Saxothuringian Zone

Last updated July 11, 2021

The Saxothuringian Zone, Saxo-Thuringian zone^[2] or Saxothuringicum is in geology a structural or tectonic zone in the Hercynian or Variscan orogen (380-270 million years old) of central and western Europe. Because rocks of Hercynian age are in most places covered by younger strata, the zone is not everywhere visible at the surface. Places where it crops out are the northern Bohemian Massif, the Spessart, the Odenwald, the northern parts of the Black Forest and Vosges and the southern part of the Taunus. West of the Vosges terranes on both sides of the English Channel are also seen as part of the zone, for example the Lizard complex in Cornwall or the Léon Zone of the Armorican Massif (Brittany).

Location

In central Europe the Saxothuringian Zone is situated between the Rhenohercynian Zone to the northwest and the Moldanubian Zone to the southeast.^[3] The Hercynian metamorphism of the former zone is generally lower grade; that of the latter zone higher grade than that of the Saxothuringian Zone. West of the Vosges the zone is displaced to the north by a major strike-slip fault, the Bray Fault.

The Saxothuringian Zone is in some places transected by Permo-Triassic grabens and intramontane basins filled with Rotliegend sediments and older deposits. The Eger Graben in the northwest of the Czech Republic and the Saar-Nahe Basin in western Germany are examples of such structures.

Geology

The Saxothuringian Zone consists of early Paleozoic marine sediments that were deposited in the Saxothuringian Basin. They were slightly metamorphosed during the Hercynian orogeny. The sedimentary sequence is assumed to be continuous from the Ediacaran to the Visean (330 million years ago).^[4] These metasediments form a wide zone north of the city of Dresden in Saxony.^[5]

Tectonostratigraphically, gneisses (high-grade metamorphic rocks) and granites are found under these metasediments. They crop out as the competent massifs of the Ore Mountains and Saxonian Granulite Massif. They were deformed and recrystallized during the Cadomian orogeny (in the Ediacaran, 650-550 million years ago) and intruded by felsic plutons during the Cambrian and Ordovician (540-420 million years ago).

In some places klippes of allochthonous crystalline rocks are found on top of these two units. These klippes are the Münchberg complex, Wildenfels complex and Frankenberg complex. They consisted originally of a sequence of deep-marine (flysch) sediments of Ordovician to Devonian age (480-360 million years old) and early Paleozoic mid-oceanic ridge basalts. The latter have been metamorphosed at a high grade (up to eclogite facies). These allochthonous nappes can probably be correlated with the Teplá terrane in the Moldanubian Zone further south.^[6]

The Saxothuringian Zone is often also supposed to include the Mid-German Crystalline High, which then forms the northern part of the zone and lies directly next to the Rhenohercynian Northern Phyllite Zone. The Mid-German Crystalline High crops out in the Odenwald, the Spessart and the northern Vosges. It consists of Proterozoic orthogneisses and early Paleozoic volcanic (amphibolites with MORB-protoliths and tuffs) and sedimentary (pelites, calcareous schists and marbles) rocks that were metamorphosed at high grade during the Hercynian orogeny (up to amphibolite facies). These rocks were intruded by two generations of plutons: Silurian to Early Devonian (440-400 million years old) granitoids and middle Carboniferous (Hercynian, 340-325 million years old) granites.^[7]

Notes

↑ Map is based on Franke (1992, 2000), Matte (2001), von Raumer et al. (2003) and Walter (2003)
↑ Kohl, Horst; Marcinek, Joachim and Nitz, Bernhard (1986). Geography of the German Democratic Republic, VEB Hermann Haack, Gotha, pp. 8 ff. ISBN 978-3-7301-0522-1.
↑ The subdivision of the central European Hercynian orogen in zones was first made by Kossmat (1927)
↑ Kroner et al. (2007); Franke (2000)
↑ For an overview see for example Linnemann (1995)
↑ Matte et al. (1990)
↑ Oncken (1997); Franke (2000)

Bibliography

Franke, W.; 1992: Phanerozoic structures and events in central Europe, in: Blundell, D.J.; Freeman, R. & Mueller, S. (eds.): A Continent Revealed - The European Geotraverse, 297 pp., Cambridge University Press, ISBN 0-521-42948-X, pp. 164–179.
Franke, W.; 2000: The mid-European segment of the Variscides: tectonostratigraphic units, terrane boundaries and plate tectonic evolution, in: Franke, W.; Haak, V.; Oncken, O. & Tanner, D. (eds.); Orogenic Processes, Quantification and Modelling in the Variscan Belt, Geological Society of London, Special Publications 179, pp. 35–61.
Kossmat, F. ; 1927: Gliederung des varistischen Gebirgsbaues, Abhandlungen des Sächsischen Geologischen Landesamtes 1, pp. 1–39.
Kroner, U.; Hahn, T.; Romer, R.L. & Linnemann, U.; 2007: The Variscan orogeny in the Saxo-Thuringian zone - heterogeneous overprint of Cadomian/Paleozoic Peri-Gondwana crust, in: Linnemann, U.; Nance, R.D.; Kraft, P. & Zulauf, G. (eds.): The evolution of the Rheic Ocean: from Avalonian-Cadomian active margin to Alleghenian-Variscan collision, Geological Society of America Special Paper 423 pp. 153–172.
Linnemann, U.-G.; 1995: The Neoproterozoic terranes of Saxony (Germany), Precambrian Research 73, pp. 235–250.
Matte, P.; 2001: The Variscan collage and orogeny (480±290 Ma) and the tectonic definition of the Armorica microplate: a review, Terra Nova 13, 122-128.
Matte, P.; Maluski, H.; Rajlich, P. & Franke, W.; 1990: Terrane boundaries in the Bohemian Massif: Result of large-scale Variscan shearing, Tectonophysics 177, pp. 151–170.
Oncken, O.; 1997: Transformation of a magmatic arc and an orogenic root during oblique collision and its consequences for the evolution of the European Variscides (Mid-German Crystalline Rise), Geologische Rundschau 86, pp. 2–20.
Raumer, J.F. von; Stampfli, G.M. & Bussy, F.; 2003: Gondwana-derived microcontinents — the constituents of the Variscan and Alpine collisional orogens, Tectonophysics 365, pp. 7–22.
Linnemann, Ulf; & Romer, Rolf; 2010: Pre-Mesozoic Geology of Saxo-Thuringia 488 p. ISBN 978-3-510-65259-4
Walter, R.; 2003: Erdgeschichte – Die Entstehung der Kontinente und Ozeane, 325 pp., Walter de Gruyter, Berlin (5^e druk), ISBN 3-11-017697-1.

Related Research Articles

The Caledonian orogeny was a mountain-building era recorded in the northern parts of the British Isles, the Scandinavian Mountains, Svalbard, eastern Greenland and parts of north-central Europe. The Caledonian orogeny encompasses events that occurred from the Ordovician to Early Devonian, roughly 490–390 million years ago (Ma). It was caused by the closure of the Iapetus Ocean when the continents and terranes of Laurentia, Baltica and Avalonia collided.

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

The London-Brabant Massif or London-Brabant Platform is, in the tectonic structure of Europe, a structural high or massif that stretches from the Rhineland in western Germany across northern Belgium and the North Sea to the sites of East Anglia and the middle Thames in southern England.

The Rheic Ocean was an ocean which separated two major palaeocontinents, Gondwana and Laurussia (Laurentia-Baltica-Avalonia). One of the principal oceans of the Palaeozoic, its sutures today stretch 10,000 km (6,200 mi) from Mexico to Turkey and its closure resulted in the assembly of the supercontinent Pangaea and the formation of the Variscan–Alleghenian–Ouachita orogenies.

The Rhenish Massif, Rhine Massif or Rhenish Uplands is a geologic massif in western Germany, eastern Belgium, Luxembourg and northeastern France. It is drained centrally, south to north by the river Rhine and a few of its tributaries.

The Armorican Massif is a geologic massif that covers a large area in the northwest of France, including Brittany, the western part of Normandy and the Pays de la Loire. It is important because it is connected to Dover on the British side of the English Channel and there has been tilting back and forth that has controlled the geography on both sides.

The Rhenohercynian Zone or Rheno-Hercynian zone in structural geology describes a fold belt of west and central Europe, formed during the Hercynian orogeny. The zone consists of folded and thrusted Devonian and early Carboniferous sedimentary rocks that were deposited in a back-arc basin along the southern margin of the then existing paleocontinent Laurussia.

The Giessen nappe is a tectonic nappe in the southeastern part of the Rhenish Massif in western Germany. The nappe is an "alien" (allochthonous) unit in the Rhenohercynian zone of the Hercynian orogeny, it was thrusted over the usual slightly metamorphosed Devonian and Carboniferous sedimentary rocks in this zone.

The Mid-German Crystalline High is a structural high in the Paleozoic geology of Germany. The high forms a northeast-southwest oriented zone through Germany, but actual rock outcrops are sparse since Paleozoic basement rocks are in most of central Germany overlain by younger sedimentary rocks. The Mid-German Crystalline High crops out in the Odenwald, the Spessart, the northern Vosges and some small other massifs.

The Bohemian Massif is in the geology of Central Europe a large massif stretching over the central Czech Republic, eastern Germany, southern Poland and northern Austria. It is surrounded by four ranges: the Ore Mountains in the northwest, the Sudetes in the northeast, the Bohemian-Moravian Highlands in the southeast, and the Bohemian Forest (Šumava) in the southwest. The massif encompasses a number of mittelgebirges and consists of crystalline rocks, which are older than the Permian and therefore deformed during the Variscan Orogeny.

The Moldanubian Zone is in the regional geology of Europe a tectonic zone formed during the Variscan or Hercynian Orogeny. The Moldanubian Zone crops out in the Bohemian Massif and the southern part of the Black Forest and Vosges and contains the highest grade metamorphic rocks of Variscan age in Europe.

The Western Carpathians are an arc-shaped mountain range, the northern branch of the Alpine-Himalayan fold and thrust system called the Alpide belt, which evolved during the Alpine orogeny. In particular, their pre-Cenozoic evolution is very similar to that of the Eastern Alps, and they constitute a transition between the Eastern Alps and the Eastern Carpathians.

The Gotthard nappe is, in the geology of the Alps a nappe in the Helvetic zone of Switzerland. It consists of crystalline rocks that were, before the formation of the Alps, part of the upper crust of the southern margin of the European continent. As it names suggests, the Gotthard nappe lies in close proximity to the Gotthard Massif.

The Massif Central is one of the two large basement massifs in France, the other being the Armorican Massif. The Massif Central's geological evolution started in the late Neoproterozoic and continues to this day. It has been shaped mainly by the Caledonian orogeny and the Variscan orogeny. The Alpine orogeny has also left its imprints, probably causing the important Cenozoic volcanism. The Massif Central has a very long geological history, underlined by zircon ages dating back into the Archaean 3 billion years ago. Structurally it consists mainly of stacked metamorphic basement nappes.

The Pyrenees are a 430-kilometre-long, roughly east–west striking, intracontinental mountain chain that divide France, Spain, and Andorra. The belt has an extended, polycyclic geological evolution dating back to the Precambrian. The chain's present configuration is due to the collision between the microcontinent Iberia and the southwestern promontory of the European Plate. The two continents were approaching each other since the onset of the Upper Cretaceous (Albian/Cenomanian) about 100 million years ago and were consequently colliding during the Paleogene (Eocene/Oligocene) 55 to 25 million years ago. After its uplift, the chain experienced intense erosion and isostatic readjustments. A cross-section through the chain shows an asymmetric flower-like structure with steeper dips on the French side. The Pyrenees are not solely the result of compressional forces, but also show an important sinistral shearing.

The Armorican terrane, Armorican terrane assemblage, or simply Armorica, was a microcontinent or group of continental fragments that rifted away from Gondwana towards the end of the Silurian and collided with Laurussia towards the end of the Carboniferous during the Variscan orogeny. The name is taken from Armorica, the Gaulish name for a large part of northwestern France that includes Brittany, as this matches closely to the present location of the rock units that form the main part of this terrane.

The geology of Germany is heavily influenced by several phases of orogeny in the Paleozoic and the Cenozoic, by sedimentation in shelf seas and epicontinental seas and on plains in the Permian and Mesozoic as well as by the Quaternary glaciations.

The geology of Sudan formed primarily in the Precambrian, as igneous and metamorphic crystalline basement rock. Ancient terranes and inliers were intruded with granites, granitoids as well as volcanic rocks. Units of all types were deformed, reactivated, intruded and metamorphosed during the Proterozoic Pan-African orogeny. Dramatic sheet flow erosion prevented almost any sedimentary rocks from forming during the Paleozoic and Mesozoic. From the Mesozoic into the Cenozoic the formation of the Red Sea depression and complex faulting led to massive sediment deposition in some locations and regional volcanism. Sudan has petroleum, chromite, salt, gold, limestone and other natural resources.

The Tuhua orogeny was a regional orogeny between 370 and 330 million years ago, now preserved in the Fiordland region of New Zealand. Early Paleozoic rocks such as Ordovician greywacke, slate and paragneiss in the Buller terrane, weakly metamorphosed greenschist and sub-greenschist rocks, Cambrian mafic volcanics, Ordovician limestone and Silurian clastic rocks were all deformed and metamorphosed. In addition, between 380 and 250 million years ago, metasediments reached amphibolite grade in the sequence of metamorphic facies.

The geology of the Czech Republic is highly tectonically complex, split between the Western Carpathian Mountains and the Bohemian Massif.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[1] Map is based on Franke (1992, 2000), Matte (2001), von Raumer et al. (2003) and Walter (2003)

[2] Kohl, Horst; Marcinek, Joachim and Nitz, Bernhard (1986). Geography of the German Democratic Republic, VEB Hermann Haack, Gotha, pp. 8 ff. ISBN 978-3-7301-0522-1.

[3] The subdivision of the central European Hercynian orogen in zones was first made by Kossmat (1927)

[4] Kroner et al. (2007); Franke (2000)

[5] For an overview see for example Linnemann (1995)

[6] Matte et al. (1990)

[7] Oncken (1997); Franke (2000)

[2]

[3]

[4]

[5]

[6]

[7]