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Anorthosite

December 15, 2023

Not to be confused with Anorthite.

Anorthosite (/əˈnɔːrθəst/) is a phaneritic, intrusive igneous rock characterized by its composition: mostly plagioclase feldspar (90–100%), with a minimal mafic component (0–10%). Pyroxene, ilmenite, magnetite, and olivine are the mafic minerals most commonly present.

Anorthosite
Igneous rock
Anorthosite from Salem district, Tamil Nadu, India
Composition
PrimaryPlagioclase
SecondaryMafic minerals

Anorthosites are of enormous geologic interest, because it is still not fully understood how they form. Most models involve separating plagioclase crystals based on their density. Plagioclase crystals are usually less dense than magma; so, as plagioclase crystallizes in a magma chamber, the plagioclase crystals float to the top, concentrating there.[1][2][3]

Anorthosite on Earth can be divided into five types:[3]

  1. Archean-age anorthosites
  2. Proterozoic anorthosite (also known as massif or massif-type anorthosite) – the most abundant type of anorthosite on Earth[2]
  3. Layers within Layered Intrusions (e.g., Bushveld and Stillwater intrusions)
  4. Mid-ocean ridge and transform fault anorthosites
  5. Anorthosite xenoliths in other rocks (often granites, kimberlites, or basalts)

Of these, the first two are the most common. These two types have different modes of occurrence, appear to be restricted to different periods in Earth's history, and are thought to have had different origins.[2]

Lunar anorthosites constitute the light-coloured areas of the Moon's surface and have been the subject of much research.[4]

Proterozoic anorthosite massifs edit

Age edit

Proterozoic anorthosites were emplaced during the Proterozoic Eon (ca. 2,500–542 Ma), though most were emplaced between 1,800 and 1,000 Ma.[2]

Occurrence edit

Proterozoic anorthosites typically occur as extensive stocks or batholiths.[1] The areal extent of anorthosite batholiths ranges from relatively small (dozens or hundreds of square kilometers) to nearly 20,000 km2 (7,700 sq mi), in the instance of the Nain Plutonic Suite or Mistastin crater[5] in northern Labrador, Canada.

Major occurrences of Proterozoic anorthosite are found in the southeast U.S., the Appalachian Mountains (e.g., the Honeybrook Upland of eastern Pennsylvania), eastern Canada (e.g., the Grenville Province), across southern Scandinavia and eastern Europe. Mapped onto the Pangaean continental configuration of that eon, these occurrences are all contained in a single straight belt, and must all have been emplaced intracratonally. The conditions and constraints of this pattern of origin and distribution are not clear.[citation needed] However, see the Origins section below.

Related rocks edit

Many Proterozoic anorthosites occur in spatial association with other highly distinctive, contemporaneous rock types: the so-called 'anorthosite suite' or 'anorthosite-mangerite-charnockite-granite (AMCG) complex'.

These rock types can include:

Though co-eval, these rocks likely represent chemically-independent magmas, likely produced by melting of country rock into which the anorthosites intruded.[2]

Importantly, large volumes of ultramafic rocks are not found in association with Proterozoic anorthosites.[6]

Physical characteristics edit

 
Nain Anorthosite, a mid-Mesoproterozoic intrusion (1.29 to 1.35 billion years), Labrador. Polished slab; blue color is labradorescence.

Since they are primarily composed of plagioclase feldspar, most of Proterozoic anorthosites appear, in outcrop, to be grey or bluish. Individual plagioclase crystals may be black, white, blue, or grey, and may exhibit an iridescence known as labradorescence on fresh surfaces. The feldspar variety labradorite is commonly present in anorthosites. Mineralogically, labradorite is a compositional term for any calcium-rich plagioclase feldspar containing 50–70 molecular percent anorthite (An 50–70), regardless of whether it shows labradorescence. The mafic mineral in Proterozoic anorthosite may be clinopyroxene, orthopyroxene, olivine, or, more rarely, amphibole. Oxides, such as magnetite or ilmenite, are also common.

Most anorthosite plutons are very coarse grained; that is, the individual plagioclase crystals and the accompanying mafic mineral are more than a few centimetres long. Less commonly, plagioclase crystals are megacrystic, or larger than one metre long. However, most Proterozoic anorthosites are deformed, and such large plagioclase crystals have recrystallized to form smaller crystals, leaving only the outline of the larger crystals behind.

While many Proterozoic anorthosite plutons appear to have no large-scale relict igneous structures (having instead post-emplacement deformational structures), some do have igneous layering, which may be defined by crystal size, mafic content, or chemical characteristics. Such layering clearly has origins with a rheologically liquid-state magma.

Chemical and isotopic characteristics edit

Proterozoic anorthosites are typically >90% plagioclase, and the plagioclase composition is commonly between An40 and An60 (40–60% anorthite).[1] This compositional range is intermediate, and is one of the characteristics which distinguish Proterozoic anorthosites from Archean anorthosites (which are typically >An80).[1]

Proterozoic anorthosites often have significant mafic components in addition to plagioclase.[1] These phases can include olivine, pyroxene, Fe-Ti oxides, and/or apatite.[2] Mafic minerals in Proterozoic anorthosites have a wide range of composition, but are not generally highly magnesian.[citation needed]

The trace-element chemistry of Proterozoic anorthosites, and the associated rock types, has been examined in some detail by researchers with the aim of arriving at a plausible genetic theory. However, there is still little agreement on just what the results mean for anorthosite genesis; see the 'Origins' section below. A very short list of results, including results for rocks thought to be related to Proterozoic anorthosites,[7][clarification needed]

Some research has focused on neodymium (Nd) and strontium (Sr) isotopic determinations for anorthosites, particularly for anorthosites of the Nain Plutonic Suite (NPS). Such isotopic determinations are of use in gauging the viability of prospective sources for magmas that gave rise to anorthosites. Some results are detailed below in the 'Origins' section.

High-alumina orthopyroxene megacrysts (HAOMs) edit

Many Proterozoic-age anorthosites contain large crystals of orthopyroxene with distinctive compositions. These are the so-called high-alumina orthopyroxene megacrysts (HAOM).[8][9]

HAOM are distinctive because 1) they contain higher amounts of Al than typically seen in orthopyroxenes; 2) they are cut by numerous thin lathes of plagioclase, which may represent exsolution lamellae;[10] and 3) they appear to be older than the anorthosites in which they are found.[9]

The origins of HAOMs are debated. One possible model[9] suggests that, during anorthosite formation, a mantle-derived melt (or partially-crystalline mush) was injected into the lower crust and began crystallizing. HAOMs would have crystallized out during this time, perhaps as long as 80–120 million years. The HAOM-bearing melt could then have risen to the upper crust. This model is supported by the fact that aluminum is more soluble in orthopyroxene at high pressure.[10][11] In this model, the HAOM represent lower-crustal cumulates that are related to the anorthosite source-magma. One problem with this model is that it requires the anorthosite source-magma to sit in the low crust for a considerable time. To solve this, some authors[10] suggest that the HAOMs may have formed in the lower crust independent of the anorthosite source-magma. Later, the anorthosite source-magma may have entrained pieces of the HAOM-bearing lower crust on its way upward. Other researchers consider the chemical compositions of the HAOM to be the product of rapid crystallization at moderate or low pressures,[12] eliminating the need for a lower-crustal origin altogether.

Origins of Proterozoic anorthosites edit

The origins of Proterozoic anorthosites have been a subject of theoretical debate for many decades. A brief synopsis of this problem is as follows:

The problem begins with the generation of magma, the necessary precursor of any igneous rock.

Magma generated by small amounts of partial melting of the mantle is generally of basaltic composition. Under normal conditions, the composition of basaltic magma requires it to crystallize between 50 and 70% plagioclase, with the bulk of the remainder of the magma crystallizing as mafic minerals. However, anorthosites are defined by a high plagioclase content (90–100% plagioclase), and are not found in association with contemporaneous ultramafic rocks.[6] This is now known as 'the anorthosite problem.' Proposed solutions to the anorthosite problem have been diverse, with many of the proposals drawing on different geological subdisciplines.

It was suggested early in the history of anorthosite debate that a special type of magma, anorthositic magma, had been generated at depth, and emplaced into the crust. However, the solidus of an anorthositic magma is too high for it to exist as a liquid for very long at normal ambient crustal temperatures, so this appears to be unlikely. The presence of water vapor has been shown to lower the solidus temperature of anorthositic magma to more reasonable values, but most anorthosites are relatively dry. It may be postulated, then, that water vapor be driven off by subsequent metamorphism of the anorthosite, but some anorthosites are undeformed, thereby invalidating the suggestion.

The discovery, in the late 1970s, of anorthositic dykes in the Nain Plutonic Suite, suggested that the possibility of anorthositic magmas existing at crustal temperatures needed to be reexamined.[13] However, the dykes were later shown to be more complex than was originally thought.

In summary, though liquid-state processes clearly operate in some anorthosite plutons, the plutons are probably not derived from anorthositic magmas.

Many researchers have argued that anorthosites are the products of basaltic magma, and that mechanical removal of mafic minerals has occurred. Since the mafic minerals are not found with the anorthosites, these minerals must have been left at either a deeper level or the base of the crust. A typical theory is as follows: partial melting of the mantle generates a basaltic magma, which does not immediately ascend into the crust. Instead, the basaltic magma forms a large magma chamber at the base of the crust and fractionates large amounts of mafic minerals, which sink to the bottom of the chamber. The co-crystallizing plagioclase crystals float, and eventually are emplaced into the crust as anorthosite plutons. Most of the sinking mafic minerals form ultramafic cumulates which stay at the base of the crust.

This theory has many appealing features, of which one is the capacity to explain the chemical composition of high-alumina orthopyroxene megacrysts (HAOM). This is detailed below in the section devoted to the HAOM. However, on its own, this hypothesis cannot coherently explain the origins of anorthosites, because it does not fit with, among other things, some important isotopic measurements made on anorthositic rocks in the Nain Plutonic Suite. The Nd and Sr isotopic data show the magma which produced the anorthosites cannot have been derived only from the mantle. Instead, the magma that gave rise to the Nain Plutonic Suite anorthosites must have had a significant crustal component. This discovery led to a slightly more complicated version of the previous hypothesis: Large amounts of basaltic magma form a magma chamber at the base of the crust, and, while crystallizing, assimilating large amounts of crust.[14]

This small addendum explains both the isotopic characteristics and certain other chemical niceties of Proterozoic anorthosite. However, at least one researcher has cogently argued, on the basis of geochemical data, that the mantle's role in production of anorthosites must actually be very limited: the mantle provides only the impetus (heat) for crustal melting, and a small amount of partial melt in the form of basaltic magma. Thus anorthosites are, in this view, derived almost entirely from lower crustal melts.[15]

Lunar anorthosite edit

On the Moon, anorthosite is the dominant rock type of the lunar highlands which covers ~80% of the lunar surface. Lunar anorthosite is characterized as ferroan anorthosite (FAN), or magnesium anorthosite (MAN).[16] Pristine lunar FAN is some of the oldest lunar rock and the original cumulate of the lunar magma ocean, with the Mg-suite forming from later impacts and plutonism.[17] However, debate exists on the magma ocean fractionation complicated by surface impact mixing with evidence potentially indicating MAN being older and more primitive.[18]

Lunar anorthosite is associated with two other rock types: norite and troctolite. Together, they comprise the "ANT" suite of moon rocks. [19][20]

Archean anorthosites edit

Archean anorthosites represent the second largest anorthosite deposits on Earth. Most have been dated between 3,200 and 2,800 Ma, and commonly associated with basalts and/or greenstone belts.[1]

Archean anorthosites are distinct texturally and mineralogically from Proterozoic anorthosite bodies. Their most characteristic feature is the presence of equant, euhedral megacrysts (up to 30 cm) of plagioclase surrounded by a fine-grained mafic groundmass. The plagioclase in these anorthosites is commonly An80-90.

Economic value of anorthosite edit

The primary economic value of anorthosite bodies is the titanium-bearing oxide ilmenite. However, some Proterozoic anorthosite bodies have large amounts of labradorite, which is quarried for its value as both a gemstone and a building material. Archean anorthosites, because they are aluminium-rich, have large amounts of aluminium substituting for silicon; a few of these bodies are mined as ores of aluminium.

Anorthosite was prominently represented in rock samples brought back from the Moon, and is important in investigations of Mars, Venus, and meteorites.

Soil development on anorthosite edit

In the Adirondack Mountains, soils on anorthositic rock tend to be stony loamy sand with classic podzol profile development usually evident.[21] In the San Gabriel Mountains, soils on anorthosite have a dominance of 1:1 clay minerals (kaolinite and halloysite) in contrast to more mafic rock over which 2:1 clays develop.[22]

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    Anorthosite from southern Finland

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    Anorthosite from Poland

  •  

    Anorthosite from the Moon, the Apollo 15 "Genesis Rock"

See also edit

References edit

  1. ^ a b c d e f Sen, Gautam (2014). "Anorthosites and Komatiites". Petrology. Springer, Berlin, Heidelberg. pp. 261–276. doi:10.1007/978-3-642-38800-2_12. ISBN 9783642387999.
  2. ^ a b c d e f Ashwal, L. D. (2010). "The Temporality of Anorthosites". The Canadian Mineralogist. 48 (4): 711–728. doi:10.3749/canmin.48.4.711.
  3. ^ a b Ashwal, Lewis D. (1993). Anorthosites. Berlin, Heidelberg: Springer Berlin Heidelberg. ISBN 9783642774409. OCLC 851768311.
  4. ^ PSRD: The Oldest Moon Rocks
  5. ^ "This moon mission is landing in Labrador's Mistastin Lake crater". CBC. from the original on 2021-08-31.
  6. ^ a b Bowen, N.L. (1917). "The problem of the anorthosites". J. Geol. 25 (3): 209–243. Bibcode:1917JG.....25..209B. doi:10.1086/622473. S2CID 128607774.
  7. ^ Bédard (2001); Emslie et al. (1994); Xue and Morse (1994); Emslie and Stirling (1993); and Xue and Morse (1993).
  8. ^ Emslie, R.F. (1975). "Pyroxene megacrysts from anorthositic rocks: new clues to the sources and evolution of the parent magmas". Canadian Mineralogist. 13: 138.
  9. ^ a b c Bybee, G.M.; Ashwal, L.D.; Shirey, S.B.; Horan, M.; Mock, T.; Andersen, T.B. (2014). "Pyroxene megacrysts in Proterozoic anorthosites: Implications for tectonic setting, magma source and magmatic processes at the Moho". Earth and Planetary Science Letters. 389: 74–85. Bibcode:2014E&PSL.389...74B. doi:10.1016/j.epsl.2013.12.015.
  10. ^ a b c Vander Auwera, Jacqueline; Charlier, Bernard; Duchesne, Jean Clair; Bingen, Bernard; Longhi, John; Bolle, Olivier (2014). "Comment on Bybee et al. (2014): Pyroxene megacrysts in Proterozoic anorthosites: Implications for tectonic setting, magma source and magmatic processes at the Moho". Earth and Planetary Science Letters. 401: 378–380. Bibcode:2014E&PSL.401..378V. doi:10.1016/j.epsl.2014.06.031. hdl:2268/170510.
  11. ^ Longhi et al. (1993); Emslie (1975).
  12. ^ e.g. Xue and Morse, (1994).
  13. ^ Wiebe, Robert A. (1979). "Anorthositic dikes, southern Nain complex, Labrador". American Journal of Science. 279 (4): 394–410. Bibcode:1979AmJS..279..394W. doi:10.2475/ajs.279.4.394.
  14. ^ Emslie et al. (1994).
  15. ^ Bédard (2001).
  16. ^ Heiken, Vaniman & French (1991) "Lunar Sourcebook A User’s Guide to the Moon", Cambridge University Press, ISBN 0-521--33444-6, page 214.
  17. ^ "Torcivia & Neal (2022) "Unraveling the Components Within Apollo 16 Ferroan Anorthosite Suite Cataclastic Anorthosite Sample 60025: Implications for the Lunar Magma Ocean Model", Journal of Geophysical Research: Planets, volume 127, e2020JE006799. https://doi.org/10.1029/2020JE006799
  18. ^ Takeda et al. (2006) "Magnesian anorthosites and a deep crustal rock from the farside crust of the moon", Earth and Planetary Science Letters, volume 247, pp. 171–184. http://dx.doi.org/10.1016/j.epsl.2006.04.004
  19. ^ "Geologic History of the Moon", USGS Professional Paper 1348. (1987) page 140. https://pubs.usgs.gov/pp/1348/report.pdf
  20. ^ Stoffler et al.(1980) "Recommended classification and nomenclature of lunar highland rocks – a committee report" Proc.Conf. Lunar Highlands Crust. pp. 51–70.
  21. ^ https://soilseries.sc.egov.usda.gov/OSD_Docs/S/SANTANONI.html National Cooperative Soil Survey U.S.A. Official Series Description Santanoni Soil
  22. ^ Graham, R. C.; Herbert, B. E.; Ervin, J. O. (1988). "Mineralogy and Incipient Pedogenesis of Entisols in Anorthosite Terrane of the San Gabriel Mountains, California". Soil Science Society of America Journal. 52 (3): 738. Bibcode:1988SSASJ..52..738G. doi:10.2136/sssaj1988.03615995005200030026x.

Bibliography edit

  • Bédard, Jean H. (2001). "Parental magmas of the Nain Plutonic Suite anorthosites and mafic cumulates: a trace element modelling approach". Contributions to Mineralogy and Petrology. 141 (6): 747–771. Bibcode:2001CoMP..141..747B. doi:10.1007/s004100100268. S2CID 129715859.
  • Emslie, R. F. (1 May 1975). "Pyroxene megacrysts from anorthositic rocks: new clues to the sources and evolution of the parent magmas". Canadian Mineralogist. 13 (2): 138–145. ISSN 0008-4476.
  • Emslie, R. F.; Stirling, J. A. R. (1 December 1993). "Rapakivi and related granitoids of the Nain Plutonic Suite: geochemistry, mineral assemblages and fluid equilibria". Canadian Mineralogist. 31 (4): 821–847. ISSN 0008-4476.
  • Emslie, R. F.; Hamilton, M. A.; Theriault, R. J. (1994). "Petrogenesis of a Mid-Proterozoic Anorthosite-Mangerite-Charnockite-Granite (AMCG) Complex: Isotopic and Chemical Evidence from the Nain Plutonic Suite". Journal of Geology. 102 (5): 539–558. Bibcode:1994JG....102..539E. doi:10.1086/629697. S2CID 128409707.
  • Longhi, John; Fram, M. S.; Vander Auwera, J.; Montieth, J. N. (1 October 1993). "Pressure effects, kinetics, and rheology of anorthositic and related magmas". American Mineralogist. 78 (9–10): 1016–1030.
  • Norman, M. D.; Borg, L. E.; Nyquist, L. E.; Bogard, D. D. (2003). "Chronology, geochemistry, and petrology of a ferroan noritic anorthosite clast from Descartes breccia 67215: Clues to the age, origin, structure, and impact history of the lunar crust". Meteoritics and Planetary Science. 38 (4): 645–661. Bibcode:2003M&PS...38..645N. doi:10.1111/j.1945-5100.2003.tb00031.x.
  • Wood, J. A.; Dickey, J. S. Jr.; Marvin, U. B.; Powell, B. N. (1970). "Lunar Anorthosites". Science. 167 (3918): 602–604. Bibcode:1970Sci...167..602W. doi:10.1126/science.167.3918.602. PMID 17781512. S2CID 20153077.
  • Xue, S.; Morse, S. A. (1993). "Geochemistry of the Nain massif anorthosite, Labrador: Magma diversity in five intrusions". Geochimica et Cosmochimica Acta. 57 (16): 3925–3948. Bibcode:1993GeCoA..57.3925X. doi:10.1016/0016-7037(93)90344-V.
  • Xue, S.; Morse, S. A. (1994). "Chemical characteristics of plagioclase and pyroxene megacrysts and their significance to the petrogenesis of the Nain Anorthosites". Geochimica et Cosmochimica Acta. 58 (20): 4317–4331. Bibcode:1994GeCoA..58.4317X. doi:10.1016/0016-7037(94)90336-0.

External links edit

  • History of the Emplacement and Deformation of Anorthosite Bodies in the Eastern Marcy Massif, Adirondacks Mountains, New York 2011-05-14 at the Wayback Machine
  • Lunar Anorthosite Specimen 60025 Photomicrographs
  • Mercury – Evidence for Anorthosite and Basalt from mid-Infrared Spectroscopy

December 15, 2023
anorthosite, confused, with, anorthite, ɔːr, phaneritic, intrusive, igneous, rock, characterized, composition, mostly, plagioclase, feldspar, with, minimal, mafic, component, pyroxene, ilmenite, magnetite, olivine, mafic, minerals, most, commonly, present, ign. Not to be confused with Anorthite Anorthosite e ˈ n ɔːr 8 e s aɪ t is a phaneritic intrusive igneous rock characterized by its composition mostly plagioclase feldspar 90 100 with a minimal mafic component 0 10 Pyroxene ilmenite magnetite and olivine are the mafic minerals most commonly present AnorthositeIgneous rockAnorthosite from Salem district Tamil Nadu IndiaCompositionPrimaryPlagioclaseSecondaryMafic mineralsAnorthosites are of enormous geologic interest because it is still not fully understood how they form Most models involve separating plagioclase crystals based on their density Plagioclase crystals are usually less dense than magma so as plagioclase crystallizes in a magma chamber the plagioclase crystals float to the top concentrating there 1 2 3 Anorthosite on Earth can be divided into five types 3 Archean age anorthosites Proterozoic anorthosite also known as massif or massif type anorthosite the most abundant type of anorthosite on Earth 2 Layers within Layered Intrusions e g Bushveld and Stillwater intrusions Mid ocean ridge and transform fault anorthosites Anorthosite xenoliths in other rocks often granites kimberlites or basalts Of these the first two are the most common These two types have different modes of occurrence appear to be restricted to different periods in Earth s history and are thought to have had different origins 2 Lunar anorthosites constitute the light coloured areas of the Moon s surface and have been the subject of much research 4 Contents 1 Proterozoic anorthosite massifs 1 1 Age 1 2 Occurrence 1 3 Related rocks 1 4 Physical characteristics 1 5 Chemical and isotopic characteristics 1 5 1 High alumina orthopyroxene megacrysts HAOMs 1 6 Origins of Proterozoic anorthosites 2 Lunar anorthosite 3 Archean anorthosites 4 Economic value of anorthosite 4 1 Soil development on anorthosite 5 See also 6 References 7 Bibliography 8 External linksProterozoic anorthosite massifs editAge edit Proterozoic anorthosites were emplaced during the Proterozoic Eon ca 2 500 542 Ma though most were emplaced between 1 800 and 1 000 Ma 2 Occurrence edit Proterozoic anorthosites typically occur as extensive stocks or batholiths 1 The areal extent of anorthosite batholiths ranges from relatively small dozens or hundreds of square kilometers to nearly 20 000 km2 7 700 sq mi in the instance of the Nain Plutonic Suite or Mistastin crater 5 in northern Labrador Canada Major occurrences of Proterozoic anorthosite are found in the southeast U S the Appalachian Mountains e g the Honeybrook Upland of eastern Pennsylvania eastern Canada e g the Grenville Province across southern Scandinavia and eastern Europe Mapped onto the Pangaean continental configuration of that eon these occurrences are all contained in a single straight belt and must all have been emplaced intracratonally The conditions and constraints of this pattern of origin and distribution are not clear citation needed However see the Origins section below Related rocks edit Many Proterozoic anorthosites occur in spatial association with other highly distinctive contemporaneous rock types the so called anorthosite suite or anorthosite mangerite charnockite granite AMCG complex These rock types can include Mangerite a pyroxene bearing monzonite intrusive igneous rock Charnockite an orthopyroxene bearing quartz feldspar rock once thought to be intrusive igneous now recognized as metamorphic Iron rich felsic rocks including monzonite and rapakivi granite Iron rich diorite gabbro and norite Leucocratic mafic rocks such as leucotroctolite and leuconoriteThough co eval these rocks likely represent chemically independent magmas likely produced by melting of country rock into which the anorthosites intruded 2 Importantly large volumes of ultramafic rocks are not found in association with Proterozoic anorthosites 6 Physical characteristics edit nbsp Nain Anorthosite a mid Mesoproterozoic intrusion 1 29 to 1 35 billion years Labrador Polished slab blue color is labradorescence Since they are primarily composed of plagioclase feldspar most of Proterozoic anorthosites appear in outcrop to be grey or bluish Individual plagioclase crystals may be black white blue or grey and may exhibit an iridescence known as labradorescence on fresh surfaces The feldspar variety labradorite is commonly present in anorthosites Mineralogically labradorite is a compositional term for any calcium rich plagioclase feldspar containing 50 70 molecular percent anorthite An 50 70 regardless of whether it shows labradorescence The mafic mineral in Proterozoic anorthosite may be clinopyroxene orthopyroxene olivine or more rarely amphibole Oxides such as magnetite or ilmenite are also common Most anorthosite plutons are very coarse grained that is the individual plagioclase crystals and the accompanying mafic mineral are more than a few centimetres long Less commonly plagioclase crystals are megacrystic or larger than one metre long However most Proterozoic anorthosites are deformed and such large plagioclase crystals have recrystallized to form smaller crystals leaving only the outline of the larger crystals behind While many Proterozoic anorthosite plutons appear to have no large scale relict igneous structures having instead post emplacement deformational structures some do have igneous layering which may be defined by crystal size mafic content or chemical characteristics Such layering clearly has origins with a rheologically liquid state magma Chemical and isotopic characteristics edit Proterozoic anorthosites are typically gt 90 plagioclase and the plagioclase composition is commonly between An40 and An60 40 60 anorthite 1 This compositional range is intermediate and is one of the characteristics which distinguish Proterozoic anorthosites from Archean anorthosites which are typically gt An80 1 Proterozoic anorthosites often have significant mafic components in addition to plagioclase 1 These phases can include olivine pyroxene Fe Ti oxides and or apatite 2 Mafic minerals in Proterozoic anorthosites have a wide range of composition but are not generally highly magnesian citation needed The trace element chemistry of Proterozoic anorthosites and the associated rock types has been examined in some detail by researchers with the aim of arriving at a plausible genetic theory However there is still little agreement on just what the results mean for anorthosite genesis see the Origins section below A very short list of results including results for rocks thought to be related to Proterozoic anorthosites 7 clarification needed Some research has focused on neodymium Nd and strontium Sr isotopic determinations for anorthosites particularly for anorthosites of the Nain Plutonic Suite NPS Such isotopic determinations are of use in gauging the viability of prospective sources for magmas that gave rise to anorthosites Some results are detailed below in the Origins section High alumina orthopyroxene megacrysts HAOMs edit Many Proterozoic age anorthosites contain large crystals of orthopyroxene with distinctive compositions These are the so called high alumina orthopyroxene megacrysts HAOM 8 9 HAOM are distinctive because 1 they contain higher amounts of Al than typically seen in orthopyroxenes 2 they are cut by numerous thin lathes of plagioclase which may represent exsolution lamellae 10 and 3 they appear to be older than the anorthosites in which they are found 9 The origins of HAOMs are debated One possible model 9 suggests that during anorthosite formation a mantle derived melt or partially crystalline mush was injected into the lower crust and began crystallizing HAOMs would have crystallized out during this time perhaps as long as 80 120 million years The HAOM bearing melt could then have risen to the upper crust This model is supported by the fact that aluminum is more soluble in orthopyroxene at high pressure 10 11 In this model the HAOM represent lower crustal cumulates that are related to the anorthosite source magma One problem with this model is that it requires the anorthosite source magma to sit in the low crust for a considerable time To solve this some authors 10 suggest that the HAOMs may have formed in the lower crust independent of the anorthosite source magma Later the anorthosite source magma may have entrained pieces of the HAOM bearing lower crust on its way upward Other researchers consider the chemical compositions of the HAOM to be the product of rapid crystallization at moderate or low pressures 12 eliminating the need for a lower crustal origin altogether Origins of Proterozoic anorthosites edit The origins of Proterozoic anorthosites have been a subject of theoretical debate for many decades A brief synopsis of this problem is as follows The problem begins with the generation of magma the necessary precursor of any igneous rock Magma generated by small amounts of partial melting of the mantle is generally of basaltic composition Under normal conditions the composition of basaltic magma requires it to crystallize between 50 and 70 plagioclase with the bulk of the remainder of the magma crystallizing as mafic minerals However anorthosites are defined by a high plagioclase content 90 100 plagioclase and are not found in association with contemporaneous ultramafic rocks 6 This is now known as the anorthosite problem Proposed solutions to the anorthosite problem have been diverse with many of the proposals drawing on different geological subdisciplines It was suggested early in the history of anorthosite debate that a special type of magma anorthositic magma had been generated at depth and emplaced into the crust However the solidus of an anorthositic magma is too high for it to exist as a liquid for very long at normal ambient crustal temperatures so this appears to be unlikely The presence of water vapor has been shown to lower the solidus temperature of anorthositic magma to more reasonable values but most anorthosites are relatively dry It may be postulated then that water vapor be driven off by subsequent metamorphism of the anorthosite but some anorthosites are undeformed thereby invalidating the suggestion The discovery in the late 1970s of anorthositic dykes in the Nain Plutonic Suite suggested that the possibility of anorthositic magmas existing at crustal temperatures needed to be reexamined 13 However the dykes were later shown to be more complex than was originally thought In summary though liquid state processes clearly operate in some anorthosite plutons the plutons are probably not derived from anorthositic magmas Many researchers have argued that anorthosites are the products of basaltic magma and that mechanical removal of mafic minerals has occurred Since the mafic minerals are not found with the anorthosites these minerals must have been left at either a deeper level or the base of the crust A typical theory is as follows partial melting of the mantle generates a basaltic magma which does not immediately ascend into the crust Instead the basaltic magma forms a large magma chamber at the base of the crust and fractionates large amounts of mafic minerals which sink to the bottom of the chamber The co crystallizing plagioclase crystals float and eventually are emplaced into the crust as anorthosite plutons Most of the sinking mafic minerals form ultramafic cumulates which stay at the base of the crust This theory has many appealing features of which one is the capacity to explain the chemical composition of high alumina orthopyroxene megacrysts HAOM This is detailed below in the section devoted to the HAOM However on its own this hypothesis cannot coherently explain the origins of anorthosites because it does not fit with among other things some important isotopic measurements made on anorthositic rocks in the Nain Plutonic Suite The Nd and Sr isotopic data show the magma which produced the anorthosites cannot have been derived only from the mantle Instead the magma that gave rise to the Nain Plutonic Suite anorthosites must have had a significant crustal component This discovery led to a slightly more complicated version of the previous hypothesis Large amounts of basaltic magma form a magma chamber at the base of the crust and while crystallizing assimilating large amounts of crust 14 This small addendum explains both the isotopic characteristics and certain other chemical niceties of Proterozoic anorthosite However at least one researcher has cogently argued on the basis of geochemical data that the mantle s role in production of anorthosites must actually be very limited the mantle provides only the impetus heat for crustal melting and a small amount of partial melt in the form of basaltic magma Thus anorthosites are in this view derived almost entirely from lower crustal melts 15 Lunar anorthosite editOn the Moon anorthosite is the dominant rock type of the lunar highlands which covers 80 of the lunar surface Lunar anorthosite is characterized as ferroan anorthosite FAN or magnesium anorthosite MAN 16 Pristine lunar FAN is some of the oldest lunar rock and the original cumulate of the lunar magma ocean with the Mg suite forming from later impacts and plutonism 17 However debate exists on the magma ocean fractionation complicated by surface impact mixing with evidence potentially indicating MAN being older and more primitive 18 Lunar anorthosite is associated with two other rock types norite and troctolite Together they comprise the ANT suite of moon rocks 19 20 Archean anorthosites editArchean anorthosites represent the second largest anorthosite deposits on Earth Most have been dated between 3 200 and 2 800 Ma and commonly associated with basalts and or greenstone belts 1 Archean anorthosites are distinct texturally and mineralogically from Proterozoic anorthosite bodies Their most characteristic feature is the presence of equant euhedral megacrysts up to 30 cm of plagioclase surrounded by a fine grained mafic groundmass The plagioclase in these anorthosites is commonly An80 90 Economic value of anorthosite editThe primary economic value of anorthosite bodies is the titanium bearing oxide ilmenite However some Proterozoic anorthosite bodies have large amounts of labradorite which is quarried for its value as both a gemstone and a building material Archean anorthosites because they are aluminium rich have large amounts of aluminium substituting for silicon a few of these bodies are mined as ores of aluminium Anorthosite was prominently represented in rock samples brought back from the Moon and is important in investigations of Mars Venus and meteorites Soil development on anorthosite edit In the Adirondack Mountains soils on anorthositic rock tend to be stony loamy sand with classic podzol profile development usually evident 21 In the San Gabriel Mountains soils on anorthosite have a dominance of 1 1 clay minerals kaolinite and halloysite in contrast to more mafic rock over which 2 1 clays develop 22 nbsp Anorthosite from southern Finland nbsp Anorthosite from Poland nbsp Anorthosite from the Moon the Apollo 15 Genesis Rock See also editList of rock types List of rock types recognized by geologistsReferences edit a b c d e f Sen Gautam 2014 Anorthosites and Komatiites Petrology Springer Berlin Heidelberg pp 261 276 doi 10 1007 978 3 642 38800 2 12 ISBN 9783642387999 a b c d e f Ashwal L D 2010 The Temporality of Anorthosites The Canadian Mineralogist 48 4 711 728 doi 10 3749 canmin 48 4 711 a b Ashwal Lewis D 1993 Anorthosites Berlin Heidelberg Springer Berlin Heidelberg ISBN 9783642774409 OCLC 851768311 PSRD The Oldest Moon Rocks This moon mission is landing in Labrador s Mistastin Lake crater CBC Archived from the original on 2021 08 31 a b Bowen N L 1917 The problem of the anorthosites J Geol 25 3 209 243 Bibcode 1917JG 25 209B doi 10 1086 622473 S2CID 128607774 Bedard 2001 Emslie et al 1994 Xue and Morse 1994 Emslie and Stirling 1993 and Xue and Morse 1993 Emslie R F 1975 Pyroxene megacrysts from anorthositic rocks new clues to the sources and evolution of the parent magmas Canadian Mineralogist 13 138 a b c Bybee G M Ashwal L D Shirey S B Horan M Mock T Andersen T B 2014 Pyroxene megacrysts in Proterozoic anorthosites Implications for tectonic setting magma source and magmatic processes at the Moho Earth and Planetary Science Letters 389 74 85 Bibcode 2014E amp PSL 389 74B doi 10 1016 j epsl 2013 12 015 a b c Vander Auwera Jacqueline Charlier Bernard Duchesne Jean Clair Bingen Bernard Longhi John Bolle Olivier 2014 Comment on Bybee et al 2014 Pyroxene megacrysts in Proterozoic anorthosites Implications for tectonic setting magma source and magmatic processes at the Moho Earth and Planetary Science Letters 401 378 380 Bibcode 2014E amp PSL 401 378V doi 10 1016 j epsl 2014 06 031 hdl 2268 170510 Longhi et al 1993 Emslie 1975 e g Xue and Morse 1994 Wiebe Robert A 1979 Anorthositic dikes southern Nain complex Labrador American Journal of Science 279 4 394 410 Bibcode 1979AmJS 279 394W doi 10 2475 ajs 279 4 394 Emslie et al 1994 Bedard 2001 Heiken Vaniman amp French 1991 Lunar Sourcebook A User s Guide to the Moon Cambridge University Press ISBN 0 521 33444 6 page 214 Torcivia amp Neal 2022 Unraveling the Components Within Apollo 16 Ferroan Anorthosite Suite Cataclastic Anorthosite Sample 60025 Implications for the Lunar Magma Ocean Model Journal of Geophysical Research Planets volume 127 e2020JE006799 https doi org 10 1029 2020JE006799 Takeda et al 2006 Magnesian anorthosites and a deep crustal rock from the farside crust of the moon Earth and Planetary Science Letters volume 247 pp 171 184 http dx doi org 10 1016 j epsl 2006 04 004 Geologic History of the Moon USGS Professional Paper 1348 1987 page 140 https pubs usgs gov pp 1348 report pdf Stoffler et al 1980 Recommended classification and nomenclature of lunar highland rocks a committee report Proc Conf Lunar Highlands Crust pp 51 70 https soilseries sc egov usda gov OSD Docs S SANTANONI html National Cooperative Soil Survey U S A Official Series Description Santanoni Soil Graham R C Herbert B E Ervin J O 1988 Mineralogy and Incipient Pedogenesis of Entisols in Anorthosite Terrane of the San Gabriel Mountains California Soil Science Society of America Journal 52 3 738 Bibcode 1988SSASJ 52 738G doi 10 2136 sssaj1988 03615995005200030026x Bibliography editBedard Jean H 2001 Parental magmas of the Nain Plutonic Suite anorthosites and mafic cumulates a trace element modelling approach Contributions to Mineralogy and Petrology 141 6 747 771 Bibcode 2001CoMP 141 747B doi 10 1007 s004100100268 S2CID 129715859 Emslie R F 1 May 1975 Pyroxene megacrysts from anorthositic rocks new clues to the sources and evolution of the parent magmas Canadian Mineralogist 13 2 138 145 ISSN 0008 4476 Emslie R F Stirling J A R 1 December 1993 Rapakivi and related granitoids of the Nain Plutonic Suite geochemistry mineral assemblages and fluid equilibria Canadian Mineralogist 31 4 821 847 ISSN 0008 4476 Emslie R F Hamilton M A Theriault R J 1994 Petrogenesis of a Mid Proterozoic Anorthosite Mangerite Charnockite Granite AMCG Complex Isotopic and Chemical Evidence from the Nain Plutonic Suite Journal of Geology 102 5 539 558 Bibcode 1994JG 102 539E doi 10 1086 629697 S2CID 128409707 Longhi John Fram M S Vander Auwera J Montieth J N 1 October 1993 Pressure effects kinetics and rheology of anorthositic and related magmas American Mineralogist 78 9 10 1016 1030 Norman M D Borg L E Nyquist L E Bogard D D 2003 Chronology geochemistry and petrology of a ferroan noritic anorthosite clast from Descartes breccia 67215 Clues to the age origin structure and impact history of the lunar crust Meteoritics and Planetary Science 38 4 645 661 Bibcode 2003M amp PS 38 645N doi 10 1111 j 1945 5100 2003 tb00031 x Wood J A Dickey J S Jr Marvin U B Powell B N 1970 Lunar Anorthosites Science 167 3918 602 604 Bibcode 1970Sci 167 602W doi 10 1126 science 167 3918 602 PMID 17781512 S2CID 20153077 Xue S Morse S A 1993 Geochemistry of the Nain massif anorthosite Labrador Magma diversity in five intrusions Geochimica et Cosmochimica Acta 57 16 3925 3948 Bibcode 1993GeCoA 57 3925X doi 10 1016 0016 7037 93 90344 V Xue S Morse S A 1994 Chemical characteristics of plagioclase and pyroxene megacrysts and their significance to the petrogenesis of the Nain Anorthosites Geochimica et Cosmochimica Acta 58 20 4317 4331 Bibcode 1994GeCoA 58 4317X doi 10 1016 0016 7037 94 90336 0 External links editAnorthosite Complexes web archive How does anorthosite crystallize History of the Emplacement and Deformation of Anorthosite Bodies in the Eastern Marcy Massif Adirondacks Mountains New York Archived 2011 05 14 at the Wayback Machine Anorthosite Lunar Highland Rock Lunar Anorthosite Specimen 60025 Photomicrographs Mercury Evidence for Anorthosite and Basalt from mid Infrared Spectroscopy Retrieved from https en wikipedia org w index php title Anorthosite amp oldid 1177067402, wikipedia, wiki, book, 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