Jump to content

Variscan orogeny: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
KolbertBot (talk | contribs)
Nomenclature: frequency of use of the terms "Hercynian" and "Variscan" - added another source reference - "Google Books n-gram"
 
(39 intermediate revisions by 29 users not shown)
Line 1: Line 1:
{{Short description|Collision of tectonic plates resulting in the creation of mountains}}
[[File:Hercynides EN.svg|thumb|300px|Location of the Hercynian-[[Alleghenian orogeny|Alleghenian]] mountain belts in the middle of the [[Carboniferous]] period. Present day coastlines are indicated in grey for reference.<ref>Based on {{Harvnb|Matte|2001}} and {{Harvnb|Ziegler|1990}}</ref>]]
[[File:Hercynides EN.svg|thumb|300px|Location of the Hercynian-[[Alleghenian orogeny|Alleghenian]] mountain belts in the middle of the [[Carboniferous]] period. Present day coastlines are indicated in grey for reference.<ref>Based on {{Harvnb|Matte|2001}} and {{Harvnb|Ziegler|1990}}</ref>]]
The '''Variscan''' or '''Hercynian''' '''orogeny''' is a geologic mountain-building event caused by Late [[Paleozoic]] [[continental collision]] between [[Euramerica]] (Laurussia) and [[Gondwana]] to form the [[supercontinent]] of [[Pangaea]].
The '''Variscan orogeny''', or '''Hercynian orogeny''', was a geologic mountain-building event caused by Late [[Paleozoic]] [[continental collision]] between [[Euramerica]] (Laurussia) and [[Gondwana]] to form the [[supercontinent]] of [[Pangaea]].


==Nomenclature==
==Nomenclature==
The name ''Variscan'', comes from the Medieval [[Latin]] name for the district ''[[Variscia]]'', the home of a Germanic tribe, the [[Varisci]]; [[Eduard Suess]], professor of geology at the [[University of Vienna]], coined the term in 1880. ([[Variscite]], a rare green mineral first discovered in the [[Vogtland]] district of [[Saxony]] in [[Germany]], which is in the Variscan belt, has the same [[etymology]].)
The name ''Variscan'' comes from the Medieval [[Latin]] name for the district ''[[Variscia]]'', the home of a Germanic tribe, the [[Varisci]]; [[Eduard Suess]], professor of geology at the [[University of Vienna]], coined the term in 1880. ([[Variscite]], a rare green mineral first discovered in the [[Vogtland]] district of [[Saxony]] in Germany, which is in the Variscan belt, has the same etymology.)


''Hercynian'', on the other hand, derives from the [[Hercynian Forest]]. Both words were descriptive terms of [[Strike (geology)|strike]] directions observed by geologists in the field, ''variscan'' for southwest to northeast, ''hercynian'' for northwest to southeast. The ''variscan'' direction reflected the direction of ancient fold belts cropping out throughout Germany and adjacent countries and the meaning shifted from direction to the fold belt proper.
''Hercynian'', on the other hand, derives from the [[Hercynian Forest]]. Both words were descriptive terms of [[Strike (geology)|strike]] directions observed by geologists in the field, ''variscan'' for southwest to northeast, ''hercynian'' for northwest to southeast. The ''variscan'' direction reflected the direction of ancient fold belts cropping out throughout Germany and adjacent countries and the meaning shifted from direction to the fold belt proper.
Line 9: Line 10:
One of the pioneers in research on the Variscan fold belt was the German geologist [[Franz Kossmat]], establishing a still valid division of the European Variscides<!--"Variscides" have not been introduced--> in 1927.<ref>{{Cite journal |last=Kossmat |first=F. |title=Gliederung des varistischen Gebirgsbaus |journal=Abh. Sächs. Geol. L.-A. |volume=1 |pages=1–39 |place=Leipzig |year=1927 }}</ref>
One of the pioneers in research on the Variscan fold belt was the German geologist [[Franz Kossmat]], establishing a still valid division of the European Variscides<!--"Variscides" have not been introduced--> in 1927.<ref>{{Cite journal |last=Kossmat |first=F. |title=Gliederung des varistischen Gebirgsbaus |journal=Abh. Sächs. Geol. L.-A. |volume=1 |pages=1–39 |place=Leipzig |year=1927 }}</ref>


The other direction, ''Hercynian'', for the direction of the [[Harz]] Mountains in Germany, saw a similar shift in meaning. Today ''Hercynian'' is often used as a [[synonym]] for ''Variscan'', but is somewhat less used than the latter.<ref>Google search on December 29, 2007: ca. 44.500 for ''Variscan orogeny'', ca. 15.000 ''Hercynian orogeny''. In German: 1.170 for "variszische Orogenese", 154 for "herzynische Orogenese".</ref> In the USA it is only used for European orogenies; the contemporaneous and genetically<!--"genetically"?--> linked mountain-building phases in the [[Appalachian Mountains]] have different names.<ref>[http://www.ucmp.berkeley.edu/devonian/devtect.html ''Tectonics of the Devonian'']. Website of University of California Museum of Paleontology. Accessed on December 29, 2007.</ref><ref name="hwilliams">[https://web.archive.org/web/20080927053810/http://courses.unt.edu:80/hwilliams/GEOL_3020/exam3review.htm "The Hercynian Orogeny"]. Historical Geology, University of North Texas.</ref>
The other direction, ''Hercynian'', for the direction of the [[Harz]] Mountains in Germany, saw a similar shift in meaning. Today, ''Hercynian'' is often used as a [[synonym]] for ''Variscan'' but is somewhat less used than the latter in the English speaking world.<ref>Google search on December 29, 2007: approximately 44,500 for ''Variscan orogeny'', approximately 15,000 ''Hercynian orogeny''. In German: 1,170 for "variszische Orogenese", 154 for "herzynische Orogenese".</ref><ref>https://books.google.com/ngrams/graph?content=Variscan+*%2CHercynian+*&year_start=1940&year_end=2022&corpus=en&smoothing=3 ; retrieved 17 November 2024</ref> In the United States, it is used only for European orogenies; the contemporaneous and genetically<!--"genetically"?--> linked mountain-building phases in the [[Appalachian Mountains]] have different names.<ref>[http://www.ucmp.berkeley.edu/devonian/devtect.html ''Tectonics of the Devonian'']. Website of University of California Museum of Paleontology. Accessed on December 29, 2007.</ref><ref name="hwilliams">[https://web.archive.org/web/20080927053810/http://courses.unt.edu/hwilliams/GEOL_3020/exam3review.htm "The Hercynian Orogeny"]. Historical Geology, University of North Texas.</ref>


The regional term ''Variscan'' underwent a further meaning shift since the 1960s. Geologists generally began to use it to characterize late Paleozoic fold-belts and orogenic phases having an age of approximately 380 to 280&nbsp;Ma.
The regional term ''Variscan'' underwent a further meaning shift since the 1960s. Geologists generally began to use it to characterize late Paleozoic fold-belts and orogenic phases having an age of approximately 380 to 280&nbsp;Ma.


Some publications use the term ''Variscan'' for fold belts of even younger age,<ref>{{Cite journal |url=https://pubs.er.usgs.gov/usgspubs/b/b1871 |title=Geology of petroleum and coal deposits in the North China Basin, Eastern China |last=Lee |first=K. Y. |journal=USGS Bulletin 1871 |year=1989 |postscript=. Table 1, p. 3. }}</ref> deviating from the meaning as a term for the North American and European orogeny related to the Gondwana-Laurasia collision.
Some publications use the term ''Variscan'' for fold belts of even younger age,<ref>{{Cite journal |url=https://pubs.er.usgs.gov/usgspubs/b/b1871 |title=Geology of petroleum and coal deposits in the North China Basin, Eastern China |last=Lee |first=K. Y. |journal=USGS Bulletin 1871 |year=1989 |postscript=. Table 1, p. 3. |access-date=2017-09-17 |archive-date=2019-09-13 |archive-url=https://web.archive.org/web/20190913035632/https://pubs.er.usgs.gov/publication/b1871 |url-status=dead }}</ref> deviating from the meaning as a term for the North American and European orogeny related to the Gondwana-Laurasia collision.


==Distribution==
==Distribution==
[[File:Distribution of varisican orogenies.png|300px|thumb|Distribution of orogenies with similar ages to the Variscan orogeny (shaded)]]
[[File:Distribution of varisican orogenies.png|300px|thumb|Distribution of orogenies with similar ages to the Variscan orogeny (shaded)]]


The North American and European Variscan Belt includes the mountains of [[Portugal]] and [[Spain]] ([[Galicia (Spain)|Galicia]], and [[Pyrenees]]), southwestern [[Ireland]] (i.e. [[Munster]]), [[Cornwall]], [[Devon]], [[Pembrokeshire]], the [[Gower Peninsula]] and the [[Vale of Glamorgan]]. Its effects are present in [[France]] from [[Brittany]], below the [[Paris Basin]] to the [[Ardennes]], the [[Massif Central]], the [[Vosges]] and [[Corsica]].
The North American and European Variscan Belt includes the mountains of Portugal and Spain ([[Galicia (Spain)|Galicia]], and [[Pyrenees]]), southwestern Ireland (i.e. [[Munster]]), [[Cornwall]], [[Devon]], [[Pembrokeshire]], the [[Gower Peninsula]] and the [[Vale of Glamorgan]]. Its effects are present in France from [[Brittany]], below the [[Paris Basin]] to the [[Ardennes]], the [[Massif Central]], the [[Vosges]] and [[Corsica]].


The Variscan Belt reappears in [[Sardinia]] in Italy and in Germany where the [[Rhine Massif]] (Ardennes, [[Eifel]], [[Hunsrück]], [[Taunus]] and other regions on both sides of [[Middle Rhine]] Valley), the [[Black Forest]] and [[Harz Mountains]] remain as testimony. In southern Iberia it is marked by a classic strike-slip suture zone between very distinct suspect terranes, and clear evidence can be seen of ductile shearing between high-grade [[metamorphic rock]]s and lower grade sedimentary rocks in a wide belt north of the [[Algarve]] and extending into the northernmost part the autonomous region of [[Andalusia]] and southern [[Extremadura]].<ref>{{Cite journal|last=Martínez Catalán|first=José R.|date=2012-07-01|title=The Central Iberian arc, an orocline centered in the Iberian Massif and some implications for the Variscan belt|journal=International Journal of Earth Sciences|language=en|volume=101|issue=5|pages=1299–1314|doi=10.1007/s00531-011-0715-6|bibcode=2012IJEaS.101.1299M| s2cid=195334509 |issn=1437-3262}}</ref><ref>{{Cite journal|last1=Crespo-Blanc|first1=Ana|last2=Orozco|first2=Miguel|date=1991-10-01|title=The boundary between the Ossa-Morena and Southportuguese Zones (Southern Iberian Massif): Major suture in the European Hercynian Chain|journal=Geologische Rundschau|language=en|volume=80|issue=3|pages=691–702|doi=10.1007/BF01803695|bibcode=1991GeoRu..80..691C|s2cid=128688878|issn=1432-1149}}</ref>
The Variscan Belt reappears in [[Sardinia]] in [[Italy]] and in [[Germany]] where the [[Rhine Massif]] (Ardennes, [[Eifel]], [[Hunsrück]], [[Taunus]] and other regions on both sides of [[Middle Rhine]] Valley), the [[Black Forest]] and [[Harz Mountains]] remain as testimony.


In the [[Czech Republic]] and Eastern [[Poland]] the [[Bohemian Massif]] is the eastern end of the unmodified Variscan belt of crustal deformation in [[Europe]]. Further Variscan developments to the southeast are partly hidden and overprinted by the [[alpine orogeny]].
In the Czech Republic and southwestern Poland the [[Bohemian Massif]] is the eastern end of the unmodified Variscan belt of crustal deformation in Europe. Further Variscan developments to the southeast are partly hidden and [[Overprinting (geology)|overprinted]] by the [[Alpine orogeny]]. In the [[Alps]] a Variscan core is built by [[Mercantour]], [[Pelvoux]], [[Belledonne]], [[Mont Blanc massif|Montblanc]] and [[Aar Massif]]. [[Dinarides|Dinaric]], Greek and Turkish mountain chains are the southeastern termination of the Variscan proper.<ref>[http://www.unil.ch/igp/page22669_fr.html Tectonic Map of the western Tethysides] {{Webarchive|url=https://web.archive.org/web/20080423091159/http://www.unil.ch/igp/page22669_fr.html |date=2008-04-23 }}. Institute of Geology and Paleontology of the [[University of Lausanne]], [[Switzerland]]. Accessed on December 29, 2007.</ref>


The Variscan was contemporaneous with the [[Acadian orogeny|Acadian]] and [[Alleghenian orogeny]] in the United States and Canada, responsible for forming the [[Ouachita Mountains|Ouachita]] and [[Appalachian Mountains]]. North American areas with Variscan foldbelts include [[New England]], [[Nova Scotia]] and [[Newfoundland and Labrador]]. The [[Moroccan Meseta]] and the [[Anti-Atlas]] in northwestern Africa show close relations to the Appalachian Mountains and used to form the eastern part of the [[Appalachian orogeny]] before the opening of the [[Atlantic Ocean]] in [[Jurassic]] times.<ref>{{Cite journal|last1=Burkhard|first1=M.|last2=Caritg|first2=S.|last3=Helg|first3=U.|last4=Robert-Charrue|first4=C.|last5=Soulaimani|first5=A.|year=2006|title=Tectonics of the anti-Atlas of Morocco|url=http://soulaimani.chez-alice.fr/Burkhardet%20al_2006.pdf|journal=Comptes Rendus Geoscience|volume=338|issue=1|pages=11–24|doi=10.1016/j.crte.2005.11.012|bibcode=2006CRGeo.338...11B|access-date=1 November 2015}}<!-- {{Harvnb|Burkhard|Caritg|Helg|Robert-Charrue|2006}} --></ref> 'Variscan' mountains in a broad chronological sense include the [[Ural Mountains|Ural]]s, the [[Pamir Mountains|Pamir]], the [[Tian Shan]] and other Asian foldbelts.<ref>[http://www.unil.ch/igp/page22666_en.html ''Paleotethys''. Paleogeographic reconstructions for the Devonian and Carboniferous] {{Webarchive|url=https://web.archive.org/web/20110608151513/http://www.unil.ch/igp/page22666_en.html |date=2011-06-08 }}. ''Tethyan Plate Tectonic Working Group'' of the [[University of Lausanne]], [[Switzerland]]. Accessed on December 29, 2007.</ref><ref>[http://www.scotese.com/newpage4.htm Paleogeographic configuration Lower Carboniferous]. ''Paleomap Project'' by C.Scotese. Accessed on December 29, 2007.</ref>
In the [[Alps]] a Variscan core is built by [[Mercantour]], [[Pelvoux]], [[Belledonne]], [[Mont Blanc massif|Montblanc]] and [[Aar Massif]]. [[Dinarides|Dinaric]], [[Greece|Greek]] and [[Turkey|Turkish]] mountain chains are the southeastern termination of the Variscan proper.<ref>[http://www.unil.ch/igp/page22669_fr.html Tectonic Map of the western Tethysides]. Institute of Geology and Paleontology of the [[University of Lausanne]], [[Switzerland]]. Accessed on December 29, 2007.</ref>

The Variscan was contemporaneous with the [[Acadian orogeny|Acadian]] and [[Alleghenian orogeny]] in the [[United States]] and [[Canada]], responsible for forming the [[Ouachita Mountains|Ouachita]] and [[Appalachian Mountains]]. North American areas with Variscan foldbelts include [[New England]], [[Nova Scotia]] and [[Newfoundland and Labrador]].

The [[Morocco|Moroccan]] Meseta and the [[Anti-Atlas]] in northwestern [[Africa]] show close relations to the Appalachian Mountains and used to form the eastern part of the [[Appalachian orogeny]] before the opening of the [[Atlantic Ocean]] in [[Jurassic]] times.<ref>{{Cite journal
| last1 = Burkhard | first1 = M.
| last2 = Caritg | first2 = S.
| last3 = Helg | first3 = U.
| last4 = Robert-Charrue | first4 = C.
| last5 = Soulaimani | first5 = A.
| title = Tectonics of the anti-Atlas of Morocco
| year = 2006 | journal = Comptes Rendus Geoscience | volume = 338 | issue = 1 | pages = 11-24
| url = http://soulaimani.chez-alice.fr/Burkhardet%20al_2006.pdf | accessdate = November 2015
| ref = harv}}<!-- {{Harvnb|Burkhard|Caritg|Helg|Robert-Charrue|2006}} --></ref>

'Variscan' mountains in a broad chronological sense include the [[Ural Mountains|Ural]]s, the [[Pamir Mountains|Pamir]], the [[Tian Shan]] and other [[Asia]]n foldbelts.<ref>[http://www.unil.ch/igp/page22666_en.html ''Paleotethys''. Paleogeographic reconstructions for the Devonian and Carboniferous]. ''Tethyan Plate Tectonic Working Group'' of the [[University of Lausanne]], [[Switzerland]]. Accessed on December 29, 2007.</ref><ref>[http://www.scotese.com/newpage4.htm Paleogeographic configuration Lower Carboniferous]. ''Paleomap Project'' by C.Scotese. Accessed on December 29, 2007.</ref>


==Formation==
==Formation==
Line 45: Line 31:
The Variscan orogeny involved a complicated heterogeneous assembly of different microplates and [[wikt:heterochronous|heterochronous]] collisions, making the exact reconstruction of the plate tectonic processes difficult. Plate convergence that caused the [[Caledonian orogeny]] in the [[Silurian]] continued to form the Variscan orogeny in the succeeding [[Devonian]] and [[Carboniferous]] Periods. Both orogenies resulted in the assembly of a super-continent, [[Pangaea]], which was essentially complete by the end of the Carboniferous.
The Variscan orogeny involved a complicated heterogeneous assembly of different microplates and [[wikt:heterochronous|heterochronous]] collisions, making the exact reconstruction of the plate tectonic processes difficult. Plate convergence that caused the [[Caledonian orogeny]] in the [[Silurian]] continued to form the Variscan orogeny in the succeeding [[Devonian]] and [[Carboniferous]] Periods. Both orogenies resulted in the assembly of a super-continent, [[Pangaea]], which was essentially complete by the end of the Carboniferous.


In the [[Ordovician]] Period, a land mass, which has been named Gondwana (present day [[South America]], [[Africa]], [[Antarctica]] and [[Australia]]), straddled the space between the [[South Pole]] and the [[Equator]] on one side of the globe. Off to the west were three other masses: [[Laurentia]], [[Siberia]] and [[Baltica]], located as if on the vertices of a triangle. To the south of them was a large archipelago, the [[terrane]] [[Avalonia]], rifted off the north Gondwana margin in early Ordovician.
In the [[Ordovician]] Period, a land mass, which has been named Gondwana (present day South America, Africa, Antarctica, [[Arabian Peninsula|Arabia]], the [[Indian subcontinent]], [[Zealandia]] and Australia), straddled the space between the [[South Pole]] and the [[Equator]] on one side of the globe. Off to the west were three other masses: [[Laurentia]], [[Siberia]] and [[Baltica]], located as if on the vertices of a triangle. To the south of them was a large archipelago, the [[terrane]] [[Avalonia]], rifted off the north Gondwana margin in early [[Ordovician]].


By the end of the [[Silurian]] and in [[Early Devonian]] times, Baltica and Laurentia drifted towards each other, closing the [[Iapetus Ocean]] between them. They collided in the [[Caledonian orogeny]] and formed the Caledonide mountains of North America, [[Greenland]], the British Isles and [[Norway]].
By the end of the [[Silurian]] and in [[Early Devonian]] times, Baltica and Laurentia drifted towards each other, closing the [[Iapetus Ocean]] between them. They collided in the [[Caledonian orogeny]] and formed the Caledonide mountains of North America, [[Greenland]], the British Isles and [[Norway]]. [[Seafloor spreading]] to the south of Avalonia pushed the latter into north Laurentia and thrust up the northern Appalachian Mountains in the [[Acadian orogeny|acadian phase]] of the Caledonian orogeny. Contemporaneously the [[Tornquist Sea]] between Avalonia and Baltica was entirely closed. Thus Avalonia formed the southern coast of the new continent [[Euramerica]] ([[Laurussia]], the [[Old Red Sandstone]] continent in present-day North America, the British Isles, northern Germany, Scandinavia and western Russia).

[[Seafloor spreading]] to the south of Avalonia pushed the latter into north Laurentia and thrust up the northern Appalachian Mountains in the [[Acadian orogeny|acadian phase]] of the Caledonian orogeny. Contemporaneously the [[Tornquist Sea]] between Avalonia and Baltica was entirely closed. Thus Avalonia formed the southern coast of the new continent [[Euramerica]] (Laurussia, the [[Old Red Sandstone]] [[continent]] in present-day [[North America]], [[British Isles]], northern [[Germany]], [[Scandinavia]] and western [[Russia]]).


In late Devonian and in the Carboniferous the archipelago [[Armorican terrane|Armorica]] of southern Europe, which had rifted off Gondwana after Avalonia later in the Ordovician, was pushed into Avalonia, creating a second range, the North American/European Variscan, to the east of the Caledonide/Appalachian. The collision of Gondwana proper with Laurussia followed in the early Carboniferous, when the Variscan belt was already in place and actively developing.
In late Devonian and in the Carboniferous the archipelago [[Armorican terrane|Armorica]] of southern Europe, which had rifted off Gondwana after Avalonia later in the Ordovician, was pushed into Avalonia, creating a second range, the North American/European Variscan, to the east of the Caledonide/Appalachian. The collision of Gondwana proper with Laurussia followed in the early Carboniferous, when the Variscan belt was already in place and actively developing.


By the end of the Carboniferous, Gondwana had united with Laurussia on its western end through northern South America and northwestern Africa. Siberia was approaching from the northeast, separated from Laurussia only by shallow waters. Collision with Siberia produced the [[Ural Mountains]] in the latest Paleozoic and completed the formation of Pangaea. Eastern [[Laurussia]] was still divided from Gondwana by the [[Paleotethys]] Ocean.
By the end of the Carboniferous, Gondwana had united with Laurussia on its western end through northern South America and northwestern Africa. Siberia was approaching from the northeast, separated from Laurussia only by shallow waters. Collision with Siberia produced the [[Ural Mountains]] in the latest Paleozoic and completed the formation of Pangaea. Eastern Laurussia was still divided from Gondwana by the [[Paleotethys]] Ocean. In the [[Triassic]] Period of the [[Mesozoic]] Era, animals could move without oceanic impediment from Siberia over the North Pole to Antarctica over the South Pole. In the Mesozoic Era, rifting and subsequent opening of the Atlantic split Pangaea. As a consequence, the Variscan Belt around the then periphery of Baltica ended up many hundreds of miles from the Appalachians.


==References==
In the [[Triassic]] Period of the [[Mesozoic]] Era, animals could move without oceanic impediment from Siberia over the North Pole to Antarctica over the South Pole. In the [[Mesozoic]] Era, the opening of the Atlantic split Pangea. As a consequence, the Variscan Belt around the then periphery of Baltica ended up many hundreds of miles from the Appalachians.
{{Reflist}}

==Notes==
{{reflist}}


==Further reading==
==Further reading==
* {{Cite journal |last=Matte |first=P. |year=2001 |title=The Variscan collage and orogeny (480 ±290&nbsp;Ma) and the tectonic definition of the Armorica microplate: a review |journal=Terra Nova |volume=13 |pages=122–128 |doi=10.1046/j.1365-3121.2001.00327.x|ref=harv}}
* {{Cite journal |last=Matte |first=P. |year=2001 |title=The Variscan collage and orogeny (480 ±290&nbsp;Ma) and the tectonic definition of the Armorica microplate: a review |journal=Terra Nova |volume=13 |issue=2 |pages=122–128 |doi=10.1046/j.1365-3121.2001.00327.x|bibcode=2001TeNov..13..122M |s2cid=129727506 }}
* {{Cite book |last=Ziegler |first=P.A. |authorlink=Peter Ziegler |year=1990 |title=Geological Atlas of Western and Central Europe |publisher=Shell Internationale Petroleum Maatschappij BV |edition=2 |isbn=90-6644-125-9|ref=harv}}
* {{Cite book |last=Ziegler |first=P.A. |author-link=Peter Ziegler |year=1990 |title=Geological Atlas of Western and Central Europe |publisher=Shell Internationale Petroleum Maatschappij BV |edition=2 |isbn=978-90-6644-125-5}}
* {{Cite journal |last=von Raumer |first=J. |last2=Stampfli |first2=G.M. |last3=Borel |first3=G.D. |last4=Bussy |first4=F. |year=2002 |title=The organisation of pre-Variscan basement areas at the north-Gondwanan margin |journal=International Journal of Earth Sciences |volume=91 |pages=35–52 |bibcode = 2002IJEaS..91...35V |doi = 10.1007/s005310100200 }}
* {{Cite journal |last1=von Raumer |first1=J. |last2=Stampfli |first2=G.M. |last3=Borel |first3=G.D. |last4=Bussy |first4=F. |year=2002 |title=The organisation of pre-Variscan basement areas at the north-Gondwanan margin |journal=International Journal of Earth Sciences |volume=91 |issue=1 |pages=35–52 |bibcode = 2002IJEaS..91...35V |doi = 10.1007/s005310100200 |s2cid=131617311 |url=http://doc.rero.ch/record/310796/files/531_2002_Article_200.pdf }}
* {{Cite journal |last=von Raumer |first=J. |last2=Stampfli |first2=G.M. |last3=Bussy |first3=F. |year=2003 |title=Gondwana-derived microcontinents - the constituents of the Variscan and Alpine collisional orogens |journal=Tectonophysics |volume=365 |pages=7–22 |bibcode = 2003Tectp.365....7V |doi = 10.1016/S0040-1951(03)00015-5 }}
* {{Cite journal |last1=von Raumer |first1=J. |last2=Stampfli |first2=G.M. |last3=Bussy |first3=F. |year=2003 |title=Gondwana-derived microcontinents - the constituents of the Variscan and Alpine collisional orogens |journal=Tectonophysics |volume=365 |issue=1–4 |pages=7–22 |bibcode = 2003Tectp.365....7V |doi = 10.1016/S0040-1951(03)00015-5 |citeseerx=10.1.1.430.1420 }}
* {{Cite book |last=Stampfli |first=GM |last2=Borel |first2=GD |year=2004 |chapter=The TRANSMED Transects in Space and Time: Constraints on the Paleotectonic Evolution of the Mediterranean Domain |editors=Cavazza W, Roure F, Spakman W, Stampfli GM, Ziegler P |title=The TRANSMED Atlas: the Mediterranean Region from Crust to Mantle |publisher=Springer Verlag |isbn=3-540-22181-6}}
* {{Cite book |last1=Stampfli |first1=GM |last2=Borel |first2=GD |year=2004 |chapter=The TRANSMED Transects in Space and Time: Constraints on the Paleotectonic Evolution of the Mediterranean Domain |editor1=Cavazza W |editor2=Roure F |editor3=Spakman W |editor4=Stampfli GM |editor5=Ziegler P |title=The TRANSMED Atlas: the Mediterranean Region from Crust to Mantle |publisher=Springer Verlag |isbn=978-3-540-22181-4}}


==External links==
==External links==
Line 73: Line 55:
** [http://www.scotese.com/late.htm Late Carboniferous Map]
** [http://www.scotese.com/late.htm Late Carboniferous Map]
** [http://www.scotese.com/newpage8.htm Triassic Map]
** [http://www.scotese.com/newpage8.htm Triassic Map]
* Ronald Blakey, Colorado Plateau Geosystems Inc: [http://cpgeosystems.com/300_Carb_Penn_EurMap_plates.jpg Europe in the Late Carboniferous]
* [[Ronald Blakey]], Colorado Plateau Geosystems Inc: [http://cpgeosystems.com/300_Carb_Penn_EurMap_plates.jpg Europe in the Late Carboniferous] {{Webarchive|url=https://web.archive.org/web/20150922025225/http://cpgeosystems.com/300_Carb_Penn_EurMap_plates.jpg |date=2015-09-22 }}

{{Authority control}}


[[Category:Hercynian orogeny]]
[[Category:Hercynian orogeny]]

Latest revision as of 15:05, 17 November 2024

Location of the Hercynian-Alleghenian mountain belts in the middle of the Carboniferous period. Present day coastlines are indicated in grey for reference.[1]

The Variscan orogeny, or Hercynian orogeny, was a geologic mountain-building event caused by Late Paleozoic continental collision between Euramerica (Laurussia) and Gondwana to form the supercontinent of Pangaea.

Nomenclature

[edit]

The name Variscan comes from the Medieval Latin name for the district Variscia, the home of a Germanic tribe, the Varisci; Eduard Suess, professor of geology at the University of Vienna, coined the term in 1880. (Variscite, a rare green mineral first discovered in the Vogtland district of Saxony in Germany, which is in the Variscan belt, has the same etymology.)

Hercynian, on the other hand, derives from the Hercynian Forest. Both words were descriptive terms of strike directions observed by geologists in the field, variscan for southwest to northeast, hercynian for northwest to southeast. The variscan direction reflected the direction of ancient fold belts cropping out throughout Germany and adjacent countries and the meaning shifted from direction to the fold belt proper.

One of the pioneers in research on the Variscan fold belt was the German geologist Franz Kossmat, establishing a still valid division of the European Variscides in 1927.[2]

The other direction, Hercynian, for the direction of the Harz Mountains in Germany, saw a similar shift in meaning. Today, Hercynian is often used as a synonym for Variscan but is somewhat less used than the latter in the English speaking world.[3][4] In the United States, it is used only for European orogenies; the contemporaneous and genetically linked mountain-building phases in the Appalachian Mountains have different names.[5][6]

The regional term Variscan underwent a further meaning shift since the 1960s. Geologists generally began to use it to characterize late Paleozoic fold-belts and orogenic phases having an age of approximately 380 to 280 Ma.

Some publications use the term Variscan for fold belts of even younger age,[7] deviating from the meaning as a term for the North American and European orogeny related to the Gondwana-Laurasia collision.

Distribution

[edit]
Distribution of orogenies with similar ages to the Variscan orogeny (shaded)

The North American and European Variscan Belt includes the mountains of Portugal and Spain (Galicia, and Pyrenees), southwestern Ireland (i.e. Munster), Cornwall, Devon, Pembrokeshire, the Gower Peninsula and the Vale of Glamorgan. Its effects are present in France from Brittany, below the Paris Basin to the Ardennes, the Massif Central, the Vosges and Corsica.

The Variscan Belt reappears in Sardinia in Italy and in Germany where the Rhine Massif (Ardennes, Eifel, Hunsrück, Taunus and other regions on both sides of Middle Rhine Valley), the Black Forest and Harz Mountains remain as testimony. In southern Iberia it is marked by a classic strike-slip suture zone between very distinct suspect terranes, and clear evidence can be seen of ductile shearing between high-grade metamorphic rocks and lower grade sedimentary rocks in a wide belt north of the Algarve and extending into the northernmost part the autonomous region of Andalusia and southern Extremadura.[8][9]

In the Czech Republic and southwestern Poland the Bohemian Massif is the eastern end of the unmodified Variscan belt of crustal deformation in Europe. Further Variscan developments to the southeast are partly hidden and overprinted by the Alpine orogeny. In the Alps a Variscan core is built by Mercantour, Pelvoux, Belledonne, Montblanc and Aar Massif. Dinaric, Greek and Turkish mountain chains are the southeastern termination of the Variscan proper.[10]

The Variscan was contemporaneous with the Acadian and Alleghenian orogeny in the United States and Canada, responsible for forming the Ouachita and Appalachian Mountains. North American areas with Variscan foldbelts include New England, Nova Scotia and Newfoundland and Labrador. The Moroccan Meseta and the Anti-Atlas in northwestern Africa show close relations to the Appalachian Mountains and used to form the eastern part of the Appalachian orogeny before the opening of the Atlantic Ocean in Jurassic times.[11] 'Variscan' mountains in a broad chronological sense include the Urals, the Pamir, the Tian Shan and other Asian foldbelts.[12][13]

Formation

[edit]

The Variscan orogeny involved a complicated heterogeneous assembly of different microplates and heterochronous collisions, making the exact reconstruction of the plate tectonic processes difficult. Plate convergence that caused the Caledonian orogeny in the Silurian continued to form the Variscan orogeny in the succeeding Devonian and Carboniferous Periods. Both orogenies resulted in the assembly of a super-continent, Pangaea, which was essentially complete by the end of the Carboniferous.

In the Ordovician Period, a land mass, which has been named Gondwana (present day South America, Africa, Antarctica, Arabia, the Indian subcontinent, Zealandia and Australia), straddled the space between the South Pole and the Equator on one side of the globe. Off to the west were three other masses: Laurentia, Siberia and Baltica, located as if on the vertices of a triangle. To the south of them was a large archipelago, the terrane Avalonia, rifted off the north Gondwana margin in early Ordovician.

By the end of the Silurian and in Early Devonian times, Baltica and Laurentia drifted towards each other, closing the Iapetus Ocean between them. They collided in the Caledonian orogeny and formed the Caledonide mountains of North America, Greenland, the British Isles and Norway. Seafloor spreading to the south of Avalonia pushed the latter into north Laurentia and thrust up the northern Appalachian Mountains in the acadian phase of the Caledonian orogeny. Contemporaneously the Tornquist Sea between Avalonia and Baltica was entirely closed. Thus Avalonia formed the southern coast of the new continent Euramerica (Laurussia, the Old Red Sandstone continent in present-day North America, the British Isles, northern Germany, Scandinavia and western Russia).

In late Devonian and in the Carboniferous the archipelago Armorica of southern Europe, which had rifted off Gondwana after Avalonia later in the Ordovician, was pushed into Avalonia, creating a second range, the North American/European Variscan, to the east of the Caledonide/Appalachian. The collision of Gondwana proper with Laurussia followed in the early Carboniferous, when the Variscan belt was already in place and actively developing.

By the end of the Carboniferous, Gondwana had united with Laurussia on its western end through northern South America and northwestern Africa. Siberia was approaching from the northeast, separated from Laurussia only by shallow waters. Collision with Siberia produced the Ural Mountains in the latest Paleozoic and completed the formation of Pangaea. Eastern Laurussia was still divided from Gondwana by the Paleotethys Ocean. In the Triassic Period of the Mesozoic Era, animals could move without oceanic impediment from Siberia over the North Pole to Antarctica over the South Pole. In the Mesozoic Era, rifting and subsequent opening of the Atlantic split Pangaea. As a consequence, the Variscan Belt around the then periphery of Baltica ended up many hundreds of miles from the Appalachians.

References

[edit]
  1. ^ Based on Matte 2001 and Ziegler 1990
  2. ^ Kossmat, F. (1927). "Gliederung des varistischen Gebirgsbaus". Abh. Sächs. Geol. L.-A. 1. Leipzig: 1–39.
  3. ^ Google search on December 29, 2007: approximately 44,500 for Variscan orogeny, approximately 15,000 Hercynian orogeny. In German: 1,170 for "variszische Orogenese", 154 for "herzynische Orogenese".
  4. ^ https://books.google.com/ngrams/graph?content=Variscan+*%2CHercynian+*&year_start=1940&year_end=2022&corpus=en&smoothing=3 ; retrieved 17 November 2024
  5. ^ Tectonics of the Devonian. Website of University of California Museum of Paleontology. Accessed on December 29, 2007.
  6. ^ "The Hercynian Orogeny". Historical Geology, University of North Texas.
  7. ^ Lee, K. Y. (1989). "Geology of petroleum and coal deposits in the North China Basin, Eastern China". USGS Bulletin 1871. Archived from the original on 2019-09-13. Retrieved 2017-09-17. Table 1, p. 3.{{cite journal}}: CS1 maint: postscript (link)
  8. ^ Martínez Catalán, José R. (2012-07-01). "The Central Iberian arc, an orocline centered in the Iberian Massif and some implications for the Variscan belt". International Journal of Earth Sciences. 101 (5): 1299–1314. Bibcode:2012IJEaS.101.1299M. doi:10.1007/s00531-011-0715-6. ISSN 1437-3262. S2CID 195334509.
  9. ^ Crespo-Blanc, Ana; Orozco, Miguel (1991-10-01). "The boundary between the Ossa-Morena and Southportuguese Zones (Southern Iberian Massif): Major suture in the European Hercynian Chain". Geologische Rundschau. 80 (3): 691–702. Bibcode:1991GeoRu..80..691C. doi:10.1007/BF01803695. ISSN 1432-1149. S2CID 128688878.
  10. ^ Tectonic Map of the western Tethysides Archived 2008-04-23 at the Wayback Machine. Institute of Geology and Paleontology of the University of Lausanne, Switzerland. Accessed on December 29, 2007.
  11. ^ Burkhard, M.; Caritg, S.; Helg, U.; Robert-Charrue, C.; Soulaimani, A. (2006). "Tectonics of the anti-Atlas of Morocco" (PDF). Comptes Rendus Geoscience. 338 (1): 11–24. Bibcode:2006CRGeo.338...11B. doi:10.1016/j.crte.2005.11.012. Retrieved 1 November 2015.
  12. ^ Paleotethys. Paleogeographic reconstructions for the Devonian and Carboniferous Archived 2011-06-08 at the Wayback Machine. Tethyan Plate Tectonic Working Group of the University of Lausanne, Switzerland. Accessed on December 29, 2007.
  13. ^ Paleogeographic configuration Lower Carboniferous. Paleomap Project by C.Scotese. Accessed on December 29, 2007.

Further reading

[edit]
[edit]