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Igneous rock

March 19, 2023

Igneous rock (derived from the Latin word ignis meaning fire), or magmatic rock, is one of the three main rock types, the others being sedimentary and metamorphic. Igneous rocks are formed through the cooling and solidification of magma or lava.

Geologic provinces of the world (USGS)

The magma can be derived from partial melts of existing rocks in either a planet's mantle or crust. Typically, the melting is caused by one or more of three processes: an increase in temperature, a decrease in pressure, or a change in composition. Solidification into rock occurs either below the surface as intrusive rocks or on the surface as extrusive rocks. Igneous rock may form with crystallization to form granular, crystalline rocks, or without crystallization to form natural glasses.

Igneous rocks occur in a wide range of geological settings: shields, platforms, orogens, basins, large igneous provinces, extended crust and oceanic crust.

Volcanic eruptions of lava are major sources of igneous rocks. (Mayon volcano in the Philippines, erupting in 2009)
Natural columns of igneous rock separated from each other by columnar joints, in Madeira

Geological significance

Igneous and metamorphic rocks make up 90–95% of the top 16 kilometres (9.9 mi) of the Earth's crust by volume.[1] Igneous rocks form about 15% of the Earth's current land surface.[note 1] Most of the Earth's oceanic crust is made of igneous rock.

Igneous rocks are also geologically important because:

  • their minerals and global chemistry give information about the composition of the lower crust or upper mantle from which their parent magma was extracted, and the temperature and pressure conditions that allowed this extraction;[3]
  • their absolute ages can be obtained from various forms of radiometric dating and can be compared to adjacent geological strata, thus permitting calibration of the geological time scale;[4]
  • their features are usually characteristic of a specific tectonic environment, allowing tectonic reconstructions (see plate tectonics);
  • in some special circumstances they host important mineral deposits (ores): for example, tungsten, tin,[5] and uranium[6] are commonly associated with granites and diorites, whereas ores of chromium and platinum are commonly associated with gabbros.[7]

Geological setting

 
Formation of igneous rock

Igneous rocks can be either intrusive (plutonic and hypabyssal) or extrusive (volcanic).

Intrusive

Main article: Intrusive rock
 
Basic types of intrusions:

Intrusive igneous rocks make up the majority of igneous rocks and are formed from magma that cools and solidifies within the crust of a planet. Bodies of intrusive rock are known as intrusions and are surrounded by pre-existing rock (called country rock). The country rock is an excellent thermal insulator, so the magma cools slowly, and intrusive rocks are coarse-grained (phaneritic). The mineral grains in such rocks can generally be identified with the naked eye. Intrusions can be classified according to the shape and size of the intrusive body and its relation to the bedding of the country rock into which it intrudes. Typical intrusive bodies are batholiths, stocks, laccoliths, sills and dikes. Common intrusive rocks are granite, gabbro, or diorite.

The central cores of major mountain ranges consist of intrusive igneous rocks. When exposed by erosion, these cores (called batholiths) may occupy huge areas of the Earth's surface.

Intrusive igneous rocks that form at depth within the crust are termed plutonic (or abyssal) rocks and are usually coarse-grained. Intrusive igneous rocks that form near the surface are termed subvolcanic or hypabyssal rocks and they are usually much finer-grained, often resembling volcanic rock.[8] Hypabyssal rocks are less common than plutonic or volcanic rocks and often form dikes, sills, laccoliths, lopoliths, or phacoliths.

Extrusive

Main article: Extrusive rock
 
Extrusive igneous rock is made from lava released by volcanoes
 
Sample of basalt (an extrusive igneous rock), found in Massachusetts

Extrusive igneous rock, also known as volcanic rock, is formed by the cooling of molten magma on the earth's surface. The magma, which is brought to the surface through fissures or volcanic eruptions, rapidly solidifies. Hence such rocks are fine-grained (aphanitic) or even glassy. Basalt is the most common extrusive igneous rock[9] and forms lava flows, lava sheets and lava plateaus. Some kinds of basalt solidify to form long polygonal columns. The Giant's Causeway in Antrim, Northern Ireland is an example.

The molten rock, which typically contains suspended crystals and dissolved gases, is called magma.[10] It rises because it is less dense than the rock from which it was extracted.[11] When magma reaches the surface, it is called lava.[12] Eruptions of volcanoes into air are termed subaerial, whereas those occurring underneath the ocean are termed submarine. Black smokers and mid-ocean ridge basalt are examples of submarine volcanic activity.[13]

The volume of extrusive rock erupted annually by volcanoes varies with plate tectonic setting. Extrusive rock is produced in the following proportions:[14]

The behaviour of lava depends upon its viscosity, which is determined by temperature, composition, and crystal content. High-temperature magma, most of which is basaltic in composition, behaves in a manner similar to thick oil and, as it cools, treacle. Long, thin basalt flows with pahoehoe surfaces are common. Intermediate composition magma, such as andesite, tends to form cinder cones of intermingled ash, tuff and lava, and may have a viscosity similar to thick, cold molasses or even rubber when erupted. Felsic magma, such as rhyolite, is usually erupted at low temperature and is up to 10,000 times as viscous as basalt. Volcanoes with rhyolitic magma commonly erupt explosively, and rhyolitic lava flows are typically of limited extent and have steep margins because the magma is so viscous.[15]

Felsic and intermediate magmas that erupt often do so violently, with explosions driven by the release of dissolved gases—typically water vapour, but also carbon dioxide. Explosively erupted pyroclastic material is called tephra and includes tuff, agglomerate and ignimbrite. Fine volcanic ash is also erupted and forms ash tuff deposits, which can often cover vast areas.[16]

Because volcanic rocks are mostly fine-grained or glassy, it is much more difficult to distinguish between the different types of extrusive igneous rocks than between different types of intrusive igneous rocks. Generally, the mineral constituents of fine-grained extrusive igneous rocks can only be determined by examination of thin sections of the rock under a microscope, so only an approximate classification can usually be made in the field. Although classification by mineral makeup is preferred by the IUGS, this is often impractical, and chemical classification is done instead using the TAS classification.[17]

Classification

Further information: List of rock types
 
Close-up of granite (an intrusive igneous rock) exposed in Chennai, India

Igneous rocks are classified according to mode of occurrence, texture, mineralogy, chemical composition, and the geometry of the igneous body.

The classification of the many types of igneous rocks can provide important information about the conditions under which they formed. Two important variables used for the classification of igneous rocks are particle size, which largely depends on the cooling history, and the mineral composition of the rock. Feldspars, quartz or feldspathoids, olivines, pyroxenes, amphiboles, and micas are all important minerals in the formation of almost all igneous rocks, and they are basic to the classification of these rocks. All other minerals present are regarded as nonessential in almost all igneous rocks and are called accessory minerals. Types of igneous rocks with other essential minerals are very rare, but include carbonatites, which contain essential carbonates.[17]

In a simplified classification, igneous rock types are separated on the basis of the type of feldspar present, the presence or absence of quartz, and in rocks with no feldspar or quartz, the type of iron or magnesium minerals present. Rocks containing quartz (silica in composition) are silica-oversaturated. Rocks with feldspathoids are silica-undersaturated, because feldspathoids cannot coexist in a stable association with quartz.[citation needed]

Igneous rocks that have crystals large enough to be seen by the naked eye are called phaneritic; those with crystals too small to be seen are called aphanitic. Generally speaking, phaneritic implies an intrusive origin; aphanitic an extrusive one.[citation needed]

An igneous rock with larger, clearly discernible crystals embedded in a finer-grained matrix is termed porphyry. Porphyritic texture develops when some of the crystals grow to considerable size before the main mass of the magma crystallizes as finer-grained, uniform material.[citation needed]

Igneous rocks are classified on the basis of texture and composition. Texture refers to the size, shape, and arrangement of the mineral grains or crystals of which the rock is composed.[citation needed]

Texture

 
Gabbro specimen showing phaneritic texture, from Rock Creek Canyon, eastern Sierra Nevada, California
Main article: Rock microstructure

Texture is an important criterion for the naming of volcanic rocks. The texture of volcanic rocks, including the size, shape, orientation, and distribution of mineral grains and the intergrain relationships, will determine whether the rock is termed a tuff, a pyroclastic lava or a simple lava. However, the texture is only a subordinate part of classifying volcanic rocks, as most often there needs to be chemical information gleaned from rocks with extremely fine-grained groundmass or from airfall tuffs, which may be formed from volcanic ash.[citation needed]

Textural criteria are less critical in classifying intrusive rocks where the majority of minerals will be visible to the naked eye or at least using a hand lens, magnifying glass or microscope. Plutonic rocks also tend to be less texturally varied and less prone to showing distinctive structural fabrics. Textural terms can be used to differentiate different intrusive phases of large plutons, for instance porphyritic margins to large intrusive bodies, porphyry stocks and subvolcanic dikes. Mineralogical classification is most often used to classify plutonic rocks. Chemical classifications are preferred to classify volcanic rocks, with phenocryst species used as a prefix, e.g. "olivine-bearing picrite" or "orthoclase-phyric rhyolite".[citation needed]

 
Basic classification scheme for igneous rocks based on their mineral composition. If the approximate volume fractions of minerals in the rock are known, the rock name and silica content can be read off the diagram. This is not an exact method, because the classification of igneous rocks also depends on other components, yet in most cases it is a good first guess.

Mineralogical classification

The IUGS recommends classifying igneous rocks by their mineral composition whenever possible. This is straightforward for coarse-grained intrusive igneous rock, but may require examination of thin sections under a microscope for fine-grained volcanic rock, and may be impossible for glassy volcanic rock. The rock must then be classified chemically.[18]

Mineralogical classification of an intrusive rock begins by determining if the rock is ultramafic, a carbonatite, or a lamprophyre. An ultramafic rock contains more than 90% of iron- and magnesium-rich minerals such as hornblende, pyroxene, or olivine, and such rocks have their own classification scheme. Likewise, rocks containing more than 50% carbonate minerals are classified as carbonatites, while lamprophyres are rare ultrapotassic rocks. Both are further classified based on detailed mineralogy.[19]

In the great majority of cases, the rock has a more typical mineral composition, with significant quartz, feldspars, or feldspathoids. Classification is based on the percentages of quartz, alkali feldspar, plagioclase, and feldspathoid out of the total fraction of the rock composed of these minerals, ignoring all other minerals present. These percentages place the rock somewhere on the QAPF diagram, which often immediately determines the rock type. In a few cases, such as the diorite-gabbro-anorthite field, additional mineralogical criteria must be applied to determine the final classification.[19]

Where the mineralogy of an volcanic rock can be determined, it is classified using the same procedure, but with a modified QAPF diagram whose fields correspond to volcanic rock types.[19]

Chemical classification and petrology

 
Total alkali versus silica classification scheme (TAS) as proposed in Le Maitre's 2002 Igneous Rocks – A classification and glossary of terms[20] Blue area is roughly where alkaline rocks plot; yellow area is where subalkaline rocks plot.

When it is impractical to classify a volcanic rock by mineralogy, the rock must be classified chemically.

There are relatively few minerals that are important in the formation of common igneous rocks, because the magma from which the minerals crystallize is rich in only certain elements: silicon, oxygen, aluminium, sodium, potassium, calcium, iron, and magnesium. These are the elements that combine to form the silicate minerals, which account for over ninety percent of all igneous rocks. The chemistry of igneous rocks is expressed differently for major and minor elements and for trace elements. Contents of major and minor elements are conventionally expressed as weight percent oxides (e.g., 51% SiO2, and 1.50% TiO2). Abundances of trace elements are conventionally expressed as parts per million by weight (e.g., 420 ppm Ni, and 5.1 ppm Sm). The term "trace element" is typically used for elements present in most rocks at abundances less than 100 ppm or so, but some trace elements may be present in some rocks at abundances exceeding 1,000 ppm. The diversity of rock compositions has been defined by a huge mass of analytical data—over 230,000 rock analyses can be accessed on the web through a site sponsored by the U. S. National Science Foundation (see the External Link to EarthChem).[citation needed]

The single most important component is silica, SiO2, whether occurring as quartz or combined with other oxides as feldspars or other minerals. Both intrusive and volcanic rocks are grouped chemically by total silica content into broad categories.

  • Felsic rocks have the highest content of silica, and are predominantly composed of the felsic minerals quartz and feldspar. These rocks (granite, rhyolite) are usually light coloured, and have a relatively low density.
  • Intermediate rocks have a moderate content of silica, and are predominantly composed of feldspars. These rocks (diorite, andesite) are typically darker in colour than felsic rocks and somewhat more dense.
  • Mafic rocks have a relatively low silica content and are composed mostly of pyroxenes, olivines and calcic plagioclase. These rocks (basalt, gabbro) are usually dark coloured, and have a higher density than felsic rocks.
  • Ultramafic rock is very low in silica, with more than 90% of mafic minerals (komatiite, dunite).

This classification is summarized in the following table:

Composition
Mode of occurrence Felsic
(>63% SiO2) 		Intermediate
(52% to 63% SiO2) 		Mafic
(45% to 52% SiO2) 		Ultramafic
(<45% SiO2)
Intrusive Granite Diorite Gabbro Peridotite
Extrusive Rhyolite Andesite Basalt Komatiite

The percentage of alkali metal oxides (Na2O plus K2O) is second only to silica in its importance for chemically classifying volcanic rock. The silica and alkali metal oxide percentages are used to place volcanic rock on the TAS diagram, which is sufficient to immediately classify most volcanic rocks. Rocks in some fields, such as the trachyandesite field, are further classified by the ratio of potassium to sodium (so that potassic trachyandesites are latites and sodic trachyandesites are benmoreites). Some of the more mafic fields are further subdivided or defined by normative mineralogy, in which an idealized mineral composition is calculated for the rock based on its chemical composition. For example, basanite is distinguished from tephrite by having a high normative olivine content.

Other refinements to the basic TAS classification include:

In older terminology, silica oversaturated rocks were called silicic or acidic where the SiO2 was greater than 66% and the family term quartzolite was applied to the most silicic. A normative feldspathoid classifies a rock as silica-undersaturated; an example is nephelinite.

 
AFM ternary diagram showing the relative proportions of Na2O + K2O (A for Alkali earth metals), FeO + Fe2O3 (F), and MgO (M) with arrows showing the path of chemical variation in tholeiitic and calc-alkaline series magmas

Magmas are further divided into three series:

The alkaline series is distinguishable from the other two on the TAS diagram, being higher in total alkali oxides for a given silica content, but the tholeiitic and calc-alkaline series occupy approximately the same part of the TAS diagram. They are distinguished by comparing total alkali with iron and magnesium content.[22]

These three magma series occur in a range of plate tectonic settings. Tholeiitic magma series rocks are found, for example, at mid-ocean ridges, back-arc basins, oceanic islands formed by hotspots, island arcs and continental large igneous provinces.[23]

All three series are found in relatively close proximity to each other at subduction zones where their distribution is related to depth and the age of the subduction zone. The tholeiitic magma series is well represented above young subduction zones formed by magma from relatively shallow depth. The calc-alkaline and alkaline series are seen in mature subduction zones, and are related to magma of greater depths. Andesite and basaltic andesite are the most abundant volcanic rock in island arc which is indicative of the calc-alkaline magmas. Some island arcs have distributed volcanic series as can be seen in the Japanese island arc system where the volcanic rocks change from tholeiite—calc-alkaline—alkaline with increasing distance from the trench.[24][25]

History of classification

Some igneous rock names date to before the modern era of geology. For example, basalt as a description of a particular composition of lava-derived rock dates to Georgius Agricola in 1546 in his work De Natura Fossilium.[26] The word granite goes back at least to the 1640s and is derived either from French granit or Italian granito, meaning simply "granulate rock".[27] The term rhyolite was introduced in 1860 by the German traveler and geologist Ferdinand von Richthofen[28][29][30] The naming of new rock types accelerated in the 19th century and peaked in the early 20th century.[31]

Much of the early classification of igneous rocks was based on the geological age and occurrence of the rocks. However, in 1902, the American petrologists Charles Whitman Cross, Joseph P. Iddings, Louis V. Pirsson, and Henry Stephens Washington proposed that all existing classifications of igneous rocks should be discarded and replaced by a "quantitative" classification based on chemical analysis. They showed how vague, and often unscientific, much of the existing terminology was and argued that as the chemical composition of an igneous rock was its most fundamental characteristic, it should be elevated to prime position.[32][33]

Geological occurrence, structure, mineralogical constitution—the hitherto accepted criteria for the discrimination of rock species—were relegated to the background. The completed rock analysis is first to be interpreted in terms of the rock-forming minerals which might be expected to be formed when the magma crystallizes, e.g., quartz feldspars, olivine, akermannite, Feldspathoids, magnetite, corundum, and so on, and the rocks are divided into groups strictly according to the relative proportion of these minerals to one another.[32] This new classification scheme created a sensation, but was criticized for its lack of utility in fieldwork, and the classification scheme was abandoned by the 1960s. However, the concept of normative mineralogy has endured, and the work of Cross and his coinvestigators inspired a flurry of new classification schemes.[34]

Among these was the classification scheme of M.A. Peacock, which divided igneous rocks into four series: the alkalic, the alkali-calcic, the calc-alkali, and the calcic series.[35] His definition of the alkali series, and the term calc-alkali, continue in use as part of the widely used[36] Irvine-Barager classification,[37] along with W.Q. Kennedy's tholeiitic series.[38]

By 1958, there were some 12 separate classification schemes and at least 1637 rock type names in use. In that year, Albert Streckeisen wrote a review article on igneous rock classification that ultimately led to the formation of the IUGG Subcommission of the Systematics of Igneous Rocks. By 1989 a single system of classification had been agreed upon, which was further revised in 2005. The number of recommended rock names was reduced to 316. These included a number of new names promulgated by the Subcommission.[31]

Origin of magmas

The Earth's crust averages about 35 kilometres (22 mi) thick under the continents, but averages only some 7–10 kilometres (4.3–6.2 mi) beneath the oceans. The continental crust is composed primarily of sedimentary rocks resting on a crystalline basement formed of a great variety of metamorphic and igneous rocks, including granulite and granite. Oceanic crust is composed primarily of basalt and gabbro. Both continental and oceanic crust rest on peridotite of the mantle.[citation needed]

Rocks may melt in response to a decrease in pressure, to a change in composition (such as an addition of water), to an increase in temperature, or to a combination of these processes.[citation needed]

Other mechanisms, such as melting from a meteorite impact, are less important today, but impacts during the accretion of the Earth led to extensive melting, and the outer several hundred kilometers of our early Earth was probably an ocean of magma. Impacts of large meteorites in the last few hundred million years have been proposed as one mechanism responsible for the extensive basalt magmatism of several large igneous provinces.[citation needed]

Decompression

Decompression melting occurs because of a decrease in pressure.[39]

The solidus temperatures of most rocks (the temperatures below which they are completely solid) increase with increasing pressure in the absence of water. Peridotite at depth in the Earth's mantle may be hotter than its solidus temperature at some shallower level. If such rock rises during the convection of solid mantle, it will cool slightly as it expands in an adiabatic process, but the cooling is only about 0.3 °C per kilometer. Experimental studies of appropriate peridotite samples document that the solidus temperatures increase by 3 °C to 4 °C per kilometer. If the rock rises far enough, it will begin to melt. Melt droplets can coalesce into larger volumes and be intruded upwards. This process of melting from the upward movement of solid mantle is critical in the evolution of the Earth.[citation needed]

Decompression melting creates the ocean crust at mid-ocean ridges. It also causes volcanism in intraplate regions, such as Europe, Africa and the Pacific sea floor. There, it is variously attributed either to the rise of mantle plumes (the "Plume hypothesis") or to intraplate extension (the "Plate hypothesis").[40]

Effects of water and carbon dioxide

The change of rock composition most responsible for the creation of magma is the addition of water. Water lowers the solidus temperature of rocks at a given pressure. For example, at a depth of about 100 kilometers, peridotite begins to melt near 800 °C in the presence of excess water, but near or above about 1,500 °C in the absence of water.[41] Water is driven out of the oceanic lithosphere in subduction zones, and it causes melting in the overlying mantle. Hydrous magmas composed of basalt and andesite are produced directly and indirectly as results of dehydration during the subduction process. Such magmas, and those derived from them, build up island arcs such as those in the Pacific Ring of Fire. These magmas form rocks of the calc-alkaline series, an important part of the continental crust.[citation needed]

The addition of carbon dioxide is relatively a much less important cause of magma formation than the addition of water, but genesis of some silica-undersaturated magmas has been attributed to the dominance of carbon dioxide over water in their mantle source regions. In the presence of carbon dioxide, experiments document that the peridotite solidus temperature decreases by about 200 °C in a narrow pressure interval at pressures corresponding to a depth of about 70 km. At greater depths, carbon dioxide can have more effect: at depths to about 200 km, the temperatures of initial melting of a carbonated peridotite composition were determined to be 450 °C to 600 °C lower than for the same composition with no carbon dioxide.[42] Magmas of rock types such as nephelinite, carbonatite, and kimberlite are among those that may be generated following an influx of carbon dioxide into mantle at depths greater than about 70 km.[citation needed]

Temperature increase

Increase in temperature is the most typical mechanism for formation of magma within continental crust. Such temperature increases can occur because of the upward intrusion of magma from the mantle. Temperatures can also exceed the solidus of a crustal rock in continental crust thickened by compression at a plate boundary. The plate boundary between the Indian and Asian continental masses provides a well-studied example, as the Tibetan Plateau just north of the boundary has crust about 80 kilometers thick, roughly twice the thickness of normal continental crust. Studies of electrical resistivity deduced from magnetotelluric data have detected a layer that appears to contain silicate melt and that stretches for at least 1,000 kilometers within the middle crust along the southern margin of the Tibetan Plateau.[43] Granite and rhyolite are types of igneous rock commonly interpreted as products of the melting of continental crust because of increases in temperature. Temperature increases also may contribute to the melting of lithosphere dragged down in a subduction zone.[citation needed]

Magma evolution

 
Schematic diagrams showing the principles behind fractional crystallisation in a magma. While cooling, the magma evolves in composition because different minerals crystallize from the melt. 1: olivine crystallizes; 2: olivine and pyroxene crystallize; 3: pyroxene and plagioclase crystallize; 4: plagioclase crystallizes. At the bottom of the magma reservoir, a cumulate rock forms.
Main article: Igneous differentiation

Most magmas are fully melted only for small parts of their histories. More typically, they are mixes of melt and crystals, and sometimes also of gas bubbles. Melt, crystals, and bubbles usually have different densities, and so they can separate as magmas evolve.

As magma cools, minerals typically crystallize from the melt at different temperatures (fractional crystallization). As minerals crystallize, the composition of the residual melt typically changes. If crystals separate from the melt, then the residual melt will differ in composition from the parent magma. For instance, a magma of gabbroic composition can produce a residual melt of granitic composition if early formed crystals are separated from the magma. Gabbro may have a liquidus temperature near 1,200 °C, and the derivative granite-composition melt may have a liquidus temperature as low as about 700 °C. Incompatible elements are concentrated in the last residues of magma during fractional crystallization and in the first melts produced during partial melting: either process can form the magma that crystallizes to pegmatite, a rock type commonly enriched in incompatible elements. Bowen's reaction series is important for understanding the idealised sequence of fractional crystallisation of a magma. Clinopyroxene thermobarometry is used to determine temperature and pressure conditions at which magma differentiation occurred for specific igneous rocks.[citation needed]

Magma composition can be determined by processes other than partial melting and fractional crystallization. For instance, magmas commonly interact with rocks they intrude, both by melting those rocks and by reacting with them. Magmas of different compositions can mix with one another. In rare cases, melts can separate into two immiscible melts of contrasting compositions.[citation needed]

Etymology

  • The word igneous rock means composed of fire. and is derived from the Latin root words of igni-,[44] meaning fire, and -eous[45] meaning composed of.
  • The word volcanic rock is derived from the Latin root words of Vulcan,[46] the Roman the god of fire, and -ic,[47] meaning having some characteristics of.
  • The word plutonic rock, another name for intrusive igneous rock, is derived from the Latin root words of Pluto,[48] the Roman god of the underworld, and -ic,[49] meaning having some characteristics of.

Gallery

  •  

    Kanaga volcano in the Aleutian Islands with a 1906 lava flow in the foreground

  •  

    A "skylight" hole, about 6 m (20 ft) across, in a solidified lava crust reveals molten lava below (flowing towards the top right) in an eruption of Kīlauea in Hawaii

  •  

    Devils Tower, an eroded laccolith in the Black Hills of Wyoming

  •  

    A cascade of molten lava flowing into Aloi Crater during the 1969-1971 Mauna Ulu eruption of Kilauea volcano

  •  

    Columnar jointing in the Alcantara Gorge, Sicily

  •  

    A laccolith of granite (light-coloured) that was intruded into older sedimentary rocks (dark-coloured) at Cuernos del Paine, Torres del Paine National Park, Chile

  •  

    An igneous intrusion cut by a pegmatite dike, which in turn is cut by a dolerite dike

See also

  • List of rock types – List of rock types recognized by geologists
  • Metamorphic rock – Rock that was subjected to heat and pressure
  • Migmatite – Mixture of metamorphic rock and igneous rock
  • Petrology – Branch of geology that studies the formation, composition, distribution and structure of rocks
  • Sedimentary rock – Rock formed by the deposition and subsequent cementation of material

Notes

  1. ^ 15% is the arithmetic sum of the area for intrusive plutonic rock (7%) plus the area for extrusive volcanic rock (8%).[2]

References

  1. ^ Prothero, Donald R.; Schwab, Fred (2004). Sedimentary geology : an introduction to sedimentary rocks and stratigraphy (2nd ed.). New York: Freeman. p. 12. ISBN 978-0-7167-3905-0.
  2. ^ Wilkinson, Bruce H.; McElroy, Brandon J.; Kesler, Stephen E.; Peters, Shanan E.; Rothman, Edward D. (2008). "Global geologic maps are tectonic speedometers—Rates of rock cycling from area-age frequencies". Geological Society of America Bulletin. 121 (5–6): 760–779. Bibcode:2009GSAB..121..760W. doi:10.1130/B26457.1.
  3. ^ Philpotts, Anthony R.; Ague, Jay J. (2009). Principles of igneous and metamorphic petrology (2nd ed.). Cambridge, UK: Cambridge University Press. pp. 356–361. ISBN 978-0-521-88006-0.
  4. ^ Philpott & Ague 2009, p. 295.
  5. ^ Heinrich, Christoph A. (1 May 1990). "The chemistry of hydrothermal tin(-tungsten) ore deposition". Economic Geology. 85 (3): 457–481. doi:10.2113/gsecongeo.85.3.457.
  6. ^ Plant, J.A.; Saunders, A.D. (1999). "Uranium ore deposits". Uranium: Mineralogy, geochemistry and the Environment. Vol. 38. pp. 272–319. ISBN 978-1-5015-0919-3. Retrieved 13 February 2021.
  7. ^ Philpotts & Ague 2009, p. 96, 387–388.
  8. ^ Philpotts & Ague 2009, p. 139.
  9. ^ Philpotts & Ague 2009, pp. 52–59.
  10. ^ Philpotts & Ague 2009, pp. 19–26.
  11. ^ Philpotts & Ague 2009, pp. 28–35.
  12. ^ Schmincke, Hans-Ulrich (2003). Volcanism. Berlin: Springer. p. 295. doi:10.1007/978-3-642-18952-4. ISBN 978-3-540-43650-8. S2CID 220886233.
  13. ^ Philpotts & Ague 2009, pp. 365–374.
  14. ^ Fisher, Richard V.; Schmincke, H.-U. (1984). Pyroclastic rocks. Berlin: Springer-Verlag. p. 5. ISBN 3-540-12756-9.
  15. ^ Philpotts & Ague 2009, pp. 23–26, 59–73.
  16. ^ Philpotts & Ague 2009, pp. 73–77.
  17. ^ a b Philpotts & Ague 2009, pp. 139–143.
  18. ^ Le Bas, M. J.; Streckeisen, A. L. (1991). "The IUGS systematics of igneous rocks". Journal of the Geological Society. 148 (5): 825–833. Bibcode:1991JGSoc.148..825L. CiteSeerX 10.1.1.692.4446. doi:10.1144/gsjgs.148.5.0825. S2CID 28548230.
  19. ^ a b c Le Bas & Streckeisen 1991.
  20. ^ Shanks III, W.C. Pat; Koski, Randolph A.; Mosier, Dan L.; Schulz, Klaus J.; Morgan, Lisa A.; Slack, John F.; Ridley, W. Ian; Dusel-Bacon, Cynthia; Seal II, Robert R.; Piatak, Nadine M. (2012). Shanks, W.C. Pat; Thurston, Roland (eds.). "Volcanogenic massive sulfide occurrence model: Chapter C in Mineral deposit models for resource assessment". U.S. Geological Survey Scientific Investigations Report. Scientific Investigations Report. 2010-5070-C: 237. doi:10.3133/sir20105070C.
  21. ^ a b Blatt, Harvey; Tracy, Robert J. (1996). Petrology : igneous, sedimentary, and metamorphic (2nd ed.). New York: W.H. Freeman. p. 185. ISBN 0-7167-2438-3.
  22. ^ Philpotts & Ague 2009, pp. 143–146.
  23. ^ (PDF). University of Washington. Archived from the original (PDF) on 1 August 2020. Retrieved 2 December 2020.
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External links

 
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March 19, 2023
igneous, rock, derived, from, latin, word, ignis, meaning, fire, magmatic, rock, three, main, rock, types, others, being, sedimentary, metamorphic, formed, through, cooling, solidification, magma, lava, geologic, provinces, world, usgs, shield, platform, oroge. Igneous rock derived from the Latin word ignis meaning fire or magmatic rock is one of the three main rock types the others being sedimentary and metamorphic Igneous rocks are formed through the cooling and solidification of magma or lava Geologic provinces of the world USGS Shield Platform Orogen Basin Large igneous province Extended crust Oceanic crust 0 20 Ma 20 65 Ma gt 65 Ma The magma can be derived from partial melts of existing rocks in either a planet s mantle or crust Typically the melting is caused by one or more of three processes an increase in temperature a decrease in pressure or a change in composition Solidification into rock occurs either below the surface as intrusive rocks or on the surface as extrusive rocks Igneous rock may form with crystallization to form granular crystalline rocks or without crystallization to form natural glasses Igneous rocks occur in a wide range of geological settings shields platforms orogens basins large igneous provinces extended crust and oceanic crust Volcanic eruptions of lava are major sources of igneous rocks Mayon volcano in the Philippines erupting in 2009 Natural columns of igneous rock separated from each other by columnar joints in Madeira Contents 1 Geological significance 2 Geological setting 2 1 Intrusive 2 2 Extrusive 3 Classification 3 1 Texture 3 2 Mineralogical classification 3 3 Chemical classification and petrology 3 4 History of classification 4 Origin of magmas 4 1 Decompression 4 2 Effects of water and carbon dioxide 4 3 Temperature increase 4 4 Magma evolution 5 Etymology 6 Gallery 7 See also 8 Notes 9 References 10 External linksGeological significanceIgneous and metamorphic rocks make up 90 95 of the top 16 kilometres 9 9 mi of the Earth s crust by volume 1 Igneous rocks form about 15 of the Earth s current land surface note 1 Most of the Earth s oceanic crust is made of igneous rock Igneous rocks are also geologically important because their minerals and global chemistry give information about the composition of the lower crust or upper mantle from which their parent magma was extracted and the temperature and pressure conditions that allowed this extraction 3 their absolute ages can be obtained from various forms of radiometric dating and can be compared to adjacent geological strata thus permitting calibration of the geological time scale 4 their features are usually characteristic of a specific tectonic environment allowing tectonic reconstructions see plate tectonics in some special circumstances they host important mineral deposits ores for example tungsten tin 5 and uranium 6 are commonly associated with granites and diorites whereas ores of chromium and platinum are commonly associated with gabbros 7 Geological setting Formation of igneous rock Igneous rocks can be either intrusive plutonic and hypabyssal or extrusive volcanic Intrusive Main article Intrusive rock Basic types of intrusions LaccolithSmall dikeBatholithDikeSillVolcanic neck pipeLopolith Intrusive igneous rocks make up the majority of igneous rocks and are formed from magma that cools and solidifies within the crust of a planet Bodies of intrusive rock are known as intrusions and are surrounded by pre existing rock called country rock The country rock is an excellent thermal insulator so the magma cools slowly and intrusive rocks are coarse grained phaneritic The mineral grains in such rocks can generally be identified with the naked eye Intrusions can be classified according to the shape and size of the intrusive body and its relation to the bedding of the country rock into which it intrudes Typical intrusive bodies are batholiths stocks laccoliths sills and dikes Common intrusive rocks are granite gabbro or diorite The central cores of major mountain ranges consist of intrusive igneous rocks When exposed by erosion these cores called batholiths may occupy huge areas of the Earth s surface Intrusive igneous rocks that form at depth within the crust are termed plutonic or abyssal rocks and are usually coarse grained Intrusive igneous rocks that form near the surface are termed subvolcanic or hypabyssal rocks and they are usually much finer grained often resembling volcanic rock 8 Hypabyssal rocks are less common than plutonic or volcanic rocks and often form dikes sills laccoliths lopoliths or phacoliths Extrusive Main article Extrusive rock Extrusive igneous rock is made from lava released by volcanoes Sample of basalt an extrusive igneous rock found in Massachusetts Extrusive igneous rock also known as volcanic rock is formed by the cooling of molten magma on the earth s surface The magma which is brought to the surface through fissures or volcanic eruptions rapidly solidifies Hence such rocks are fine grained aphanitic or even glassy Basalt is the most common extrusive igneous rock 9 and forms lava flows lava sheets and lava plateaus Some kinds of basalt solidify to form long polygonal columns The Giant s Causeway in Antrim Northern Ireland is an example The molten rock which typically contains suspended crystals and dissolved gases is called magma 10 It rises because it is less dense than the rock from which it was extracted 11 When magma reaches the surface it is called lava 12 Eruptions of volcanoes into air are termed subaerial whereas those occurring underneath the ocean are termed submarine Black smokers and mid ocean ridge basalt are examples of submarine volcanic activity 13 The volume of extrusive rock erupted annually by volcanoes varies with plate tectonic setting Extrusive rock is produced in the following proportions 14 divergent boundary 73 convergent boundary subduction zone 15 hotspot 12 The behaviour of lava depends upon its viscosity which is determined by temperature composition and crystal content High temperature magma most of which is basaltic in composition behaves in a manner similar to thick oil and as it cools treacle Long thin basalt flows with pahoehoe surfaces are common Intermediate composition magma such as andesite tends to form cinder cones of intermingled ash tuff and lava and may have a viscosity similar to thick cold molasses or even rubber when erupted Felsic magma such as rhyolite is usually erupted at low temperature and is up to 10 000 times as viscous as basalt Volcanoes with rhyolitic magma commonly erupt explosively and rhyolitic lava flows are typically of limited extent and have steep margins because the magma is so viscous 15 Felsic and intermediate magmas that erupt often do so violently with explosions driven by the release of dissolved gases typically water vapour but also carbon dioxide Explosively erupted pyroclastic material is called tephra and includes tuff agglomerate and ignimbrite Fine volcanic ash is also erupted and forms ash tuff deposits which can often cover vast areas 16 Because volcanic rocks are mostly fine grained or glassy it is much more difficult to distinguish between the different types of extrusive igneous rocks than between different types of intrusive igneous rocks Generally the mineral constituents of fine grained extrusive igneous rocks can only be determined by examination of thin sections of the rock under a microscope so only an approximate classification can usually be made in the field Although classification by mineral makeup is preferred by the IUGS this is often impractical and chemical classification is done instead using the TAS classification 17 ClassificationFurther information List of rock types Close up of granite an intrusive igneous rock exposed in Chennai India Igneous rocks are classified according to mode of occurrence texture mineralogy chemical composition and the geometry of the igneous body The classification of the many types of igneous rocks can provide important information about the conditions under which they formed Two important variables used for the classification of igneous rocks are particle size which largely depends on the cooling history and the mineral composition of the rock Feldspars quartz or feldspathoids olivines pyroxenes amphiboles and micas are all important minerals in the formation of almost all igneous rocks and they are basic to the classification of these rocks All other minerals present are regarded as nonessential in almost all igneous rocks and are called accessory minerals Types of igneous rocks with other essential minerals are very rare but include carbonatites which contain essential carbonates 17 In a simplified classification igneous rock types are separated on the basis of the type of feldspar present the presence or absence of quartz and in rocks with no feldspar or quartz the type of iron or magnesium minerals present Rocks containing quartz silica in composition are silica oversaturated Rocks with feldspathoids are silica undersaturated because feldspathoids cannot coexist in a stable association with quartz citation needed Igneous rocks that have crystals large enough to be seen by the naked eye are called phaneritic those with crystals too small to be seen are called aphanitic Generally speaking phaneritic implies an intrusive origin aphanitic an extrusive one citation needed An igneous rock with larger clearly discernible crystals embedded in a finer grained matrix is termed porphyry Porphyritic texture develops when some of the crystals grow to considerable size before the main mass of the magma crystallizes as finer grained uniform material citation needed Igneous rocks are classified on the basis of texture and composition Texture refers to the size shape and arrangement of the mineral grains or crystals of which the rock is composed citation needed Texture Gabbro specimen showing phaneritic texture from Rock Creek Canyon eastern Sierra Nevada California Main article Rock microstructure Texture is an important criterion for the naming of volcanic rocks The texture of volcanic rocks including the size shape orientation and distribution of mineral grains and the intergrain relationships will determine whether the rock is termed a tuff a pyroclastic lava or a simple lava However the texture is only a subordinate part of classifying volcanic rocks as most often there needs to be chemical information gleaned from rocks with extremely fine grained groundmass or from airfall tuffs which may be formed from volcanic ash citation needed Textural criteria are less critical in classifying intrusive rocks where the majority of minerals will be visible to the naked eye or at least using a hand lens magnifying glass or microscope Plutonic rocks also tend to be less texturally varied and less prone to showing distinctive structural fabrics Textural terms can be used to differentiate different intrusive phases of large plutons for instance porphyritic margins to large intrusive bodies porphyry stocks and subvolcanic dikes Mineralogical classification is most often used to classify plutonic rocks Chemical classifications are preferred to classify volcanic rocks with phenocryst species used as a prefix e g olivine bearing picrite or orthoclase phyric rhyolite citation needed Basic classification scheme for igneous rocks based on their mineral composition If the approximate volume fractions of minerals in the rock are known the rock name and silica content can be read off the diagram This is not an exact method because the classification of igneous rocks also depends on other components yet in most cases it is a good first guess Mineralogical classification The IUGS recommends classifying igneous rocks by their mineral composition whenever possible This is straightforward for coarse grained intrusive igneous rock but may require examination of thin sections under a microscope for fine grained volcanic rock and may be impossible for glassy volcanic rock The rock must then be classified chemically 18 Mineralogical classification of an intrusive rock begins by determining if the rock is ultramafic a carbonatite or a lamprophyre An ultramafic rock contains more than 90 of iron and magnesium rich minerals such as hornblende pyroxene or olivine and such rocks have their own classification scheme Likewise rocks containing more than 50 carbonate minerals are classified as carbonatites while lamprophyres are rare ultrapotassic rocks Both are further classified based on detailed mineralogy 19 In the great majority of cases the rock has a more typical mineral composition with significant quartz feldspars or feldspathoids Classification is based on the percentages of quartz alkali feldspar plagioclase and feldspathoid out of the total fraction of the rock composed of these minerals ignoring all other minerals present These percentages place the rock somewhere on the QAPF diagram which often immediately determines the rock type In a few cases such as the diorite gabbro anorthite field additional mineralogical criteria must be applied to determine the final classification 19 Where the mineralogy of an volcanic rock can be determined it is classified using the same procedure but with a modified QAPF diagram whose fields correspond to volcanic rock types 19 Chemical classification and petrology Total alkali versus silica classification scheme TAS as proposed in Le Maitre s 2002 Igneous Rocks A classification and glossary of terms 20 Blue area is roughly where alkaline rocks plot yellow area is where subalkaline rocks plot When it is impractical to classify a volcanic rock by mineralogy the rock must be classified chemically There are relatively few minerals that are important in the formation of common igneous rocks because the magma from which the minerals crystallize is rich in only certain elements silicon oxygen aluminium sodium potassium calcium iron and magnesium These are the elements that combine to form the silicate minerals which account for over ninety percent of all igneous rocks The chemistry of igneous rocks is expressed differently for major and minor elements and for trace elements Contents of major and minor elements are conventionally expressed as weight percent oxides e g 51 SiO2 and 1 50 TiO2 Abundances of trace elements are conventionally expressed as parts per million by weight e g 420 ppm Ni and 5 1 ppm Sm The term trace element is typically used for elements present in most rocks at abundances less than 100 ppm or so but some trace elements may be present in some rocks at abundances exceeding 1 000 ppm The diversity of rock compositions has been defined by a huge mass of analytical data over 230 000 rock analyses can be accessed on the web through a site sponsored by the U S National Science Foundation see the External Link to EarthChem citation needed The single most important component is silica SiO2 whether occurring as quartz or combined with other oxides as feldspars or other minerals Both intrusive and volcanic rocks are grouped chemically by total silica content into broad categories Felsic rocks have the highest content of silica and are predominantly composed of the felsic minerals quartz and feldspar These rocks granite rhyolite are usually light coloured and have a relatively low density Intermediate rocks have a moderate content of silica and are predominantly composed of feldspars These rocks diorite andesite are typically darker in colour than felsic rocks and somewhat more dense Mafic rocks have a relatively low silica content and are composed mostly of pyroxenes olivines and calcic plagioclase These rocks basalt gabbro are usually dark coloured and have a higher density than felsic rocks Ultramafic rock is very low in silica with more than 90 of mafic minerals komatiite dunite This classification is summarized in the following table CompositionMode of occurrence Felsic gt 63 SiO2 Intermediate 52 to 63 SiO2 Mafic 45 to 52 SiO2 Ultramafic lt 45 SiO2 Intrusive Granite Diorite Gabbro PeridotiteExtrusive Rhyolite Andesite Basalt KomatiiteThe percentage of alkali metal oxides Na2O plus K2O is second only to silica in its importance for chemically classifying volcanic rock The silica and alkali metal oxide percentages are used to place volcanic rock on the TAS diagram which is sufficient to immediately classify most volcanic rocks Rocks in some fields such as the trachyandesite field are further classified by the ratio of potassium to sodium so that potassic trachyandesites are latites and sodic trachyandesites are benmoreites Some of the more mafic fields are further subdivided or defined by normative mineralogy in which an idealized mineral composition is calculated for the rock based on its chemical composition For example basanite is distinguished from tephrite by having a high normative olivine content Other refinements to the basic TAS classification include Ultrapotassic rocks containing molar K2O Na2O gt 3 Peralkaline rocks containing molar K2O Na2O Al2O3 gt 1 21 Peraluminous rocks containing molar K2O Na2O CaO Al2O3 lt 1 21 In older terminology silica oversaturated rocks were called silicic or acidic where the SiO2 was greater than 66 and the family term quartzolite was applied to the most silicic A normative feldspathoid classifies a rock as silica undersaturated an example is nephelinite AFM ternary diagram showing the relative proportions of Na2O K2O A for Alkali earth metals FeO Fe2O3 F and MgO M with arrows showing the path of chemical variation in tholeiitic and calc alkaline series magmas Magmas are further divided into three series The tholeiitic series basaltic andesites and andesites The calc alkaline series andesites The alkaline series subgroups of alkaline basalts and the rare very high potassium bearing i e shoshonitic lavas The alkaline series is distinguishable from the other two on the TAS diagram being higher in total alkali oxides for a given silica content but the tholeiitic and calc alkaline series occupy approximately the same part of the TAS diagram They are distinguished by comparing total alkali with iron and magnesium content 22 These three magma series occur in a range of plate tectonic settings Tholeiitic magma series rocks are found for example at mid ocean ridges back arc basins oceanic islands formed by hotspots island arcs and continental large igneous provinces 23 All three series are found in relatively close proximity to each other at subduction zones where their distribution is related to depth and the age of the subduction zone The tholeiitic magma series is well represented above young subduction zones formed by magma from relatively shallow depth The calc alkaline and alkaline series are seen in mature subduction zones and are related to magma of greater depths Andesite and basaltic andesite are the most abundant volcanic rock in island arc which is indicative of the calc alkaline magmas Some island arcs have distributed volcanic series as can be seen in the Japanese island arc system where the volcanic rocks change from tholeiite calc alkaline alkaline with increasing distance from the trench 24 25 History of classification Some igneous rock names date to before the modern era of geology For example basalt as a description of a particular composition of lava derived rock dates to Georgius Agricola in 1546 in his work De Natura Fossilium 26 The word granite goes back at least to the 1640s and is derived either from French granit or Italian granito meaning simply granulate rock 27 The term rhyolite was introduced in 1860 by the German traveler and geologist Ferdinand von Richthofen 28 29 30 The naming of new rock types accelerated in the 19th century and peaked in the early 20th century 31 Much of the early classification of igneous rocks was based on the geological age and occurrence of the rocks However in 1902 the American petrologists Charles Whitman Cross Joseph P Iddings Louis V Pirsson and Henry Stephens Washington proposed that all existing classifications of igneous rocks should be discarded and replaced by a quantitative classification based on chemical analysis They showed how vague and often unscientific much of the existing terminology was and argued that as the chemical composition of an igneous rock was its most fundamental characteristic it should be elevated to prime position 32 33 Geological occurrence structure mineralogical constitution the hitherto accepted criteria for the discrimination of rock species were relegated to the background The completed rock analysis is first to be interpreted in terms of the rock forming minerals which might be expected to be formed when the magma crystallizes e g quartz feldspars olivine akermannite Feldspathoids magnetite corundum and so on and the rocks are divided into groups strictly according to the relative proportion of these minerals to one another 32 This new classification scheme created a sensation but was criticized for its lack of utility in fieldwork and the classification scheme was abandoned by the 1960s However the concept of normative mineralogy has endured and the work of Cross and his coinvestigators inspired a flurry of new classification schemes 34 Among these was the classification scheme of M A Peacock which divided igneous rocks into four series the alkalic the alkali calcic the calc alkali and the calcic series 35 His definition of the alkali series and the term calc alkali continue in use as part of the widely used 36 Irvine Barager classification 37 along with W Q Kennedy s tholeiitic series 38 By 1958 there were some 12 separate classification schemes and at least 1637 rock type names in use In that year Albert Streckeisen wrote a review article on igneous rock classification that ultimately led to the formation of the IUGG Subcommission of the Systematics of Igneous Rocks By 1989 a single system of classification had been agreed upon which was further revised in 2005 The number of recommended rock names was reduced to 316 These included a number of new names promulgated by the Subcommission 31 Origin of magmasThe Earth s crust averages about 35 kilometres 22 mi thick under the continents but averages only some 7 10 kilometres 4 3 6 2 mi beneath the oceans The continental crust is composed primarily of sedimentary rocks resting on a crystalline basement formed of a great variety of metamorphic and igneous rocks including granulite and granite Oceanic crust is composed primarily of basalt and gabbro Both continental and oceanic crust rest on peridotite of the mantle citation needed Rocks may melt in response to a decrease in pressure to a change in composition such as an addition of water to an increase in temperature or to a combination of these processes citation needed Other mechanisms such as melting from a meteorite impact are less important today but impacts during the accretion of the Earth led to extensive melting and the outer several hundred kilometers of our early Earth was probably an ocean of magma Impacts of large meteorites in the last few hundred million years have been proposed as one mechanism responsible for the extensive basalt magmatism of several large igneous provinces citation needed Decompression Decompression melting occurs because of a decrease in pressure 39 The solidus temperatures of most rocks the temperatures below which they are completely solid increase with increasing pressure in the absence of water Peridotite at depth in the Earth s mantle may be hotter than its solidus temperature at some shallower level If such rock rises during the convection of solid mantle it will cool slightly as it expands in an adiabatic process but the cooling is only about 0 3 C per kilometer Experimental studies of appropriate peridotite samples document that the solidus temperatures increase by 3 C to 4 C per kilometer If the rock rises far enough it will begin to melt Melt droplets can coalesce into larger volumes and be intruded upwards This process of melting from the upward movement of solid mantle is critical in the evolution of the Earth citation needed Decompression melting creates the ocean crust at mid ocean ridges It also causes volcanism in intraplate regions such as Europe Africa and the Pacific sea floor There it is variously attributed either to the rise of mantle plumes the Plume hypothesis or to intraplate extension the Plate hypothesis 40 Effects of water and carbon dioxide The change of rock composition most responsible for the creation of magma is the addition of water Water lowers the solidus temperature of rocks at a given pressure For example at a depth of about 100 kilometers peridotite begins to melt near 800 C in the presence of excess water but near or above about 1 500 C in the absence of water 41 Water is driven out of the oceanic lithosphere in subduction zones and it causes melting in the overlying mantle Hydrous magmas composed of basalt and andesite are produced directly and indirectly as results of dehydration during the subduction process Such magmas and those derived from them build up island arcs such as those in the Pacific Ring of Fire These magmas form rocks of the calc alkaline series an important part of the continental crust citation needed The addition of carbon dioxide is relatively a much less important cause of magma formation than the addition of water but genesis of some silica undersaturated magmas has been attributed to the dominance of carbon dioxide over water in their mantle source regions In the presence of carbon dioxide experiments document that the peridotite solidus temperature decreases by about 200 C in a narrow pressure interval at pressures corresponding to a depth of about 70 km At greater depths carbon dioxide can have more effect at depths to about 200 km the temperatures of initial melting of a carbonated peridotite composition were determined to be 450 C to 600 C lower than for the same composition with no carbon dioxide 42 Magmas of rock types such as nephelinite carbonatite and kimberlite are among those that may be generated following an influx of carbon dioxide into mantle at depths greater than about 70 km citation needed Temperature increase Increase in temperature is the most typical mechanism for formation of magma within continental crust Such temperature increases can occur because of the upward intrusion of magma from the mantle Temperatures can also exceed the solidus of a crustal rock in continental crust thickened by compression at a plate boundary The plate boundary between the Indian and Asian continental masses provides a well studied example as the Tibetan Plateau just north of the boundary has crust about 80 kilometers thick roughly twice the thickness of normal continental crust Studies of electrical resistivity deduced from magnetotelluric data have detected a layer that appears to contain silicate melt and that stretches for at least 1 000 kilometers within the middle crust along the southern margin of the Tibetan Plateau 43 Granite and rhyolite are types of igneous rock commonly interpreted as products of the melting of continental crust because of increases in temperature Temperature increases also may contribute to the melting of lithosphere dragged down in a subduction zone citation needed Magma evolution Schematic diagrams showing the principles behind fractional crystallisation in a magma While cooling the magma evolves in composition because different minerals crystallize from the melt 1 olivine crystallizes 2 olivine and pyroxene crystallize 3 pyroxene and plagioclase crystallize 4 plagioclase crystallizes At the bottom of the magma reservoir a cumulate rock forms Main article Igneous differentiationMost magmas are fully melted only for small parts of their histories More typically they are mixes of melt and crystals and sometimes also of gas bubbles Melt crystals and bubbles usually have different densities and so they can separate as magmas evolve As magma cools minerals typically crystallize from the melt at different temperatures fractional crystallization As minerals crystallize the composition of the residual melt typically changes If crystals separate from the melt then the residual melt will differ in composition from the parent magma For instance a magma of gabbroic composition can produce a residual melt of granitic composition if early formed crystals are separated from the magma Gabbro may have a liquidus temperature near 1 200 C and the derivative granite composition melt may have a liquidus temperature as low as about 700 C Incompatible elements are concentrated in the last residues of magma during fractional crystallization and in the first melts produced during partial melting either process can form the magma that crystallizes to pegmatite a rock type commonly enriched in incompatible elements Bowen s reaction series is important for understanding the idealised sequence of fractional crystallisation of a magma Clinopyroxene thermobarometry is used to determine temperature and pressure conditions at which magma differentiation occurred for specific igneous rocks citation needed Magma composition can be determined by processes other than partial melting and fractional crystallization For instance magmas commonly interact with rocks they intrude both by melting those rocks and by reacting with them Magmas of different compositions can mix with one another In rare cases melts can separate into two immiscible melts of contrasting compositions citation needed EtymologyThe word igneous rock means composed of fire and is derived from the Latin root words of igni 44 meaning fire and eous 45 meaning composed of The word volcanic rock is derived from the Latin root words of Vulcan 46 the Roman the god of fire and ic 47 meaning having some characteristics of The word plutonic rock another name for intrusive igneous rock is derived from the Latin root words of Pluto 48 the Roman god of the underworld and ic 49 meaning having some characteristics of Gallery Kanaga volcano in the Aleutian Islands with a 1906 lava flow in the foreground A skylight hole about 6 m 20 ft across in a solidified lava crust reveals molten lava below flowing towards the top right in an eruption of Kilauea in Hawaii Devils Tower an eroded laccolith in the Black Hills of Wyoming A cascade of molten lava flowing into Aloi Crater during the 1969 1971 Mauna Ulu eruption of Kilauea volcano Columnar jointing in the Alcantara Gorge Sicily A laccolith of granite light coloured that was intruded into older sedimentary rocks dark coloured at Cuernos del Paine Torres del Paine National Park Chile An igneous intrusion cut by a pegmatite dike which in turn is cut by a dolerite dikeSee also Geology portalList of rock types List of rock types recognized by geologists Metamorphic rock Rock that was subjected to heat and pressure Migmatite Mixture of metamorphic rock and igneous rock Petrology Branch of geology that studies the formation composition distribution and structure of rocks Sedimentary rock Rock formed by the deposition and subsequent cementation of materialNotes 15 is the arithmetic sum of the area for intrusive plutonic rock 7 plus the area for extrusive volcanic rock 8 2 References Prothero Donald R Schwab Fred 2004 Sedimentary geology an introduction to sedimentary rocks and stratigraphy 2nd ed New York Freeman p 12 ISBN 978 0 7167 3905 0 Wilkinson Bruce H McElroy Brandon J Kesler Stephen E Peters Shanan E Rothman Edward D 2008 Global geologic maps are tectonic speedometers Rates of rock cycling from area age frequencies Geological Society of America Bulletin 121 5 6 760 779 Bibcode 2009GSAB 121 760W doi 10 1130 B26457 1 Philpotts Anthony R Ague Jay J 2009 Principles of igneous and metamorphic petrology 2nd ed Cambridge UK Cambridge University Press pp 356 361 ISBN 978 0 521 88006 0 Philpott amp Ague 2009 p 295 sfn error no target CITEREFPhilpottAgue2009 help Heinrich Christoph A 1 May 1990 The chemistry of hydrothermal tin tungsten ore deposition Economic Geology 85 3 457 481 doi 10 2113 gsecongeo 85 3 457 Plant J A Saunders A D 1999 Uranium ore deposits Uranium Mineralogy geochemistry and the Environment Vol 38 pp 272 319 ISBN 978 1 5015 0919 3 Retrieved 13 February 2021 Philpotts amp Ague 2009 p 96 387 388 Philpotts amp Ague 2009 p 139 Philpotts amp Ague 2009 pp 52 59 Philpotts amp Ague 2009 pp 19 26 Philpotts amp Ague 2009 pp 28 35 Schmincke Hans Ulrich 2003 Volcanism Berlin Springer p 295 doi 10 1007 978 3 642 18952 4 ISBN 978 3 540 43650 8 S2CID 220886233 Philpotts amp Ague 2009 pp 365 374 Fisher Richard V Schmincke H U 1984 Pyroclastic rocks Berlin Springer Verlag p 5 ISBN 3 540 12756 9 Philpotts amp Ague 2009 pp 23 26 59 73 Philpotts amp Ague 2009 pp 73 77 a b Philpotts amp Ague 2009 pp 139 143 Le Bas M J Streckeisen A L 1991 The IUGS systematics of igneous rocks Journal of the Geological Society 148 5 825 833 Bibcode 1991JGSoc 148 825L CiteSeerX 10 1 1 692 4446 doi 10 1144 gsjgs 148 5 0825 S2CID 28548230 a b c Le Bas amp Streckeisen 1991 Shanks III W C Pat Koski Randolph A Mosier Dan L Schulz Klaus J Morgan Lisa A Slack John F Ridley W Ian Dusel Bacon Cynthia Seal II Robert R Piatak 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public domain Flett John Smith 1911 Petrology In Chisholm Hugh ed Encyclopaedia Britannica Vol 21 11th ed Cambridge University Press p 330 Cross C W Iddings J P Pirsson L V Washington H S 1903 Quantitative Classification of Igneous Rocks Chicago University of Chicago Press Oldroyd David Young Davis 1 January 2012 Of the American Quantitative Igneous Rock Classification Part 5 Earth Sciences History 31 1 1 41 doi 10 17704 eshi 31 1 17660412784m64r4 Peacock M A 1 January 1931 Classification of Igneous Rock Series The Journal of Geology 39 1 54 67 Bibcode 1931JG 39 54P doi 10 1086 623788 S2CID 140563237 Philpotts amp Ague 2009 p 143 Irvine T N Baragar W R A 6 February 2011 A Guide to the Chemical Classification of the Common Volcanic Rocks Canadian Journal of Earth Sciences 8 5 523 548 Bibcode 1971CaJES 8 523I doi 10 1139 e71 055 Kennedy W Q 1 March 1933 Trends of differentiation in basaltic magmas American Journal of Science s5 25 147 239 256 Bibcode 1933AmJS 25 239K doi 10 2475 ajs s5 25 147 239 Geoff C Brown C J Hawkesworth R C L Wilson 1992 Understanding the Earth 2nd ed Cambridge University Press p 93 ISBN 0 521 42740 1 Foulger G R 2010 Plates vs Plumes A Geological Controversy Wiley Blackwell ISBN 978 1 4051 6148 0 Grove T L Chatterjee N Parman S W Medard E 2006 The influence of H2O on mantle wedge melting Earth and Planetary Science Letters 249 1 2 74 89 Bibcode 2006E amp PSL 249 74G doi 10 1016 j epsl 2006 06 043 Dasgupta R Hirschmann M M 2007 Effect of variable carbonate concentration on the solidus of mantle peridotite American Mineralogist 92 2 3 370 379 Bibcode 2007AmMin 92 370D doi 10 2138 am 2007 2201 S2CID 95932394 Unsworth M J et al 2005 Crustal rheology of the Himalaya and Southern Tibet inferred from magnetotelluric data Nature 438 7064 78 81 Bibcode 2005Natur 438 78U doi 10 1038 nature04154 PMID 16267552 S2CID 4359642 igneous Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 eous Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 Volvano Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 ic Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 Pluto Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 ic Dictionary com Archived from the original on 15 October 2022 Retrieved 15 October 2022 External links The Wikibook Historical Geology has a page on the topic of Igneous rocks and stratigraphy The Wikibook Historical Geology has a page on the topic of Igneous rocks USGS Igneous Rocks Archived 21 February 2013 at the Wayback Machine Igneous rock classification flowchart Igneous Rocks Tour an introduction to Igneous Rocks The IUGS systematics of igneous rocks Wikimedia Commons has media related to Igneous rocks Retrieved from https en wikipedia org w index php title Igneous rock amp oldid 1143945777, wikipedia, wiki, book, books, library,

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