Jump to content

Picrite basalt: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
Refined definition according to TAS classification system.
Tags: Mobile edit Mobile web edit
 
(30 intermediate revisions by 21 users not shown)
Line 1: Line 1:
{{short description|Variety of high-magnesium basalt that is very rich in the mineral olivine}}
[[Image:Oceanite grand brule dsc03601.jpg|thumb|right|300px|Picrite basalt or oceanite from the [[Piton de la Fournaise]]]]
{{Distinguish|Pykrete}}
'''Picrite basalt''', '''picrobasalt''' is a variety of high-magnesium olivine [[basalt]] that is very rich in the mineral [[olivine]]. It is dark with yellow-green olivine [[phenocryst]]s (20 to 50%) and black to dark brown [[pyroxene]], mostly [[augite]].
{{redirects here|Picrite|the component of triple-base NQ propellants|Nitroguanidine}}
{{Use dmy dates|date=February 2020}}
[[Image:Oceanite grand brule dsc03601.jpg|thumb|Picrite basalt or oceanite from the [[Piton de la Fournaise]]]]


'''Picrite basalt''' or '''picrobasalt''' is a variety of high-magnesium olivine [[basalt]] that is very rich in the mineral [[olivine]]. It is dark with yellow-green olivine [[phenocryst]]s (20-50%) and black to dark brown [[pyroxene]], mostly [[augite]].
The olivine-rich picrite basalts that occur with the more common tholeiitic basalts of [[Kīlauea]] and other volcanoes of the [[Hawaiian Islands]] are the result of accumulation of olivine crystals either in a portion of the magma chamber or in a caldera lava lake.{{ref|Carmichael}} The compositions of these rocks are well represented by mixes of olivine and more typical tholeiitic basalt.


The olivine-rich picrite basalts that occur with the more common [[tholeiitic basalt]]s of [[Kīlauea]] and other volcanoes of the [[Hawaiian Islands]] are the result of accumulation of olivine crystals either in a portion of the [[magma chamber]] or in a caldera lava lake.{{ref|Carmichael}} The compositions of these rocks are well represented by mixes of olivine and more typical tholeiitic basalt.
The name "picrite" can also be applied to an olivine-rich alkali basalt: such picrite consists largely of [[phenocryst]]s of olivine and titanium-rich [[augite]] pyroxene with minor [[plagioclase]] set in a groundmass of augite and more sodic plagioclase and perhaps [[analcite]] and [[biotite]].


The name "picrite" can also be applied to an olivine-rich [[alkali basalt]]: such picrite consists largely of [[phenocryst]]s of olivine and titanium-rich [[augite]] pyroxene with minor [[plagioclase]] set in a groundmass of augite and more sodic plagioclase and perhaps [[analcite]] and [[biotite]].
Picrites and komatiites are somewhat similar chemically, but differ in that [[komatiite]] lavas are products of more magnesium-rich melts, and good examples exhibit the [[Spinifex (genus)|spinifex]] texture.{{ref|Kerr}} In contrast, picrites are magnesium-rich because crystals of olivine have accumulated in more normal melts by magmatic processes. Komatiites are largely restricted to the [[Archean]].


More generally the classification of fine grained rocks recognises a group known as 'picritic rocks' that are characterised by high magnesium content and low SiO2 content. They fit in the [[TAS classification]] system only at the lowest level of Si02 (41 to 43% by weight) and Na2O + K2O (up to 3% by weight). They include picrite, komatiite and meimechite.
When the term ''oceanite'' was apparently first proposed by [[Antoine Lacroix]], he used the term to apply only to basalts with more than 50% olivine content (an extremely rare occurrence). Picrite basalt is found in the [[lava]]s of [[Mauna Kea]] and [[Mauna Loa]] in [[Hawaii|Hawai{{okina}}i]]{{ref|Rhodes}}, [[Curaçao]], in the [[Piton de la Fournaise]]{{ref|Metrich}} volcano on [[Réunion Island]] and various other oceanic island volcanoes.


Picrites and komatiites are somewhat similar chemically (defined as >18% MgO), but differ in having 1 to 3% total alkalis and <1% total alkalis respectively. [[Komatiite]] lavas are products of more magnesium-rich melts, and good examples exhibit the [[Triodia (plant)|spinifex]] texture.{{ref|Kerr}} They are largely restricted to the [[Archean]]. In contrast, picrites are magnesium-rich because crystals of olivine have accumulated in more normal melts by magmatic processes.{{cn|date=November 2022}}
*Picrite basalt has been erupted in historical times from [[Mauna Loa]] during the eruptions of 1852 and 1868 (from different flanks of Mauna Loa){{ref|Wilkenson}}.

*Picrite basalt with 30% olivine commonly erupts from the [[Piton de la Fournaise]]. [http://www.the-conference.com/JConfAbs/1/88.html]
Picrite basalt is found in the [[lava]]s of [[Mauna Kea]] and [[Mauna Loa]] in [[Hawaii|Hawai{{okina}}i]]{{ref|Rhodes}}, [[Curaçao]], in the [[Piton de la Fournaise]]{{ref|Metrich}} volcano on [[Réunion Island]] and various other oceanic island volcanoes.

*Picrite basalt has erupted in historical times from [[Mauna Loa]] during the eruptions of 1852 and 1868 (from different flanks of Mauna Loa).{{ref|Wilkenson}}
*Picrite basalt with 30% olivine commonly erupts from the [[Piton de la Fournaise]].{{ref|Metrich}}

In addition to extrusive occurrences, it also occurs in minor intrusions.


==Oceanite==
==Oceanite==
Oceanite is the name of variety of picritic basalt characterized by its large amounts of olivine phenocrysts and lesser amounts of [[augite]] and by having a groundmass of olivine, plagioclase and augite. The term was coined by [[Antoine Lacroix]] in 1923.<ref>Le Maitre (ed.) 2002, p. 118.</ref>
'''Oceanite''' is a variety of picritic basalt characterized by its large amounts of olivine phenocrysts and lesser amounts of [[augite]] and by having a groundmass of olivine, plagioclase and augite. The term was coined by [[Antoine Lacroix]] in 1923 for rare basalts with more than 50% olivine.{{ref|LeMaitre}}

==Common uses==
==Common uses==
Olivine basalt is commonly used by foundries, boilermakers and boiler users to protect the area around a burner tip or to protect a floor from molten metal and other slag. Its use in this fashion is appropriate since olivine is a highly refractory, high-melting-temperature mineral.{{citation needed|date=April 2015}}
Olivine basalt is commonly used by foundries, boilermakers and boiler users to protect the area around a burner tip or to protect a floor from molten metal and other slag. Its use in this fashion is appropriate since olivine is a highly refractory, high-melting-temperature mineral.{{citation needed|date=April 2015}}
Line 21: Line 30:
==References==
==References==
{{Reflist}}
{{Reflist}}
* {{note|Carmichael}}[[Ian S. E. Carmichael|Carmichael, Ian S. E.]], Turner, Francis J., and Verhoogen, John; (1974) ''Igneous Petrology'', McGraw-Hill, pp.&nbsp;406 – 426.
* {{note|Carmichael}}{{cite book|author-link1=Ian S. E. Carmichael|last1=Carmichael|first1=Ian S. E.|last2=Turner|first2=Francis J.|last3=Verhoogen|first3=John|date=1974|title=Igneous Petrology|publisher=[[McGraw-Hill]]|pages=406–426}}
*{{note|Metrich}} Metrich, Nicole, Françoise Pineau and Marc Javoy, 1988, ''Volatiles : Mantle Source Characterization and Degassing Process for Hot Spot Volcanism - The Piton de la Fournaise (Reunion Island) Example'', http://www.the-conference.com/JConfAbs/1/88.html Retrieved 18 February 2006.
* {{note|Metrich}} {{cite journal|last1=Metrich|first1=Nicole|first2=Françoise|last2=Pineau|first3=Marc|last3=Javoy|date=1988|archive-url=https://web.archive.org/web/20051108173330/http://www.the-conference.com/JConfAbs/1/88.html|url=http://www.the-conference.com/JConfAbs/1/88.html|archive-date=8 November 2005 |title=Volatiles: Mantle Source Characterization and Degassing Process for Hot Spot Volcanism - The Piton de la Fournaise (Reunion Island) Example|url-status=dead}}
* {{note|Kerr}}Kerr, A. C. (1997) ''What is the difference between a komatiite and a picrite?'' http://www.le.ac.uk/geology/ack2/komatiite/difference.html retrieved 22 August 2005.
* {{note|Kerr}}{{cite web|last=Kerr|first=A. C.|date=1997|archive-url=https://web.archive.org/web/20040622175836/http://www.le.ac.uk/geology/ack2/komatiite/difference.html|url=http://www.le.ac.uk/geology/ack2/komatiite/difference.html |archive-date=22 June 2004 |title=What is the difference between a komatiite and a picrite?|url-status=dead}}.
* {{note|LeMaitre}} Le Maitre, L.E., ed., (2002) ''Igneous Rocks: A Classification and Glossary of Terms'' 2nd edition, Cambridge.
* {{note|LeMaitre}}{{cite book|editor-last=Le Maitre|editor-first=L. E.|date=2002|title=Igneous Rocks: A Classification and Glossary of Terms|edition=2nd|publisher=Cambridge|page=118}}
* {{note|rhodes}}Rhodes, J. M., (1995) ''The 1852 and 1868 Mauna Loa Picrite Eruptions'' Geophysical Monograph Series, vol. 92, AGU, [http://www.geo.umass.edu/xrf/picrite.html Abstract] retrieved 18 February 2006.
* {{note|rhodes}}{{cite journal|last=Rhodes|first=J. M.|date=1995|title=The 1852 and 1868 Mauna Loa Picrite Eruptions|journal=Geophysical Monograph Series|volume=92|publisher=[[American Geophysical Union]]|url=http://www.geo.umass.edu/xrf/picrite.html|access-date=18 February 2006}}
* {{note|Wilkenson}} Wilkenson, J.F.G., and Hensel, H. D., 1988, ''The petrology of some picrites from Mauna Loa and Kilauea volcanoes, Hawaii'': Contrib. Mineralogy and Petrology, v. 98, pp.&nbsp;326–345.
* {{cite journal|last1=Wilkinson|first1=J. F. G.|last2=Hensel|first2=H. D.|title=The petrology of some picrites from Mauna Loa and Kilauea volcanoes, Hawaii|journal=Contributions to Mineralogy and Petrology|date=1988|volume=98|issue=3|pages=326–345|doi=10.1007/bf00375183|bibcode=1988CoMP...98..326W|s2cid=115132181}}
* {{note|Williams}} Williams, Howel, Francis J. Turner, and Charles M. Gilbert, 1954, ''Petrography'' W. H. Freeman, pp.&nbsp;40 – 41.
* {{note|Williams}}{{cite book|last1=Williams|first1=Howel|first2=Francis J.|last2=Turner|first3=Charles M.|last3=Gilbert|date=1954|title=Petrography|publisher=[[W. H. Freeman and Company|W. H. Freeman]]|pages=40–41}}
{{Use dmy dates|date=September 2010}}


{{basalt}}
{{basalt}}
{{Rock type}}

{{DEFAULTSORT:Picrite Basalt}}
{{DEFAULTSORT:Picrite Basalt}}
[[Category:Aphanitic rocks]]
[[Category:Aphanitic rocks]]

Latest revision as of 13:00, 3 November 2024

Picrite basalt or oceanite from the Piton de la Fournaise

Picrite basalt or picrobasalt is a variety of high-magnesium olivine basalt that is very rich in the mineral olivine. It is dark with yellow-green olivine phenocrysts (20-50%) and black to dark brown pyroxene, mostly augite.

The olivine-rich picrite basalts that occur with the more common tholeiitic basalts of Kīlauea and other volcanoes of the Hawaiian Islands are the result of accumulation of olivine crystals either in a portion of the magma chamber or in a caldera lava lake.[1] The compositions of these rocks are well represented by mixes of olivine and more typical tholeiitic basalt.

The name "picrite" can also be applied to an olivine-rich alkali basalt: such picrite consists largely of phenocrysts of olivine and titanium-rich augite pyroxene with minor plagioclase set in a groundmass of augite and more sodic plagioclase and perhaps analcite and biotite.

More generally the classification of fine grained rocks recognises a group known as 'picritic rocks' that are characterised by high magnesium content and low SiO2 content. They fit in the TAS classification system only at the lowest level of Si02 (41 to 43% by weight) and Na2O + K2O (up to 3% by weight). They include picrite, komatiite and meimechite.

Picrites and komatiites are somewhat similar chemically (defined as >18% MgO), but differ in having 1 to 3% total alkalis and <1% total alkalis respectively. Komatiite lavas are products of more magnesium-rich melts, and good examples exhibit the spinifex texture.[2] They are largely restricted to the Archean. In contrast, picrites are magnesium-rich because crystals of olivine have accumulated in more normal melts by magmatic processes.[citation needed]

Picrite basalt is found in the lavas of Mauna Kea and Mauna Loa in Hawaiʻi[3], Curaçao, in the Piton de la Fournaise[4] volcano on Réunion Island and various other oceanic island volcanoes.

  • Picrite basalt has erupted in historical times from Mauna Loa during the eruptions of 1852 and 1868 (from different flanks of Mauna Loa).[5]
  • Picrite basalt with 30% olivine commonly erupts from the Piton de la Fournaise.[6]

In addition to extrusive occurrences, it also occurs in minor intrusions.

Oceanite

[edit]

Oceanite is a variety of picritic basalt characterized by its large amounts of olivine phenocrysts and lesser amounts of augite and by having a groundmass of olivine, plagioclase and augite. The term was coined by Antoine Lacroix in 1923 for rare basalts with more than 50% olivine.[7]

Common uses

[edit]

Olivine basalt is commonly used by foundries, boilermakers and boiler users to protect the area around a burner tip or to protect a floor from molten metal and other slag. Its use in this fashion is appropriate since olivine is a highly refractory, high-melting-temperature mineral.[citation needed]

References

[edit]
  • ^ Carmichael, Ian S. E.; Turner, Francis J.; Verhoogen, John (1974). Igneous Petrology. McGraw-Hill. pp. 406–426.
  • ^ Metrich, Nicole; Pineau, Françoise; Javoy, Marc (1988). "Volatiles: Mantle Source Characterization and Degassing Process for Hot Spot Volcanism - The Piton de la Fournaise (Reunion Island) Example". Archived from the original on 8 November 2005. {{cite journal}}: Cite journal requires |journal= (help)
  • ^ Kerr, A. C. (1997). "What is the difference between a komatiite and a picrite?". Archived from the original on 22 June 2004..
  • ^ Le Maitre, L. E., ed. (2002). Igneous Rocks: A Classification and Glossary of Terms (2nd ed.). Cambridge. p. 118.
  • ^ Rhodes, J. M. (1995). "The 1852 and 1868 Mauna Loa Picrite Eruptions". Geophysical Monograph Series. 92. American Geophysical Union. Retrieved 18 February 2006.
  • Wilkinson, J. F. G.; Hensel, H. D. (1988). "The petrology of some picrites from Mauna Loa and Kilauea volcanoes, Hawaii". Contributions to Mineralogy and Petrology. 98 (3): 326–345. Bibcode:1988CoMP...98..326W. doi:10.1007/bf00375183. S2CID 115132181.
  • ^ Williams, Howel; Turner, Francis J.; Gilbert, Charles M. (1954). Petrography. W. H. Freeman. pp. 40–41.