Greenstone belts are zones of variably metamorphosed mafic to ultramafic volcanic sequences with associated sedimentary rocks that occur within Archaean and Proterozoic cratons between granite and gneiss bodies.

Kilimafedha greenstone belt in Tanzania

The name comes from the green hue imparted by the colour of the metamorphic minerals within the mafic rocks: The typical green minerals are chlorite, actinolite, and other green amphiboles. Greenstone belts also often contain ore deposits of gold, silver, copper, zinc, and lead.

A greenstone belt is typically several dozens to several thousand kilometres long. Typically, a greenstone belt within the greater volume of otherwise homogeneous granite-gneiss within a craton contains a significantly larger degree of heterogeneity and complications and forms a tectonic marker far more distinct than the much more voluminous and homogeneous granites. Additionally, a greenstone belt contains far more information on tectonic and metamorphic events, deformations, and paleogeologic conditions than the granite and gneiss events, because the vast majority of greenstones are interpreted as altered basalts and other volcanic or sedimentary rocks. As such, understanding the nature and origin of greenstone belts is the most fruitful way of studying Archaean geological history.

Nature and formation

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Metamorphosed pillow lava from the Ishpeming Greenstone Belt in Michigan

Greenstone belts have been interpreted as having formed at ancient oceanic spreading centers and island arc terranes.

Greenstone belts are primarily formed of volcanic rocks, dominated by basalt, with minor sedimentary rocks inter-leaving the volcanic formations. Through time, the degree of sediment contained within greenstone belts has risen, and the amount of ultramafic rock (either as layered intrusions or as volcanic komatiite) has decreased.

There is also a change in the structure and relationship of greenstone belts to their basements between the Archaean where there is little clear relationship, if any, between basalt-peridotite sheets of a greenstone belt and the granites they abut, and the Proterozoic where greenstone belts sit upon granite-gneiss basements and / or other greenstone belts, and the Phanerozoic where clear examples of island arc volcanism, arc sedimentation and ophiolite sequences become more dominant.

This change in nature is interpreted as a response to the maturity of the plate tectonics processes throughout the Earth's geological history. Archaean plate tectonics did not take place on mature crust and as such the presence of thrust-in allochthonous greenstone belts is expected. By the Proterozoic, magmatism was occurring around cratons and with established sedimentary sources, with little recycling of the crust, allowing preservation of more sediments. By the Phanerozoic, extensive continental cover and lower heat flow from the mantle has seen greater preservation of sediments and greater influence of continental masses.

Greenstones, aside from containing basalts, also give rise to several types of metamorphic rocks which are used synonymously with 'metabasalt' et cetera; greenschist, whiteschist and blueschist are all terms spawned from the study of greenstone belts.

The West African early Proterozoic greenstone belts are similar to the Archean greenstone belts. These similarities include a decrease in the amount of ultramafic and mafic rocks as you move up the stratigraphic column, in addition to an increase in pyroclastics, felsic and/or andesite rocks. Also, the rock successions tend to have clastics in the upper portion and tholeiitic suites in the lower. Calc-alkaline dikes are common in these suites.[1]

Distribution

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Weathered Precambrian pillow lava in the Temagami greenstone belt on the Canadian Shield

Archaean greenstones are found in the Slave craton, northern Canada, Pilbara craton and Yilgarn Craton, Western Australia, Gawler Craton in South Australia, and in the Wyoming Craton in the US. Examples are found in South and Eastern Africa, namely the Kaapvaal craton and also in the cratonic core of Madagascar, as well as West Africa and Brazil, northern Scandinavia and the Kola Peninsula (see Baltic Shield).

Proterozoic greenstones occur sandwiched between the Pilbara and Yilgarn cratons in Australia, and adjoining the Gawler Craton and within the extensive Proterozoic mobile belts of Australia, within West Africa, throughout the metamorphic complexes surrounding the Archaean core of Madagascar; the eastern United States, northern Canada and northern Scandinavia. The Abitibi greenstone belt in Ontario and Quebec is one of the largest Archean greenstone belts in the world.

In Antarctica, the Proterozoic-aged Fisher Massif closely resembles the composition and structure of a greenstone belt.[2]

One of the best known greenstone belts in the world is the South African Barberton greenstone belt, where gold was first discovered in South Africa. The Barberton Greenstone belt was first uniquely identified by Prof Annhauser at the University of the Witwatersrand, Johannesburg. His work in mapping and detailing the characteristics of the Barberton Greenstone belt has been used as a primer for other greenstone belts around the world. He noted the existence of pillow lavas, indicating a lava being rapidly cooled in water, as well as the spinifex textures created by crystals formed under rapidly cooling environments, namely water.

List of greenstone belts

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Africa

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Asia

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Europe

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North America

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South America

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Australia

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References

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  1. ^ Huot, Daniel; Sattran, Vladimir (1987). "Gold in Birrimian greenstone belts of Burkina Faso, West Africa". Economic Geology. 82 (8): 2033–2044. Bibcode:1987EcGeo..82.2033H. doi:10.2113/gsecongeo.82.8.2033.
  2. ^ "Prince Charles Mountains". Australian Antarctic Division. 30 July 2002. Archived from the original on 2 April 2015. Retrieved 14 November 2019.
  3. ^ Manikyamba, C.; Kerrich, R.; Naqvi, S.M.; Ram Mohan, M. (2004). "Geochemical systematics of tholeiitic basalts from the 2.7 Ga Ramagiri-Hungund composite greenstone belt, Dharwar craton". Precambrian Research. 134 (1–2): 21–39. Bibcode:2004PreR..134...21M. doi:10.1016/j.precamres.2004.05.010.
  4. ^ Robertson, James M.; Moench, R.H. (17 October 2023) [c. 2014]. "The Pecos greenstone belt – a Proterozoic volcano-sedimentary sequence in the southern Sangre de Cristo Mountains, New Mexico". nmgs.nmt.edu. Guidebook (revised ed.). Socorro, NM: New Mexico Geological Society. ID 6172. Retrieved 1 March 2017.
  5. ^ Lemen, D.; Lindline, J.; Bosbyshell, H. (2015). The Gallinas Canyon gneiss: A window into the nature and timing of Paleoproterozoic events in northern New Mexico (PDF). Field Conference. Vol. 66. Socorro, NM: New Mexico Geological Society. pp. 185–192. Retrieved 15 June 2020.
  6. ^ Henderson, J.F.; Brown, I.C. (1966). Geology and structure of the Yellowknife Greenstone Belt, District of Mackenzie (zip) (Report). Geological Survey of Canada Bulletin. Vol. 141. p. 38. doi:10.4095/101459. (lat,lon) = ( 49.5°, −114°) to ( 49.0°, −113°).
  7. ^ Naipal, R.; Kroonenberg, S.B. (December 2016) [4 May 2016]. "Provenance signals in metaturbidites of the Paleoproterozoic greenstone belt of the Guiana shield in Suriname". Netherlands Journal of Geosciences. 95 (4): 467–489. Bibcode:2016NJGeo..95..467N. doi:10.1017/njg.2016.9. Available on CJO 2016.
  8. ^ Norseman-Wiluna greenstone belt (PDF). gladiatorresources.com.au (map). Leederville, WA, Australia: Gladiator Resources Ltd. Archived from the original (PDF) on 14 October 2009. Retrieved 6 September 2009.

Sources

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