Regional Regional metamorphism is a general term for metamorphism that affects entire regions of the Earth's crust. It most often refers to
dynamothermal metamorphism, which takes place in
orogenic belts (regions where
mountain building is taking place), but also includes
burial metamorphism, which results simply from rock being buried to great depths below the Earth's surface in a subsiding basin.
Dynamothermal , at
Vall de Cardós,
Lérida,
Spain To many geologists, regional metamorphism is practically synonymous with dynamothermal metamorphism. This form of metamorphism takes place at
convergent plate boundaries, where two
continental plates or a continental plate and an
island arc collide. The collision zone becomes a belt of
mountain formation called an
orogeny. The orogenic belt is characterized by thickening of the Earth's crust, during which the deeply buried crustal rock is subjected to high temperatures and pressures and is intensely deformed. Subsequent
erosion of the mountains exposes the roots of the orogenic belt as extensive outcrops of metamorphic rock, characteristic of mountain chains. Metamorphic rock formed in these settings tends to shown well-developed
foliation. Foliation develops when a rock is being shortened along one axis during metamorphism. This causes crystals of platy minerals, such as
mica and
chlorite, to become rotated such that their short axes are parallel to the direction of shortening. This results in a banded, or foliated, rock, with the bands showing the colors of the minerals that formed them. Foliated rock often develops planes of
cleavage.
Slate is an example of a foliated metamorphic rock, originating from
shale, and it typically shows well-developed cleavage that allows slate to be split into thin plates. The type of foliation that develops depends on the metamorphic grade. For instance, starting with a
mudstone, the following sequence develops with increasing temperature: The mudstone is first converted to slate, which is a very fine-grained, foliated metamorphic rock, characteristic of very low grade metamorphism. Slate in turn is converted to
phyllite, which is fine-grained and found in areas of low grade metamorphism.
Schist is medium to coarse-grained and found in areas of medium grade metamorphism. High-grade metamorphism transforms the rock to
gneiss, which is coarse to very coarse-grained. Rocks that were subjected to uniform pressure from all sides, or those that lack minerals with distinctive growth habits, will not be foliated. Marble lacks platy minerals and is generally not foliated, which allows its use as a material for sculpture and architecture. Collisional orogenies are preceded by
subduction of oceanic crust. The conditions within the subducting slab as it plunges toward the
mantle in a subduction zone produce
their own distinctive regional metamorphic effects, characterized by
paired metamorphic belts. The pioneering work of
George Barrow on regional metamorphism in the Scottish Highlands showed that some regional metamorphism produces well-defined, mappable zones of increasing metamorphic grade. This
Barrovian metamorphism is the most recognized
metamorphic series in the world. However, Barrovian metamorphism is specific to
pelitic rock, formed from
mudstone or
siltstone, and it is not unique even in pelitic rock. A different sequence in the northeast of Scotland defines
Buchan metamorphism, which took place at lower pressure than the Barrovian.
Burial Burial metamorphism takes place simply through rock being buried to great depths below the Earth's surface in a subsiding basin. Here the rock is subjected to high temperatures and the great pressure caused by the immense weight of the rock layers above. Burial metamorphism tends to produce low-grade metamorphic rock. This shows none of the effects of deformation and folding so characteristic of dynamothermal metamorphism. Examples of metamorphic rocks formed by burial metamorphism include some of the rocks of the
Midcontinent Rift System of North America, such as the
Sioux Quartzite, and in the
Hamersley Basin of Australia.
Contact laccolith, and the pinkish rock on the bottom is the sedimentary country rock, a siltstone. In between, the metamorphosed siltstone is visible as both the dark layer (~5 cm thick) and the pale layer below it.
Contact metamorphism occurs typically around
intrusive igneous rocks as a result of the temperature increase caused by the intrusion of
magma into cooler
country rock. The area surrounding the intrusion where the contact metamorphism effects are present is called the
metamorphic aureole, the
contact aureole, or simply the aureole. Contact metamorphic rocks are usually known as
hornfels. Rocks formed by contact metamorphism may not present signs of strong deformation and are often fine-grained and extremely tough. The
Yule Marble used on the
Lincoln Memorial exterior and the
Tomb of the Unknown Soldier in
Arlington National Cemetery was formed by contact metamorphism. Contact metamorphism is greater adjacent to the intrusion and dissipates with distance from the contact. The size of the aureole depends on the heat of the intrusion, its size, and the temperature difference with the wall rocks. Dikes generally have small aureoles with minimal metamorphism, extending not more than one or two dike thicknesses into the surrounding rock, whereas the aureoles around
batholiths can be up to several kilometers wide. The metamorphic grade of an aureole is measured by the peak metamorphic mineral which forms in the aureole. This is usually related to the metamorphic temperatures of
pelitic or aluminosilicate rocks and the minerals they form. The metamorphic grades of aureoles at shallow depth are
albite-
epidote hornfels, hornblende hornfels,
pyroxene hornfels, and sillimanite hornfels, in increasing order of temperature of formation. However, the albite-epidote hornfels is often not formed, even though it is the lowest temperature grade. Magmatic fluids coming from the intrusive rock may also take part in the
metamorphic reactions. An extensive addition of magmatic fluids can significantly modify the chemistry of the affected rocks. In this case the metamorphism grades into
metasomatism. If the intruded rock is rich in
carbonate the result is a
skarn.
Fluorine-rich magmatic waters which leave a cooling granite may often form
greisens within and adjacent to the contact of the granite. Metasomatic altered aureoles can localize the deposition of metallic
ore minerals and thus are of economic interest.
Fenitization, or
Na-metasomatism, is a distinctive form of contact metamorphism accompanied by metasomatism. It takes place around intrusions of a rare type of magma called a
carbonatite that is highly enriched in
carbonates and low in
silica. Cooling bodies of carbonatite magma give off highly alkaline fluids rich in sodium as they solidify, and the hot, reactive fluid replaces much of the mineral content in the aureole with sodium-rich minerals. A special type of contact metamorphism, associated with fossil fuel fires, is known as
pyrometamorphism.
Hydrothermal Hydrothermal metamorphism is the result of the interaction of a rock with a high-temperature fluid of variable composition. The difference in composition between an existing rock and the invading fluid triggers a set of metamorphic and
metasomatic reactions. The hydrothermal fluid may be magmatic (originate in an intruding magma), circulating
groundwater, or ocean water. Convective circulation of hydrothermal fluids in the ocean floor
basalts produces extensive hydrothermal metamorphism adjacent to spreading centers and other submarine volcanic areas. The fluids eventually escape through vents on the ocean floor known as
black smokers. The patterns of this
hydrothermal alteration are used as a guide in the search for deposits of valuable metal ores.
Shock Shock metamorphism occurs when an extraterrestrial object (a
meteorite for instance) collides with the Earth's surface. Impact metamorphism is, therefore, characterized by ultrahigh pressure conditions and low temperature. The resulting minerals (such as SiO2
polymorphs coesite and
stishovite) and textures are characteristic of these conditions.
Dynamic Dynamic metamorphism is associated with zones of high strain such as
fault zones. In these environments, mechanical deformation is more important than chemical reactions in transforming the rock. The minerals present in the rock often do not reflect conditions of chemical equilibrium, and the textures produced by dynamic metamorphism are more significant than the mineral makeup. There are three
deformation mechanisms by which rock is mechanically deformed. These are
cataclasis, the deformation of rock via the fracture and rotation of mineral grains; plastic deformation of individual mineral crystals; and movement of individual atoms by diffusive processes. The textures of dynamic metamorphic zones are dependent on the depth at which they were formed, as the temperature and confining pressure determine the deformation mechanisms which predominate. At the shallowest depths, a fault zone will be filled with various kinds of unconsolidated
cataclastic rock, such as
fault gouge or
fault breccia. At greater depths, these are replaced by consolidated cataclastic rock, such as
crush breccia, in which the larger rock fragments are cemented together by calcite or quartz. At depths greater than about ,
cataclasites appear; these are quite hard rocks consist of crushed rock fragments in a flinty matrix, which forms only at elevated temperature. At still greater depths, where temperatures exceed , plastic deformation takes over, and the fault zone is composed of
mylonite. Mylonite is distinguished by its strong foliation, which is absent in most cataclastic rock. It is distinguished from the surrounding rock by its finer grain size. There is considerable evidence that cataclasites form as much through
plastic deformation and
recrystallization as
brittle fracture of grains, and that the rock may never fully lose cohesion during the process. Different minerals become
ductile at different temperatures, with quartz being among the first to become ductile, and sheared rock composed of different minerals may simultaneously show both plastic deformation and brittle fracture. The
strain rate also affects the way in which rocks deform. Ductile deformation is more likely at low strain rates (less than 10−14 sec−1) in the middle and lower crust, but high strain rates can cause brittle deformation. At the highest strain rates, the rock may be so strongly heated that it briefly melts, forming a glassy rock called
pseudotachylite. Pseudotachylites seem to be restricted to dry rock, such as
granulite. ==Classification of metamorphic rocks==