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orogeny

 
Dictionary: o·rog·e·ny   (ô-rŏj'ə-nē) pronunciation also or·o·gen·e·sis
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(ôr'ə-jĕn'ĭ-sĭs, ōr'-)
n.
The process of mountain formation, especially by a folding and faulting of the earth's crust.

orogenic or'o·gen'ic (ôr'ə-jĕn'ĭk, ōr'-) adj.
orogenically or'o·gen'i·cal·ly adv.

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Sci-Tech Encyclopedia: Orogeny
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The process of mountain building. As traditionally used, the term orogeny refers to the development of long, mountainous belts on the continents that are called orogenic belts or orogens. These include the Appalachian and Cordilleran orogens of North America, the Andean orogen of western South America, the Caledonian orogen of northern Europe and eastern Greenland, and the Alpine-Himalayan orogen that stretches from western Europe to eastern China. It is important to recognize that these systems represent only the most recent orogenic belts that retain the high relief characteristic of mountainous regions. In fact, the continents can be viewed as a collage of ancient orogenic belts, most of which are so deeply eroded that no trace of their original mountainous topography remains. By comparing characteristic rock assemblages from more recent orogens with their deeply eroded counterparts, geologists surmise that the processes responsible for mountain building today extended back through most (if not all) of geologic time and played a major role in the growth of the continents. See also Continents, evolution of.

The construction of mountain belts is best understood in the context of plate tectonics theory. Orogenic belts form at convergent boundaries, where lithosphere plates collide. See also Lithosphere; Plate tectonics.

There are two basic kinds of convergent plate boundaries, leading to the development of two end-member classes of orogenic belts. Oceanic subduction boundaries are those at which oceanic lithosphere is thrust (subducted) beneath either continental or oceanic lithosphere. The process of subduction leads to partial melting near the plate boundary at depth, which is manifested by volcanic and intrusive igneous activity in the overriding plate. Where the overriding plate consists of oceanic lithosphere, the result is an intraoceanic island arc, such as the Japanese islands. Where the overriding plate is continental, a continental arc is formed. The Andes of western South America is an example. See also Marine geology; Oceanic islands; Subduction zones.

The second kind of convergent plate boundary forms when an ocean basin between two continental masses has been completely consumed at an oceanic subduction boundary and the continents collide. Continent collisional orogeny has resulted in some of the most dramatic mountain ranges on Earth; a good example is the Himalayan orogen, which began forming roughly 50 million years ago when India collided with the Asian continent. Because the destruction of oceanic lithosphere at subduction boundaries is a prerequisite for continental collision, continent collisional orogens contain deformational features and rock associations developed during arc formation as well as those produced by continental collision.

Geography Dictionary: orogeny
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Movements of the earth which involve the folding of sediments, faulting, and metamorphism. A cordilleran orogeny begins with sedimentation at a passive continental margin, ranging from coarse sand and silt near shore, to limestone reefs in tropical seas. Fine-grained clastic sediments accumulate on the deeper continental slopes, forming shales and greywackes. The deposition of these geosynclinal deposits is followed by subduction and compression. Folds, thrust faults, and a volcanic arc form. Lateral growth continues through igneous activity, and metamorphism, uplift, and deformation result from continuing plate convergence. The Andes of western South America formed in this way.

Initially, a continental collision-type orogeny is similar to the cordilleran type. However, when two continental plates collide, both are too thick and too buoyant for subduction. Consequently, the plates are welded together to produce a large mountain chain, containing sedimentary, igneous, and metamorphic rock; the collision that created the Himalayas is the classic example.

Britannica Concise Encyclopedia: orogeny
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Mountain-building event, generally one that occurs in a geosyncline. Orogeny tends to occur during a relatively short geologic time frame. It is usually accompanied by folding and faulting of strata and by the deposition of sediments in areas adjacent to the orogenic belt. Orogenies may result from continental collisions, the underthrusting of continents by oceanic plates, the overriding of oceanic ridges by continents, and other causes. See also Acadian orogeny, Alleghenian orogeny, Alpine orogeny, Laramide orogeny, Taconic orogeny.

For more information on orogeny, visit Britannica.com.

Obscure Words: orogeny
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the process of mountain making, esp by folding of the earth's crust
Wikipedia: Orogeny
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Geologic provinces of the world (USGS)
     Shield      Platform      Orogen      Basin      Large igneous province      Extended crust Oceanic crust:      0–20 Ma      20–65 Ma      >65 Ma

Orogeny (Greek for "mountain generating") refers to natural mountain building, and may be studied as (a) a tectonic structural event, (b) as a geographical event, and (c) a chronological event. Orogenic events (a) cause distinctive structural phenomena and related tectonic activity, (b) affect certain regions of rocks and crust, and (c) happen within a specific period of time.

Orogenic events occur solely as a result of plate tectonics; the problems which were investigated and resolved by the study of orogenesis contributed greatly to the theory of plate tectonics, coupled with study of flora and fauna, geography and mid ocean ridges in the 1950s and 1960s.

The physical manifestations of orogenesis (the process of orogeny) are orogenic belts or orogens. An orogen is different from a mountain range in that an orogen may be almost completely eroded away, and only recognizable by studying (old) rocks that bear traces of orogenesis. Orogens are usually long, thin, arcuate tracts of rock that have a pronounced linear structure resulting in terranes or blocks of deformed rocks, separated generally by dipping thrust faults. These thrust faults carry relatively thin slices of rock (which are called nappes or thrust sheets, and differ from tectonic plates) from the core of the shortening orogen out toward the margins, and are intimately associated with folds and the development of metamorphism.

The topographic height of orogenic mountains is related to the principle of isostasy, where the gravitational force of the upthrust mountain range of light, continental crust material is balanced against its buoyancy relative to the dense mantle.

Erosion inevitably removes much of the mountains, exposing the core or mountain roots (metamorphic rocks brought to the surface from a depth of several kilometres). Such exhumation may be helped by isostatic movements balancing out the buoyancy of the evolving orogen. There is debate about the extent to which erosion modifies the patterns of tectonic deformation (see erosion and tectonics). Thus, the final form of the majority of old orogenic belts is a long arcuate strip of crystalline metamorphic rocks sequentially below younger sediments which are thrust atop them and dip away from the orogenic core.

Contents

History

Before the development of geologic concepts during the 19th century, the presence of mountains was explained in Christian contexts as a result of the Biblical Deluge. This was an extension of Neoplatonic thought, which influenced early Christian writers and assumed that a perfect Creation would have to have taken the form of a perfect sphere. Such thinking persisted into the 18th century.

Orogeny was used by Amanz Gressly (1840) and Jules Thurmann (1854) as orogenic in terms of the creation of mountain elevations, as the term mountain building was still used to describe the processes.

Elie de Beaumont (1852) used the evocative "Jaws of a Vise" theory to explain orogeny, but was more concerned with the height rather than the implicit structures created by and contained in orogenic belts. His theory essentially held that mountains were created by the squeezing of certain rocks.

Eduard Suess (1875) recognised the importance of horizontal movement of rocks. The concept of a precursor geosyncline or initial downward warping of the solid earth (Hall, 1859) prompted James Dwight Dana (1873) to include the concept of compression in the theories surrounding mountain-building. With hindsight, we can discount Dana's conjecture that this contraction was due to the cooling of the Earth (aka the cooling Earth theory).

The cooling Earth theory was the chief paradigm for most geologists until the 1960s. It was, in the context of orogeny, fiercely contested by proponents of vertical movements in the crust (similar to tephrotectonics), or convection within the asthenosphere or mantle.

Gustav Steinmann (1906) recognised different classes of orogenic belts, including the Alpine type orogenic belt, typified by a flysch and molasse geometry to the sediments; ophiolite sequences, tholeiitic basalts, and a nappe style fold structure.

In terms of recognising orogeny as an event, Leopold von Buch (1855) recognised that orogenies could be placed in time by bracketing between the youngest deformed rock and the oldest undeformed rock, a principle which is still in use today, though commonly investigated by geochronology using radiometric dating.

H.J. Zwart (1967) drew attention to the metamorphic differences in orogenic belts, proposing three types, modified by W. S. Pitcher (1979);

The advent of plate tectonics has explained the vast majority of orogenic belts and their features. The cooling earth theory (principally advanced by Descartes) is dispensed with, and tephrotectonic style vertical movements have been explained primarily by the process of isostasy.

Some oddities exist, where simple collisional tectonics are modified in a transform plate boundary, such as in New Zealand, or where island arc orogenies, for instance in New Guinea occur away from a continental backstop. Further complications such as Proterozoic continent-continent collisional orogens, explicitly the Musgrave Block in Australia, previously inexplicable (see Dennis, 1982) are being brought to light with the advent of seismic imaging techniques which can resolve the deep crust structure of orogenic belts.

Physiography

The process of orogeny can take tens of millions of years and build mountains from plains or even the ocean floor. Orogeny can occur due to continental collision or volcanic activity. Frequently, rock formations that undergo orogeny are severely deformed and undergo metamorphism. During orogeny, deeply buried rocks may be pushed to the surface. Sea bottom and near shore material may cover some or all of the orogenic area. If the orogeny is due to two continents colliding, the resulting mountains can be very high (see Himalaya).

Orogeny usually produces long linear structures, known as orogenic belts. Generally, orogenic belts consist of long parallel strips of rock exhibiting similar characteristics along the length of the belt. Orogenic belts are associated with subduction zones, which consume crust, produce volcanoes, and build island arcs. These island arcs may be added to a continent during an orogenic event.

List of orogenies

This list is incomplete; you can help by expanding it.

North American orogenies

Taconic orogeny

European orogenies

Asian orogenies

The Dabie-Sulu Orogen (Mesozoic)

South American orogenies

  • Pampean orogeny
  • Famatinian orogeny
  • Gondwanide orogeny
  • Toco orogeny
  • Andean orogeny
    • Andes Mountains, 0–200 Ma.

African orogenies

Australian orogenies

Antarctic orogenies

  • Napier orogeny (4000 ± 200 Ma)
  • Rayner orogeny (~ 3500 Ma)
  • Humboldt orogeny (~ 3000 Ma)
  • Insel orogeny (2650 ± 150 Ma)
  • Early Ruker orogeny (2000–1700 Ma)
  • Late Ruker / Nimrod orogeny (1000 ± 150 Ma)
  • Beardmore orogeny (633–620 Ma)
  • Ross Orogeny (~ 500 Ma)

New Zealand orogenies

See also

References

  1. ^ The Geology of Chile Teresa Moreno, Wes Gibbons, Geological Society of London
  • Élie de Beaumont, J.-B., 1852. Notice sur les Systèmes de Montagnes ("Note on Mountain Systems"), Bertrand, Paris, 1543 pp. (English synopsis in Dennis (1982))
  • Buch, L. Von, 1902. Gesammelte Schriften, Roth & Eck, Berlin.
  • Dana, James D., 1873. On some results of the Earth's contraction from cooling, including a discussion of the origins of mountains, and the nature of the Earth's interior. American Journal of Science, 5, pp. 423-443.
  • Dennis, John G., 1982. Orogeny, Benchmark Papers in Geology, Volume 62, Hutchinson Ross Pulishing Company, New York ISBN 0-87933-394-4
  • Hall, J., 1859. Palaeontology of New York, in New York National Survey No. 3, Part 1, 533 p.
  • Suess, Eduard, 1875. Die Entstehung Der Alpen lit. The Origin Of The Alps, Braumüller, Vienna, 168 p.
  • Harms, Brady, Cheney, 2006. Exploring the Proterozoic Big Sky Orogeny in Southwest Montana, 19th annual Keck symposium.

External links


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