Carbonatite

Carbonatite ( /kɑːrˈbɒnətt/) is a type of intrusive or extrusive igneous rock defined by mineralogic composition consisting of greater than 50% carbonate minerals.[1] Carbonatites may be confused with marble and may require geochemical verification.

Carbonatite
Igneous rock
Carbonatite from Jacupiranga, Brazil. This rock is a mixture of calcite, magnetite and olivine
Composition
Primarycarbonate minerals, (> 50%)
SecondaryOther
Carbonatite lava at Ol Doinyo Lengai volcano, Tanzania

Carbonatites usually occur as small plugs within zoned alkalic intrusive complexes, or as dikes, sills, breccias, and veins.[2] They are almost exclusively associated with continental rift-related tectonic settings. It seems that there has been a steady increase in the carbonatitic igneous activity through the Earth's history, from the Archean eon to the present.

Nearly all carbonatite occurrences are intrusives or subvolcanic intrusives. This is because carbonatite lava flows, being composed largely of soluble carbonates, are easily weathered and are therefore unlikely to be preserved in the geologic record. Carbonatite eruptions as lava may therefore not be as uncommon as thought, but they have been poorly preserved throughout the Earth's history.[3]

Carbonatite liquid compositions are significantly more alkaline than what is preserved in the fossil carbonatite rock record as composition of the melt inclusions shows.[4]

Only one carbonatite volcano is known to have erupted in historical time, the active Ol Doinyo Lengai volcano in Tanzania. It erupts with the lowest-temperature lava in the world, at 500–600 °C. The lava is natrocarbonatite dominated by nyerereite and gregoryite.

Genesis

The magmatic origin of carbonatite was argued in detail by Swedish geologist Harry von Eckermann in 1948 based on his study of Alnö Complex.[5][6] It was however the 1960 eruption of Ol Doinyo Lengai in Tanzania that led to geological investigations that finally confirmed the view that carbonatite is derived from magma.[5]

Carbonatites are rare, peculiar igneous rocks formed by unusual processes and from unusual source rocks. Three models of their formation exist:

  1. direct generation by very low-degree partial melts in the mantle and melt differentiation,
  2. liquid immiscibility between a carbonate melt and a silicate melt,
  3. peculiar, extreme crystal fractionation.

Evidence for each process exists, but the key is that these are unusual phenomena. Historically, carbonatites were thought to form by melting of limestone or marble by intrusion of magma, but geochemical and mineralogical data discount this. For example, the carbon isotopic composition of carbonatites is mantle-like and not like sedimentary limestone.[7]

The age of carbonatites ranges from Archean to present: the oldest carbonatite, Tupertalik in Greenland, is 3007 Ma old, while Ol Doinyo Lengai volcano in Tanzania is presently active.[8]

Mineralogy

Primary mineralogy is highly variable, but may include natrolite, sodalite, apatite, magnetite, barite, fluorite, ancylite group minerals, and other rare minerals not found in more common igneous rocks. Recognition of carbonatites may be difficult, especially as their mineralogy and texture may not differ much from marble except the presence of igneous minerals. They may also be sources of mica or vermiculite.

Carbonatites are classed as calcitic sovite (coarse textured) and alvikite (finer textured) varieties or facies. The two are also distinguished by minor and trace element composition.[9][10] The terms rauhaugite and beforsite refer to dolomite- and ankerite-rich occurrences respectively. The alkali-carbonatites are termed lengaite. Examples with 50–70% carbonate minerals are termed silico-carbonatites.[10] Additionally, carbonatites may be either enriched in magnetite and apatite or rare-earth elements, fluorine and barium.[11]

Natrocarbonatite is made up largely of two minerals, nyerereite (named after Julius Nyerere, the first president of independent Tanzania) and gregoryite (named after John Walter Gregory, one of the first geologists to study the East African Rift and author of the book The Great Rift Valley). These minerals are both carbonates in which sodium and potassium are present in significant quantities. Both are anhydrous, and when they come into contact with the moisture in the atmosphere, they begin to react extremely quickly. The black or dark brown lava and ash erupted begins to turn white within a few hours, then grey after a few days, then brown after a few weeks.[12]

Geochemistry

Magnesiocarbonatite, from Verity-Paradise Carbonatite Complex of British Columbia. Specimen is 75 mm wide.

Carbonatite is composed predominantly of carbonate minerals and extremely unusual in its major element composition as compared to silicate igneous rocks, obviously because it is composed primarily of Na2O and CaO plus CO2.

Most carbonatites tend to include some silicate mineral fraction; by definition an igneous rock containing >50% carbonate minerals is classified as a carbonatite. Silicate minerals associated with such compositions are pyroxene, olivine, and silica-undersaturated minerals such as nepheline and other feldspathoids.

Geochemically, carbonatites are dominated by incompatible elements (Ba, Cs, Rb) and depletions in compatible elements (Hf, Zr, Ti). This together with their silica-undersaturated composition supports inferences that carbonatites are formed by low degrees of partial melting.

A specific type of hydrothermal alteration termed fenitization is typically associated with carbonatite intrusions. This alteration assemblage produces a unique rock mineralogy termed a fenite after its type locality, the Fen Complex in Norway. The alteration consists of metasomatic halos consisting of sodium rich silicates arfvedsonite, barkevikite and glaucophane along with phosphates, hematite and other iron and titanium oxides.[11]

Occurrence

Okaite, an ultramafic rock found near the carbonatite of the Oka Carbonatite Complex, Oka, Quebec

Overall, 527 carbonatite localities are known on Earth, and they are found on all continents and also on oceanic islands. Most of the carbonatites are shallow intrusive bodies of calcite-rich igneous rocks in form of volcanic necks, dykes, and cone-sheets. These generally occur in association with larger intrusions of alkali-rich silicate igneous rocks. The extrusive carbonatites are particularly rare, only 49 are known, and they appear to be restricted to a few continental rift zones, such as the Rhine valley and the East African rift system.[13]

Associated igneous rocks typically include ijolite, melteigite, teschenite, lamprophyres, phonolite, foyaite, shonkinite, silica undersaturated foid-bearing pyroxenite (essexite), and nepheline syenite.

Carbonatites are typically associated with undersaturated (low silica) igneous rocks that are either alkali (Na2O and K2O), ferric iron (Fe2O3) and zirconium-rich agpaitic rocks or alkali-poor, FeO-CaO-MgO-rich and zirconium-poor miaskitic rocks.[11]

The Mount Weld carbonatite is unassociated with a belt or suite of alkaline igneous rocks, although calc-alkaline magmas are known in the region. The genesis of this Archaean carbonatite remains contentious as it is the sole example of an Archaean carbonatite in Australia.

Intrusive morphology

Carbonatite is known to form in association with concentrically zoned complexes of alkaline-igneous rocks, the typical example of this being Phalaborwa, South Africa.

Carbonatites take the form of sills, lopoliths and rare dikes are reported in the Guyana Shield.

The Mud Tank and Mount Weld carbonatites take the form of multi-stage cylindrical intrusive bodies with several distinct phases of carbonatite intrusion. Smaller carbonatite sills and dikes are present in other Proterozoic mobile belts in Australia, typically as dikes and discontinuous pods.

Known examples

Dozens of carbonatites are known including:

In 2017, the discovery of a new carbonatite deposit was confirmed north-west of Prince George, British Columbia, in a region termed the "Rocky Mountain Rare Metal Belt".[15]

The volcano Ol Doinyo Lengai, in the East African Rift is the world's only active carbonatite volcano. Other older carbonatite volcanoes are located in the same region, including Mount Homa.

Economic importance

Thin section of apatite-rich carbonatite in cross polarised transmitted light. The sample is from Siilinjärvi apatite mine.

Carbonatites may contain economic or anomalous concentrations of rare-earth elements, phosphorus, niobiumtantalum, uranium, thorium, copper, iron, titanium, vanadium, barium, fluorine, zirconium, and other rare or incompatible elements. Apatite, barite and vermiculite are among the industrially important minerals associated with some carbonatites.[11]

Trace elements are extremely enriched in carbonatites, and they have the highest concentration of lanthanides of any known rock type.[16] The largest REE-carbonatite deposits are Bayan Obo,[17] Mountain Pass,[18] Maoniuping,[19] and Mount Weld.[20]

Vein deposits of thorium, fluorite, or rare-earth elements may be associated with carbonatites and may be hosted internal to or within the metasomatized aureole of a carbonatite.

As an example, the Palabora complex of South Africa has produced significant copper (as chalcopyrite, bornite and chalcocite), apatite, vermiculate along with lesser magnetite, linnaeite (cobalt), baddeleyite (zirconium–hafnium), and by-product gold, silver, nickel and platinum.[11]

References

  1. Bell, Keith (editor) (1989) Carbonatites: Genesis and Evolution, London, Unwin Hyman.
  2. Andersson, Magnus; Malehmir, Alireza; Troll, Valentin R.; Dehghannejad, Mahdieh; Juhlin, Christopher; Ask, Maria (2013-04-17). "Carbonatite ring-complexes explained by caldera-style volcanism". Scientific Reports. 3 (1): 1677. doi:10.1038/srep01677. ISSN 2045-2322.
  3. Stoppa, Francesco; Jones, Adrian P.; Sharygin, Victor V. (2009). "Nyerereite from carbonatite rocks at Vulture volcano: implications for mantle metasomatism and petrogenesis of alkali carbonate melts". Central European Journal of Geosciences. 1 (2): 131–151. doi:10.2478/v10085-009-0012-9.
  4. Guzmics, Tibor; Mitchell, Roger H.; Szabó, Csaba; Berkesi, Márta; Milke, Ralf; Ratter, Kitti (2012). "Liquid immiscibility between silicate, carbonate and sulfide melts in melt inclusions hosted in co-precipitated minerals from Kerimasi volcano (Tanzania): evolution of carbonated nephelinitic magma". Contributions to Mineralogy and Petrology. 164 (1): 101–122. Bibcode:2012CoMP..164..101G. doi:10.1007/s00410-012-0728-6.
  5. Hode Vuorinen, Jaana (2005). The Alnö alkaline and carbonatitic complex, east central Sweden – a petrogenetic study (Ph.D.). Stockholm University. pp. 1–28.
  6. Kresten, Peter; Troll, Valentin R. (2018). The Alnö Carbonatite Complex, Central Sweden. GeoGuide. Springer International Publishing. ISBN 978-3-319-90223-4.
  7. Shavers, Ethan J.; Ghulam, Abduwasit; Encarnacion, John; Bridges, David L.; Luetkemeyer, P. Benjamin (2016-04-01). "Carbonatite associated with ultramafic diatremes in the Avon Volcanic District, Missouri, USA: Field, petrographic, and geochemical constraints". Lithos. 248–251: 506–516. Bibcode:2016Litho.248..506S. doi:10.1016/j.lithos.2016.02.005.
  8. Downes, H., Wall, F., Demy, A. & Szabo, C. 2012. Continuing the Carbonatite Controversy. Mineralogical Magazine 76, 255-257.
  9. http://sajg.geoscienceworld.org/cgi/content/abstract/102/2/109 M. J. Le Bas, Sovite and alvikite; two chemically distinct calciocarbonatites C1 and C2, South African Journal of Geology; June 1999; v. 102; no. 2; p. 109–121.
  10. Peter Kresten, Carbonatite nomenclature, International Journal of Earth Sciences, Volume 72, Number 1 / February, 1983.
  11. Guilbert, John M. and Charles F. Park, Jr., 1986, The Geology of Ore Deposits, Freeman, pp. 188 and 352-361 ISBN 0-7167-1456-6
  12. Allington-Jones, L. (2014). "Preserving carbonatite lavas" (PDF). The Geological Curator. 10 (1): 3–8.
  13. Woolley & Church 2005, Woolley & Kjarsgaard 2008a, 2008b
  14. Shavers, Ethan J. (2016). "Carbonatite associated with ultramafic diatremes in the Avon Volcanic District, Missouri, USA: Field, petrographic, and geochemical constraints". Lithos. 248–251: 506–516. Bibcode:2016Litho.248..506S. doi:10.1016/j.lithos.2016.02.005.
  15. "German Geologist Discovers a Rare Carbonatite Complex in British Columbia" (PDF).
  16. Woolley, A.R. ja Kempe, D.R.C. 1989. Nomenclature, Average Chemical Compositions, and Element Distribution. In: Bell, K. (Eds.) Carbonatites, Genesis and Evolution, Unwin Hyman, 1-14.
  17. Yang, X.Y., Sun, W.D., Zhang, Y.X. & Zheng Y.F. 2009. Geochemical constraints on the genesis of the Bayan Obo Fe-Nb-REE deposit in Inner Mongolia, China. Geochimica et Cosmochimica Acta 73, 1417-1435
  18. Castor, S.B. 2008. The Mountain Pass Rare Earth carbonatite and associated ultrapotassic rocks, California. Canadian Mineralogist 46, 779-806.
  19. Xie, Y., Hou, Z., Yin, S., Dominy, S.C., Xu, J., Tian, S. & Xu, W. 2009. Continuous carbonatitic melt-fluid evolution of a REE mineralization system: Evidence from inclusions in the Maoniuping REE Deposit, Western Sichuan, China. Ore Geology Reviews 36, 90-105.
  20. Lottermoser, B.G. 1990. Rare-earth element mineralisation within the Mt. Weld carbonatite laterite, Western Australia. Lithos 24, 151-167

Sources

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