Geology of Turkey: Difference between revisions
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{{Short description|none}} <!-- "none" is preferred when the title is sufficiently descriptive; see [[WP:SDNONE]] --> |
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[[File:Map of earthquakes in Turkey 1900- |
[[File:Map of earthquakes in Turkey 1900-2023.svg|420px|thumb|right|Map of earthquakes in Turkey 1900–2023]] |
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The '''geology of Turkey''' is the product of a wide variety of [[Tectonics|tectonic process]]es that have shaped [[Anatolia]] over millions of years, a process which continues today as evidenced by frequent earthquakes and occasional [[volcanic eruption]]s. |
The '''geology of Turkey''' is the product of a wide variety of [[Tectonics|tectonic process]]es that have shaped [[Anatolia]] over millions of years, a process which continues today as evidenced by frequent earthquakes and occasional [[volcanic eruption]]s. |
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[[File:Turkey_topo.jpg|thumb|400x400px|Topographic map of Turkey]] |
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Turkey's varied landscapes are the product of a wide variety of tectonic processes that have shaped Anatolia over millions of years and continue today as evidenced by frequent earthquakes and occasional volcanic eruptions. Except for a relatively small portion of its territory along the Syrian border that is a continuation of the Arabian Platform, Turkey geologically is part of the great [[Alpide belt]] that extends from the [[Atlantic Ocean]] to the [[Himalaya Mountains]]. This belt was formed during the [[Paleogene Period]], as the Arabian, African, and Indian [[Tectonic plates|continental plates]] began to collide with the [[Eurasian plate]]. This process is still at work today as the African Plate converges with the Eurasian Plate and the Anatolian Plate escapes towards the west and southwest along [[strike-slip]] faults. These are the [[North Anatolian Fault]] Zone, which forms the present-day plate boundary of Eurasia near the Black Sea coast, and the [[East Anatolian Fault]] Zone, which forms part of the boundary of the North Arabian Plate in the southeast. As a result, Turkey lies on one of the world's [[Seismology|seismically]] most active regions.{{Citation needed|date=February 2007}} |
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However, many of the rocks exposed in Turkey were formed long before this process began. Turkey contains outcrops of Precambrian rocks, (more than 520 million years old; Bozkurt et al., 2000). The earliest geological history of Turkey is poorly understood, partly because of the problem of reconstructing how the region has been tectonically assembled by plate motions. Turkey can be thought of as a collage of different pieces (possibly [[Terrane|terranes]]) of ancient continental and oceanic [[lithosphere]] stuck together by younger igneous, volcanic, and sedimentary rocks. |
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[[File:Istanbul_and_Bosporus_big.jpg|left|thumb|[[Istanbul]] and the [[Bosphorus]]]] |
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During the [[Mesozoic]] era (about 250 to 66 million years ago) a large ocean ([[Tethys Ocean]]), floored by oceanic [[lithosphere]] existed in-between the supercontinents of [[Gondwana]] and [[Laurasia]] (which lay to the south and north respectively; Robertson & Dixon, 2006). This large oceanic plate was consumed at subduction zones (see [[subduction zone]]). At the subduction trenches the [[sedimentary rock]] layers that were deposited within the prehistoric [[Tethys Ocean]] buckled, were folded, faulted, and tectonically mixed with huge blocks of crystalline basement rocks of the oceanic [[lithosphere]]. These blocks form a very complex mixture or [[mélange]] of rocks that include mainly [[serpentinite]], [[basalt]], [[dolerite]] and [[chert]] (e.g. Bergougnan, 1975). The Eurasian margin, now preserved in the Pontides (the [[Pontic Mountains]] along the [[Black Sea]] coast), is thought to have been geologically similar to the Western Pacific region today (e.g. Rice et al., 2006). Volcanic arcs (see [[volcanic arc]]) and backarc basins (see [[back-arc basin]]) formed and were emplaced onto [[Eurasia]] as ophiolites (see [[ophiolite]]) as they collided with microcontinents (literally relatively small plates of continental [[lithosphere]]; e.g. Ustaomer and Robertson, 1997). These microcontinents had been pulled away from the Gondwanan continent further south. Turkey is therefore made up of several different prehistorical microcontinents.{{Citation needed|date=February 2007}} |
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During the [[Cenozoic]] folding, faulting, and uplifting, accompanied by volcanic activity and intrusion of igneous rocks was related to major continental collision between the larger Arabian and Eurasian plates (e.g. Robertson & Dixon, 1984). |
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Present-day earthquakes range from barely perceptible tremors to major movements measuring five or higher on the open-ended [[Richter magnitude scale|Richter scale]]. Turkey's most severe earthquake in the twentieth century occurred in [[Erzincan]] on the night of December 28–29, 1939; it devastated most of the city and caused an estimated 160,000 deaths. Earthquakes of moderate intensity often continue with sporadic aftershocks over periods of several days or even weeks. The most earthquake-prone part of Turkey is an arc-shaped region stretching from the general vicinity of [[İzmit|Kocaeli]] to the area north of [[Lake Van]] on the border with [[Armenia]] and [[Georgia (country)|Georgia]]. |
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[[File:Slip-dist.png|thumb|300x300px|Fault lines and earthquakes]] |
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Turkey's terrain is structurally complex. A central massif composed of uplifted blocks and downfolded troughs, covered by recent deposits and giving the appearance of a plateau with rough terrain, is wedged between two folded mountain ranges that converge in the east. True [[Lowland|lowlands]] are confined to the ''Ergene Ovası'' (Ergene Plain) in [[Thrace]], extending along rivers that discharge into the [[Aegean Sea]] or the [[Sea of Marmara]], and to a few narrow coastal strips along the [[Black Sea]] and [[Mediterranean Sea]] coasts.{{Citation needed|date=February 2007}} |
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Nearly 85% of the land is at an elevation of at least 450 meters; the average and median altitude of the country is 1,332 and 1,128 meters, respectively. In Asiatic Turkey, flat or gently sloping land is rare and largely confined to the deltas of the [[Kızıl River]], the coastal plains of Antalya and Adana, and the valley floors of the Gediz River and the [[Maeander River|Büyükmenderes River]], and some interior high plains in Anatolia, mainly around [[Lake Tuz|Tuz Gölü]] (Salt Lake) and ''Konya Ovası'' (Konya Plain). Moderately sloping terrain is limited almost entirely outside Thrace to the hills of the Arabian Platform along the border with Syria. |
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More than 80% of the land surface is rough, broken, and mountainous, and therefore is of limited agricultural value (see Agriculture, ch. 3). The terrain's ruggedness is accentuated in the eastern part of the country, where the two mountain ranges converge into a lofty region with a median elevation of more than 1,500 meters, which reaches its highest point along the borders with Armenia, Azerbaijan, and Iran. Turkey's highest peak, [[Mount Ararat]] (Ağrı Dağı) — 5,137 meters high — is situated near the point where the boundaries of the four countries meet. |
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== Background == |
== Background == |
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More than 80% of the land surface is rough, broken, and mountainous, and therefore is of limited agricultural value. The terrain's ruggedness is accentuated in the eastern part of the country, where the two mountain ranges converge into a lofty region with a median elevation of more than 1,500 meters, which reaches its highest point along the borders with [[Armenia]], [[Azerbaijan]], and [[Iran]]. Turkey's highest peak, [[Mount Ararat]] (Ağrı Dağı)—about 5,166 meters high—is situated near the point where the boundaries of the four countries meet. |
More than 80% of the land surface is rough, broken, and mountainous, and therefore is of limited agricultural value. The terrain's ruggedness is accentuated in the eastern part of the country, where the two mountain ranges converge into a lofty region with a median elevation of more than 1,500 meters, which reaches its highest point along the borders with [[Armenia]], [[Azerbaijan]], and [[Iran]]. Turkey's highest peak, [[Mount Ararat]] (Ağrı Dağı)—about 5,166 meters high—is situated near the point where the boundaries of the four countries meet. |
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== Geological |
== Geological history == |
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The earliest geological history of Turkey is poorly understood, partly because these oldest rocks in the region are involved into younger deformation phases that hindered their evolution. This created problem of reconstructing how the region has been tectonically assembled by plate motions. Turkey can be thought of as a collage of different continental pieces and remnants of oceanic lithospheric rocks amalgamated together by younger tectonic processes that involve accumulation of igneous (both plutonic and volcanic) and sedimentary rocks. |
The earliest geological history of Turkey is poorly understood, partly because these oldest rocks in the region are involved into younger deformation phases that hindered their evolution. This created problem of reconstructing how the region has been tectonically assembled by plate motions. Turkey can be thought of as a collage of different continental pieces and remnants of oceanic lithospheric rocks amalgamated together by younger tectonic processes that involve accumulation of igneous (both plutonic and volcanic) and sedimentary rocks. |
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=== Plate tectonics === |
=== Plate tectonics === |
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[[File:Turkey-faults-platenames. |
[[File:Turkey-faults-platenames.svg|thumb|[[Tectonic plates]] in Turkey; the [[Anatolian Plate]], the [[African Plate]], the [[Arabian Plate]], and the [[Eurasian Plate]].]] |
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Except for a relatively small portion of its territory along the [[Syria]]n border that is a continuation of the [[Arabian Plate]], Turkey geologically is part of the great |
Except for a relatively small portion of its territory along the [[Syria]]n border that is a continuation of the [[Arabian Plate]], Turkey geologically is part of the great [[Alpide belt]] that extends from the Atlantic Ocean to the Himalaya Mountains. This belt was formed during the [[Cenozoic Era]] (about 66 to 1.6 million years ago), as the Arabian, [[African Plate|African]], and [[Indian Plate|Indian]] [[continental plate]]s began to collide with the [[Eurasian Plate]]. This process is still at work today as the African Plate converges with the Eurasian Plate and the [[Anatolian Plate]] escapes towards the west and southwest along strike-slip faults. These are the [[North Anatolian Fault Zone]], which forms the present day plate boundary of Eurasia near the Black Sea coast and, the [[East Anatolian Fault]] Zone, which forms part of the boundary of the North Arabian Plate in the southeast. As a result of this [[plate tectonics]] configuration, Turkey is one of the world's more active earthquake and volcanic regions.<ref>Kaymakci et al., 2010</ref> |
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The Anatolian Plate, together with the [[Aegean Sea|Aegean]]-[[Peloponnesus]] block, is located near the centre of a very wide region, including the [[Arabian Plate]] with the adjacent [[Zagros Mountains]] and central [[Iran]], that moves in a circulatory pattern at a relatively fast rate of 20 mm/yr. The rate of this counter-clockwise motion increases near the [[Hellenic Trench]] system south of Turkey and decreases away from it (i.e. the Eurasian and African plates move at a rate of 5 mm/yr), resulting in internal deformations in several areas, including central and eastern Anatolia, south-western Aegean-Peloponnesus, [[Lesser Caucasus]], and central Iran. |
The Anatolian Plate, together with the [[Aegean Sea|Aegean]]-[[Peloponnesus]] block, is located near the centre of a very wide region, including the [[Arabian Plate]] with the adjacent [[Zagros Mountains]] and central [[Iran]], that moves in a circulatory pattern at a relatively fast rate of 20 mm/yr. The rate of this counter-clockwise motion increases near the [[Hellenic Trench]] system south of Turkey and decreases away from it (i.e. the Eurasian and African plates move at a rate of 5 mm/yr), resulting in internal deformations in several areas, including central and eastern Anatolia, south-western Aegean-Peloponnesus, [[Lesser Caucasus]], and central Iran. |
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The dominant process in the region is the subduction of the African Plate beneath the Hellenic Trench, and the deformation in the entire African-Arabian-Eurasian collision zone is most likely driven by the slab roll-back of the subducting African Plate in the East Mediterranean.<ref> |
The dominant process in the region is the subduction of the African Plate beneath the Hellenic Trench, and the deformation in the entire African-Arabian-Eurasian collision zone is most likely driven by the slab roll-back of the subducting African Plate in the East Mediterranean.<ref>Biryol et al., 2011</ref> This process is further fuelled by slab-pull forces in the [[Makran Trench]] in the [[Gulf of Oman]] where the Arabian Plate is subducting under Eurasia. A response to this tectonic maelstrom is the rifting in the Red Sea and Gulf of Aden which will separate Arabia from Africa.<ref>{{Harvnb|Reilinger|McClusky|Vernant|Lawrence|2006|loc=Abstract; Fig. 2, p. 33, Fig. 3, p. 34}}</ref> |
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The [[tomography]] of the velocity propagation distributions of the P_<sub>n</sub> [[Seismic wave#Love waves|seismic waves]] both in an isotropic and [[anisotropy|anisotropic]] conditions, compared with the lateral variations of that velocity has highlighted the physical properties of the [[Earth's mantle|uppermost mantle]] and [[Crust (geology)|crustal thickness]] of the Earth. A study analyzed 700 earthquakes occurred in Turkey from 1999 to 2010 with [[Richter magnitude scale|magnitude degree]] major than 4.0 and the related 50.000 Pn first arrivals recorded by 832 seismic stations at a distance range of |
The [[tomography]] of the velocity propagation distributions of the P_<sub>n</sub> [[Seismic wave#Love waves|seismic waves]] both in an isotropic and [[anisotropy|anisotropic]] conditions, compared with the lateral variations of that velocity has highlighted the physical properties of the [[Earth's mantle|uppermost mantle]] and [[Crust (geology)|crustal thickness]] of the Earth. A study analyzed 700 earthquakes occurred in Turkey from 1999 to 2010 with [[Richter magnitude scale|magnitude degree]] major than 4.0 and the related 50.000 Pn first arrivals recorded by 832 seismic stations at a distance range of 180–1500 km from the [[epicenter]]. The tomography highlighted that "Pn velocities are found to be lowest in eastern Turkey (<7.6 km s-1) and highest in the eastern [[Mediterranean Sea]] and [[Zagros fold and thrust belt|Zagros Suture]] (>8.3 km s-1). Large Pn anisotropy is observed in the Aegean, central Anatolia and along the southern coast of Anatolia. [...] Large crustal thicknesses are observed along the [[Dinarides]]-[[Hellenides]] and along the southern coast of Anatolia."<ref>{{cite journal | title = Anisotropic Pn tomography of Turkey and adjacent regions | author = Ahu Kömeç Mutlu | author2 = Hayrullah Karabulut | journal = [[Geophysical Journal International]] | volume = 187 | issue = 3 | date = December 1, 2011 | pages = 1743–1758 | doi = 10.1111/j.1365-246X.2011.05235.x | publisher = [[Oxford University Press]] | bibcode = 2011GeoJI.187.1743M | issn = 1365-246X | oclc = 5137621576 | doi-access = free }}</ref> |
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=== Rocks === |
=== Rocks === |
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[[Image:View of Cappadocia edit.jpg|thumb|View of [[Cappadocia]] landscape]] |
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Many of the rocks exposed in Turkey were formed long before this process began. Turkey contains outcrops of [[Precambrian]] rocks, (more than 540 million years old).<ref>Bozkurt et al., 2000</ref> |
Many of the rocks exposed in Turkey were formed long before this process began. Turkey contains outcrops of [[Precambrian]] rocks, (more than 540 million years old).<ref>Bozkurt et al., 2000</ref> |
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During the [[Mesozoic era]] (about 250 to 66 million years ago) a large ocean ([[Tethys Ocean]]), floored by oceanic lithosphere existed in-between the [[supercontinent]]s of [[Gondwana]] and [[Laurasia]] (which lay to the south and north respectively).<ref>Şengör and Yılmaz, 1981</ref> This large oceanic plate was consumed at [[subduction zone]]s. At the subduction trenches the sedimentary rock layers that were deposited within the prehistoric Tethys Ocean were folded, faulted and tectonically mixed with huge blocks of crystalline basement rocks of the oceanic lithosphere. These blocks form a very complex mixture or [[mélange]] of rocks that include mainly [[serpentinite]], [[basalt]], [[dolerite]], and [[chert]].<ref>Okay and Tüysüz, 1999</ref> The Eurasian margin, now preserved in the Pontides (the [[Pontic Mountains]] along the Black Sea coast), is thought to have been geologically similar to the Western Pacific region today.<ref>Kaymakci, 2000</ref> [[Volcanic arc]]s and [[back-arc basin]]s formed and were emplaced onto Eurasia as [[ophiolite]]s as they collided with [[microcontinent]]s (literally relatively small plates of continental lithosphere).<ref>Ustaomer and Robertson, 1997</ref> These microcontinents had been pulled away from the Gondwanan continent further south. Turkey is therefore made up from several different prehistorical microcontinents.{{Citation needed|date=May 2007}} |
During the [[Mesozoic era]] (about 250 to 66 million years ago) a large ocean ([[Tethys Ocean]]), floored by oceanic lithosphere existed in-between the [[supercontinent]]s of [[Gondwana]] and [[Laurasia]] (which lay to the south and north respectively).<ref>Şengör and Yılmaz, 1981</ref> This large oceanic plate was consumed at [[subduction zone]]s. At the subduction trenches the sedimentary rock layers that were deposited within the prehistoric Tethys Ocean were folded, faulted and tectonically mixed with huge blocks of crystalline basement rocks of the oceanic lithosphere. These blocks form a very complex mixture or [[mélange]] of rocks that include mainly [[serpentinite]], [[basalt]], [[dolerite]], and [[chert]].<ref>Okay and Tüysüz, 1999</ref> The Eurasian margin, now preserved in the Pontides (the [[Pontic Mountains]] along the Black Sea coast), is thought to have been geologically similar to the Western Pacific region today.<ref>Kaymakci, 2000</ref> [[Volcanic arc]]s and [[back-arc basin]]s formed and were emplaced onto Eurasia as [[ophiolite]]s as they collided with [[microcontinent]]s (literally relatively small plates of continental lithosphere).<ref>Ustaomer and Robertson, 1997</ref> These microcontinents had been pulled away from the Gondwanan continent further south. Turkey is therefore made up from several different prehistorical microcontinents.{{Citation needed|date=May 2007}} |
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During the [[Cenozoic]] (Tertiary about 66 to 1.6 million years) folding, faulting and uplifting, accompanied by volcanic activity and intrusion of igneous rocks was related to major continental collision between the larger Arabian and Eurasian plates.<ref>Robertson & Dixon, 1984</ref> |
During the [[Cenozoic]] (Tertiary about 66 to 1.6 million years) folding, faulting and uplifting, accompanied by volcanic activity and intrusion of igneous rocks was related to major continental collision between the larger Arabian and Eurasian plates.<ref>Robertson & Dixon, 1984</ref> [[Pamukkale]] terraces are made of [[travertine]], a sedimentary rock deposited by mineral water from [[hot springs]]. The area is famous for a carbonate mineral left by the flowing of thermal spring water.<ref name="readers natural">{{Cite book|title=Natural Wonders of the World|publisher=Reader's Digest Association, Inc|year=1980|isbn=978-0-89577-087-5|editor-last=Scheffel|editor-first=Richard L.|page=286|editor-last2=Wernet|editor-first2=Susan J.}}</ref><ref name="Unesco">{{cite web |url=https://whc.unesco.org/en/list/485 |title=Hierapolis-Pamukkale World Heritage Site |publisher=UNESCO World Heritage Center|access-date=17 January 2022}}</ref> |
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== Earthquakes == |
== Earthquakes == |
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{{See also|1939 Erzincan earthquake}} |
{{See also|1939 Erzincan earthquake}} |
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Turkey's most severe earthquake in the twentieth century occurred in [[Erzincan]] on the night of 1939-12-27; it devastated most of the city and caused an estimated 30,000 deaths. Earthquakes of moderate intensity often continue with sporadic aftershocks over periods of several days or even weeks. Seismicity in Turkey is more likely to happen in the North Anatolian Fault Zone, East Anatolian Fault Zone and in the subduction region of the |
Turkey's most severe earthquake in the twentieth century occurred in [[Erzincan]] on the night of 1939-12-27; it devastated most of the city and caused an estimated 30,000 deaths. Earthquakes of moderate intensity often continue with sporadic aftershocks over periods of several days or even weeks. Seismicity in Turkey is more likely to happen in the North Anatolian Fault Zone, East Anatolian Fault Zone and in the subduction region of the Aegean Plate between the Anatolian plate. |
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==See also== |
==See also== |
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* [[List of earthquakes in Turkey]] |
* [[List of earthquakes in Turkey]] |
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==External links== |
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*[https://www.mta.gov.tr/v3.0/hizmetler/yenilenmis-diri-fay-haritalari 1:25,000 scale fault maps (click the square to see a map if there are faults)] |
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*[https://tdth.afad.gov.tr/TDTH/main.xhtml Seismic Risk Map (requires logon with Turkish ID)] |
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== Notes == |
== Notes == |
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== References == |
== References == |
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*Bergougnan, H. (1975) Dispositif des ophiolites nord-est anatoliennes, origine des nappes ophiolitiques et sud-pontiques, jeu de la faille nord-anatolienne. Comptes Rendus |
*Bergougnan, H. (1975) Dispositif des ophiolites nord-est anatoliennes, origine des nappes ophiolitiques et sud-pontiques, jeu de la faille nord-anatolienne. Comptes Rendus de l'Académie des Sciences, Série D: Sciences Naturelles, 281: 107–110. |
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*Bozkurt, E. and Satir, M. (2000) The southern Menderes Massif (western Turkey); geochronology and exhumation history. Geological Journal, 35: 285–296. |
*Bozkurt, E. and Satir, M. (2000) The southern Menderes Massif (western Turkey); geochronology and exhumation history. Geological Journal, 35: 285–296. |
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*Kaymakci, N., 2000. Tectono-stratigraphical evolution of the Çankırı basin (Central Anatolia, Turkey) (Vol. 190, pp. |
*Kaymakci, N., 2000. [http://www.itc.nl/library/papers_2000/phd/kaymakci.pdf Tectono-stratigraphical evolution of the Çankırı basin (Central Anatolia, Turkey)] (Vol. 190, pp. 1–247). Utrecht University. |
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*Kaymakci, N., Inceöz, M., Ertepinar, P. and Koç, A. 2010. |
*Kaymakci, N., Inceöz, M., Ertepinar, P. and Koç, A. 2010. [http://www.metu.edu.tr/~kaymakci/papers/17_Kaymakci%202010_GSL340_SE_Anatolia.pdf Cretaceous to recent kinematics of SE Anatolia (Turkey)] In Sosson, M. Kaymakci, N., Stephenson, R., Starostenko, V. and Bergerat, F. (Eds.) Sedimentary basin tectonics from the Black Sea and Caucasus to the Arabian Platform. Geological Society London Special Issue No. 340, 409-435. |
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*Reilinger |
* {{cite journal |last1=Reilinger |first1=Robert |last2=McClusky |first2=Simon |last3=Vernant |first3=Philippe |last4=Lawrence |first4=Shawn |last5=Ergintav |first5=Semih |last6=Cakmak |first6=Rahsan |title=GPS constraints on continental deformation in the Africa-Arabia-Eurasia continental collision zone and implications for the dynamics of plate interactions: EASTERN MEDITERRANEAN ACTIVE TECTONICS |journal=Journal of Geophysical Research: Solid Earth |date=May 2006 |volume=111 |issue=B5 |doi=10.1029/2005JB004051 |url=https://www.researchgate.net/publication/224962277|doi-access=free |bibcode=2006JGRB..111.5411R }} |
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*Robertson, A. and Dixon, J.E.D. (1984) Introduction: aspects of the geological evolution of the Eastern Mediterranean. In: Dixon and Robertson (Editors), The Geological Evolution of the Eastern Mediterranean. Geological Society, London, Special Publications, 17, 1–74. |
*Robertson, A. and Dixon, J.E.D. (1984) Introduction: aspects of the geological evolution of the Eastern Mediterranean. In: Dixon and Robertson (Editors), The Geological Evolution of the Eastern Mediterranean. Geological Society, London, Special Publications, 17, 1–74. |
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*Ustaömer, T. and Robertson, A. (1997) Tectonic-sedimentary evolution of the north Tethyan margin in the Central Pontides of northern Turkey. In: A.G. Robinson (Editor), Regional and Petroleum Geology of the Black Sea and Surrounding Region. AAPG Memoir, 68, Tulsa, Oklahoma, 255–290. |
*Ustaömer, T. and Robertson, A. (1997) Tectonic-sedimentary evolution of the north Tethyan margin in the Central Pontides of northern Turkey. In: A.G. Robinson (Editor), Regional and Petroleum Geology of the Black Sea and Surrounding Region. AAPG Memoir, 68, Tulsa, Oklahoma, 255–290. |
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*{{ |
*{{Country study}} |
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*{{CIA World Factbook}} |
*{{CIA World Factbook}} |
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*Brinkmann, Roland, 1976, Geology of Turkey, Elsevier Scientific Pub. Co {{ISBN|0-444-99833-0}} |
*Brinkmann, Roland, 1976, Geology of Turkey, Elsevier Scientific Pub. Co {{ISBN|0-444-99833-0}} |
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*Higgins, MD and Higgins, RA, 1996,*[http://uqac.ca/mhiggins/greece.htm ''A Geological Companion to Greece and the Aegean''] Cornell University Press. {{ISBN|0-8014-3337-1}} |
*Higgins, MD and Higgins, RA, 1996,*[http://uqac.ca/mhiggins/greece.htm ''A Geological Companion to Greece and the Aegean''] Cornell University Press. {{ISBN|0-8014-3337-1}} |
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[[Category:Geology of Turkey| ]] |
[[Category:Geology of Turkey| ]] |
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[[Category:Natural history of Turkey]] |
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[[Category:Geology of Western Asia|Turkey]] |
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[[Category:Geology by country|Turkey]] |
Revision as of 01:34, 29 July 2024
This article needs additional citations for verification. (May 2007) |
The geology of Turkey is the product of a wide variety of tectonic processes that have shaped Anatolia over millions of years, a process which continues today as evidenced by frequent earthquakes and occasional volcanic eruptions.
Turkey's varied landscapes are the product of a wide variety of tectonic processes that have shaped Anatolia over millions of years and continue today as evidenced by frequent earthquakes and occasional volcanic eruptions. Except for a relatively small portion of its territory along the Syrian border that is a continuation of the Arabian Platform, Turkey geologically is part of the great Alpide belt that extends from the Atlantic Ocean to the Himalaya Mountains. This belt was formed during the Paleogene Period, as the Arabian, African, and Indian continental plates began to collide with the Eurasian plate. This process is still at work today as the African Plate converges with the Eurasian Plate and the Anatolian Plate escapes towards the west and southwest along strike-slip faults. These are the North Anatolian Fault Zone, which forms the present-day plate boundary of Eurasia near the Black Sea coast, and the East Anatolian Fault Zone, which forms part of the boundary of the North Arabian Plate in the southeast. As a result, Turkey lies on one of the world's seismically most active regions.[citation needed]
However, many of the rocks exposed in Turkey were formed long before this process began. Turkey contains outcrops of Precambrian rocks, (more than 520 million years old; Bozkurt et al., 2000). The earliest geological history of Turkey is poorly understood, partly because of the problem of reconstructing how the region has been tectonically assembled by plate motions. Turkey can be thought of as a collage of different pieces (possibly terranes) of ancient continental and oceanic lithosphere stuck together by younger igneous, volcanic, and sedimentary rocks.
During the Mesozoic era (about 250 to 66 million years ago) a large ocean (Tethys Ocean), floored by oceanic lithosphere existed in-between the supercontinents of Gondwana and Laurasia (which lay to the south and north respectively; Robertson & Dixon, 2006). This large oceanic plate was consumed at subduction zones (see subduction zone). At the subduction trenches the sedimentary rock layers that were deposited within the prehistoric Tethys Ocean buckled, were folded, faulted, and tectonically mixed with huge blocks of crystalline basement rocks of the oceanic lithosphere. These blocks form a very complex mixture or mélange of rocks that include mainly serpentinite, basalt, dolerite and chert (e.g. Bergougnan, 1975). The Eurasian margin, now preserved in the Pontides (the Pontic Mountains along the Black Sea coast), is thought to have been geologically similar to the Western Pacific region today (e.g. Rice et al., 2006). Volcanic arcs (see volcanic arc) and backarc basins (see back-arc basin) formed and were emplaced onto Eurasia as ophiolites (see ophiolite) as they collided with microcontinents (literally relatively small plates of continental lithosphere; e.g. Ustaomer and Robertson, 1997). These microcontinents had been pulled away from the Gondwanan continent further south. Turkey is therefore made up of several different prehistorical microcontinents.[citation needed]
During the Cenozoic folding, faulting, and uplifting, accompanied by volcanic activity and intrusion of igneous rocks was related to major continental collision between the larger Arabian and Eurasian plates (e.g. Robertson & Dixon, 1984).
Present-day earthquakes range from barely perceptible tremors to major movements measuring five or higher on the open-ended Richter scale. Turkey's most severe earthquake in the twentieth century occurred in Erzincan on the night of December 28–29, 1939; it devastated most of the city and caused an estimated 160,000 deaths. Earthquakes of moderate intensity often continue with sporadic aftershocks over periods of several days or even weeks. The most earthquake-prone part of Turkey is an arc-shaped region stretching from the general vicinity of Kocaeli to the area north of Lake Van on the border with Armenia and Georgia.
Turkey's terrain is structurally complex. A central massif composed of uplifted blocks and downfolded troughs, covered by recent deposits and giving the appearance of a plateau with rough terrain, is wedged between two folded mountain ranges that converge in the east. True lowlands are confined to the Ergene Ovası (Ergene Plain) in Thrace, extending along rivers that discharge into the Aegean Sea or the Sea of Marmara, and to a few narrow coastal strips along the Black Sea and Mediterranean Sea coasts.[citation needed]
Nearly 85% of the land is at an elevation of at least 450 meters; the average and median altitude of the country is 1,332 and 1,128 meters, respectively. In Asiatic Turkey, flat or gently sloping land is rare and largely confined to the deltas of the Kızıl River, the coastal plains of Antalya and Adana, and the valley floors of the Gediz River and the Büyükmenderes River, and some interior high plains in Anatolia, mainly around Tuz Gölü (Salt Lake) and Konya Ovası (Konya Plain). Moderately sloping terrain is limited almost entirely outside Thrace to the hills of the Arabian Platform along the border with Syria.
More than 80% of the land surface is rough, broken, and mountainous, and therefore is of limited agricultural value (see Agriculture, ch. 3). The terrain's ruggedness is accentuated in the eastern part of the country, where the two mountain ranges converge into a lofty region with a median elevation of more than 1,500 meters, which reaches its highest point along the borders with Armenia, Azerbaijan, and Iran. Turkey's highest peak, Mount Ararat (Ağrı Dağı) — 5,137 meters high — is situated near the point where the boundaries of the four countries meet.
Background
Turkey's terrain is structurally complex. A central massif composed of uplifted blocks and downfolded troughs, covered by recent deposits and giving the appearance of a plateau with rough terrain, is wedged between two folded mountain ranges that converge in the east. True lowland is confined to the plain of the Ergene river in Thrace, extending along rivers that discharge into the Aegean Sea or the Sea of Marmara, and to a few narrow coastal strips along the Black Sea and Mediterranean Sea coasts.[citation needed]
Nearly 85% of the land is at an elevation of at least 450 meters; the median altitude of the country is 1,128 meters. In Asiatic Turkey, flat or gently sloping land is rare and largely confined to the deltas of the Kızıl River, the coastal plains of Antalya and Adana, and the valley floors of the Gediz River and the Büyük Menderes River, and some interior high plains in Anatolia, mainly around Tuz Gölü (Salt Lake) and Konya Ovası (Konya Basin). Moderately sloping terrain is limited almost entirely outside Thrace to the hills of the Arabian Platform along the border with Syria.
More than 80% of the land surface is rough, broken, and mountainous, and therefore is of limited agricultural value. The terrain's ruggedness is accentuated in the eastern part of the country, where the two mountain ranges converge into a lofty region with a median elevation of more than 1,500 meters, which reaches its highest point along the borders with Armenia, Azerbaijan, and Iran. Turkey's highest peak, Mount Ararat (Ağrı Dağı)—about 5,166 meters high—is situated near the point where the boundaries of the four countries meet.
Geological history
The earliest geological history of Turkey is poorly understood, partly because these oldest rocks in the region are involved into younger deformation phases that hindered their evolution. This created problem of reconstructing how the region has been tectonically assembled by plate motions. Turkey can be thought of as a collage of different continental pieces and remnants of oceanic lithospheric rocks amalgamated together by younger tectonic processes that involve accumulation of igneous (both plutonic and volcanic) and sedimentary rocks.
Plate tectonics
Except for a relatively small portion of its territory along the Syrian border that is a continuation of the Arabian Plate, Turkey geologically is part of the great Alpide belt that extends from the Atlantic Ocean to the Himalaya Mountains. This belt was formed during the Cenozoic Era (about 66 to 1.6 million years ago), as the Arabian, African, and Indian continental plates began to collide with the Eurasian Plate. This process is still at work today as the African Plate converges with the Eurasian Plate and the Anatolian Plate escapes towards the west and southwest along strike-slip faults. These are the North Anatolian Fault Zone, which forms the present day plate boundary of Eurasia near the Black Sea coast and, the East Anatolian Fault Zone, which forms part of the boundary of the North Arabian Plate in the southeast. As a result of this plate tectonics configuration, Turkey is one of the world's more active earthquake and volcanic regions.[1]
The Anatolian Plate, together with the Aegean-Peloponnesus block, is located near the centre of a very wide region, including the Arabian Plate with the adjacent Zagros Mountains and central Iran, that moves in a circulatory pattern at a relatively fast rate of 20 mm/yr. The rate of this counter-clockwise motion increases near the Hellenic Trench system south of Turkey and decreases away from it (i.e. the Eurasian and African plates move at a rate of 5 mm/yr), resulting in internal deformations in several areas, including central and eastern Anatolia, south-western Aegean-Peloponnesus, Lesser Caucasus, and central Iran. The dominant process in the region is the subduction of the African Plate beneath the Hellenic Trench, and the deformation in the entire African-Arabian-Eurasian collision zone is most likely driven by the slab roll-back of the subducting African Plate in the East Mediterranean.[2] This process is further fuelled by slab-pull forces in the Makran Trench in the Gulf of Oman where the Arabian Plate is subducting under Eurasia. A response to this tectonic maelstrom is the rifting in the Red Sea and Gulf of Aden which will separate Arabia from Africa.[3]
The tomography of the velocity propagation distributions of the P_n seismic waves both in an isotropic and anisotropic conditions, compared with the lateral variations of that velocity has highlighted the physical properties of the uppermost mantle and crustal thickness of the Earth. A study analyzed 700 earthquakes occurred in Turkey from 1999 to 2010 with magnitude degree major than 4.0 and the related 50.000 Pn first arrivals recorded by 832 seismic stations at a distance range of 180–1500 km from the epicenter. The tomography highlighted that "Pn velocities are found to be lowest in eastern Turkey (<7.6 km s-1) and highest in the eastern Mediterranean Sea and Zagros Suture (>8.3 km s-1). Large Pn anisotropy is observed in the Aegean, central Anatolia and along the southern coast of Anatolia. [...] Large crustal thicknesses are observed along the Dinarides-Hellenides and along the southern coast of Anatolia."[4]
Rocks
Many of the rocks exposed in Turkey were formed long before this process began. Turkey contains outcrops of Precambrian rocks, (more than 540 million years old).[5]
During the Mesozoic era (about 250 to 66 million years ago) a large ocean (Tethys Ocean), floored by oceanic lithosphere existed in-between the supercontinents of Gondwana and Laurasia (which lay to the south and north respectively).[6] This large oceanic plate was consumed at subduction zones. At the subduction trenches the sedimentary rock layers that were deposited within the prehistoric Tethys Ocean were folded, faulted and tectonically mixed with huge blocks of crystalline basement rocks of the oceanic lithosphere. These blocks form a very complex mixture or mélange of rocks that include mainly serpentinite, basalt, dolerite, and chert.[7] The Eurasian margin, now preserved in the Pontides (the Pontic Mountains along the Black Sea coast), is thought to have been geologically similar to the Western Pacific region today.[8] Volcanic arcs and back-arc basins formed and were emplaced onto Eurasia as ophiolites as they collided with microcontinents (literally relatively small plates of continental lithosphere).[9] These microcontinents had been pulled away from the Gondwanan continent further south. Turkey is therefore made up from several different prehistorical microcontinents.[citation needed]
During the Cenozoic (Tertiary about 66 to 1.6 million years) folding, faulting and uplifting, accompanied by volcanic activity and intrusion of igneous rocks was related to major continental collision between the larger Arabian and Eurasian plates.[10] Pamukkale terraces are made of travertine, a sedimentary rock deposited by mineral water from hot springs. The area is famous for a carbonate mineral left by the flowing of thermal spring water.[11][12]
Earthquakes
Turkey's most severe earthquake in the twentieth century occurred in Erzincan on the night of 1939-12-27; it devastated most of the city and caused an estimated 30,000 deaths. Earthquakes of moderate intensity often continue with sporadic aftershocks over periods of several days or even weeks. Seismicity in Turkey is more likely to happen in the North Anatolian Fault Zone, East Anatolian Fault Zone and in the subduction region of the Aegean Plate between the Anatolian plate.
See also
External links
Notes
- ^ Kaymakci et al., 2010
- ^ Biryol et al., 2011
- ^ Reilinger et al. 2006, Abstract; Fig. 2, p. 33, Fig. 3, p. 34
- ^ Ahu Kömeç Mutlu; Hayrullah Karabulut (December 1, 2011). "Anisotropic Pn tomography of Turkey and adjacent regions". Geophysical Journal International. 187 (3). Oxford University Press: 1743–1758. Bibcode:2011GeoJI.187.1743M. doi:10.1111/j.1365-246X.2011.05235.x. ISSN 1365-246X. OCLC 5137621576.
- ^ Bozkurt et al., 2000
- ^ Şengör and Yılmaz, 1981
- ^ Okay and Tüysüz, 1999
- ^ Kaymakci, 2000
- ^ Ustaomer and Robertson, 1997
- ^ Robertson & Dixon, 1984
- ^ Scheffel, Richard L.; Wernet, Susan J., eds. (1980). Natural Wonders of the World. Reader's Digest Association, Inc. p. 286. ISBN 978-0-89577-087-5.
- ^ "Hierapolis-Pamukkale World Heritage Site". UNESCO World Heritage Center. Retrieved 17 January 2022.
References
- Bergougnan, H. (1975) Dispositif des ophiolites nord-est anatoliennes, origine des nappes ophiolitiques et sud-pontiques, jeu de la faille nord-anatolienne. Comptes Rendus de l'Académie des Sciences, Série D: Sciences Naturelles, 281: 107–110.
- Bozkurt, E. and Satir, M. (2000) The southern Menderes Massif (western Turkey); geochronology and exhumation history. Geological Journal, 35: 285–296.
- Kaymakci, N., 2000. Tectono-stratigraphical evolution of the Çankırı basin (Central Anatolia, Turkey) (Vol. 190, pp. 1–247). Utrecht University.
- Kaymakci, N., Inceöz, M., Ertepinar, P. and Koç, A. 2010. Cretaceous to recent kinematics of SE Anatolia (Turkey) In Sosson, M. Kaymakci, N., Stephenson, R., Starostenko, V. and Bergerat, F. (Eds.) Sedimentary basin tectonics from the Black Sea and Caucasus to the Arabian Platform. Geological Society London Special Issue No. 340, 409-435.
- Reilinger, Robert; McClusky, Simon; Vernant, Philippe; Lawrence, Shawn; Ergintav, Semih; Cakmak, Rahsan (May 2006). "GPS constraints on continental deformation in the Africa-Arabia-Eurasia continental collision zone and implications for the dynamics of plate interactions: EASTERN MEDITERRANEAN ACTIVE TECTONICS". Journal of Geophysical Research: Solid Earth. 111 (B5). Bibcode:2006JGRB..111.5411R. doi:10.1029/2005JB004051.
- Robertson, A. and Dixon, J.E.D. (1984) Introduction: aspects of the geological evolution of the Eastern Mediterranean. In: Dixon and Robertson (Editors), The Geological Evolution of the Eastern Mediterranean. Geological Society, London, Special Publications, 17, 1–74.
- Ustaömer, T. and Robertson, A. (1997) Tectonic-sedimentary evolution of the north Tethyan margin in the Central Pontides of northern Turkey. In: A.G. Robinson (Editor), Regional and Petroleum Geology of the Black Sea and Surrounding Region. AAPG Memoir, 68, Tulsa, Oklahoma, 255–290.
- This article incorporates text from this source, which is in the public domain. Country Studies. Federal Research Division.
- This article incorporates public domain material from The World Factbook. CIA.
Further reading
- Brinkmann, Roland, 1976, Geology of Turkey, Elsevier Scientific Pub. Co ISBN 0-444-99833-0
- Higgins, MD and Higgins, RA, 1996,*A Geological Companion to Greece and the Aegean Cornell University Press. ISBN 0-8014-3337-1