesonen et al. 2003, Abstract
- ^ Salminen, Johnna; Pehrsson, Sally; Evans, David A.D.; Wang, Chong (2021). "Neoarchean-Paleoproterozoic supercycles". In Pesonen, Lauri J.; Salminen, Johanna; Elming, Sten-Ake; Evans, David A.D.; Veikkolainen, Toni (eds.). Ancient Supercontinents and the Paleogeography of Earth. Elsevier. p. 466. ISBN 0128185341.
- ^ Gower, Charles F.; Clifford, Paul M. (1981). "The structural geometry and geological history of Archean rocks at Kenora, north-western Ontario—a proposed type area for the Kenoran Orogeny". Canadian Journal of Earth Sciences.
- ^ Halla 2005, Introduction, p. 22
- ^ Mertanen 2004, p. 190
Bibliography
edit- Arestova, N. A.; Lobach-Zhuchenko, S. B.; Chekulaev, V. P.; Gus'kova, E. G. (2003). "Early Precambrian mafic rocks of the Fennoscandian shield as a reflection of plume magmatism: Geochemical types and formation stages" (PDF). Russian Journal of Earth Sciences. 5 (3): 145–163. doi:10.2205/2003es000126. Retrieved March 12, 2016.
- Aspler, L. B.; Chiarenzilli, J. R.; Cousens, B. L.; Davis, W. J.; McNicoll, V. J.; Rainbird, R. H. (1999). "Intracratonic basin processes from breakup of Kenorland to assembly of Laurentia: new geochronology and models for Hurwitz Basin, Western Churchill Province" (PDF). Contributions to the Western Churchill NATMAP Project; Canada-Nunavut Geoscience Office. Retrieved March 12, 2016.
- Halla, J. (2005). "Neoarchean sanukitoids (2.74–2.70 Ga)" (PDF). In Halla, J.; Nironen, M.; Lauri, L. S.; Kurhila, M. I.; Käpyaho, A.; Sorjonen-Ward, P.; Äikäs, O. (eds.). Eurogranites 2005: Proterozoic and Archean Granites and Related Rocks of the Finnish Precambrian. University of Helsinki. Retrieved March 12, 2016.
- Mertanen, Satu (2004). Paleomagnetic Evidences for the Evolution of the Earth during Early Paleoproterozoic. Symposium EV04: Interaction of Endogenic, Exogenic and Biological Terrestrial Systems (PDF).
- Pesonen, L. J.; Elming, S.-Å.; Mertanen, S.; Pisarevsky, S.; D’Agrella-Filho, M. S.; Meert, J. G.; Schmidt, P. W.; Abrahamsen, N.; Bylund, G. (2003). "Palaeomagnetic configuration of continents during the Proterozoic". Tectonophysics. 375 (1–4): 289–324. Bibcode:2003Tectp.375..289P. doi:10.1016/s0040-1951(03)00343-3. Retrieved March 12, 2016.