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Structural and metamorphic evolution of the Sierras Australes (Buenos Aires Province/Argentina) (1990)

Gosen, W. ; Buggisch, W. ; Dimieri, L. V.

Springer

International journal of earth sciences 79 (1990), S. 797-821

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ISSN: 1437-3262

Source: Springer Online Journal Archives 1860-2000

Topics: Geosciences

Description / Table of Contents: Abstract The Precambrian Basement Complex rocks as well as the Early to Late Palaeozoic cover sediments of the Sierras Australes were affected by one dominant folding and shearing event verging northeastward during Middle to Late Permian times. Strain estimates point to a minimal flattening and lateral shortening of the sedimentary cover sequence of c.20% and c.24% respectively. Continuing rotational deformation within first and second shear and thrust zones is documented by second and third folding and shearing. To the SW the fold belt changes into a fold and thrust belt where imbrication involves the basement. The deformational events were accompanied and outlasted by anchizonal to greenschist facies metamorphism proven by illite crystallinity and quartz deformation and recrystallization data. A temperature increase from ENE to WSW and also from N to S allowed a more ductile deformation of the rock sequence due to different deformation mechanisms operating. The folding and thrusting events were followed by strike-slip shearing on subvertical shear planes and shear zones under an overall sinistral transpressive regime. A model for the tectonic evolution of the Sierras Australes is proposed and some implications for its setting in the Gondwana reconstruction are given.

Abstract: Résumé Les roches du socle précambrien ainsi que la couverture sédimentaire éo- à tardi-paléozoïque des Sierras Australes ont été affectées, au cours du Permien moyen à supérieur, d'un plissement et d'un cisaillement à vergence nord-est. Les déformations sont estimées à au moins 20% d'aplatissement et 24% de raccourcissement latéral. Dans la première et la deuxième zone de cisaillement et de charriage, la déformation rotationnelle continue s'exprime par les deuxième et troisième plissements. Vers le SW la ceinture plissée passe à une ceinture plissée et charriée qui comporte des imbrications du socle. Les déformations ont été accompagnées et suivies d'un métamorphisme de faciès d'anchizone à «schistes verts», ainsi qu'en attestent la cristallinité de l'illite et la déformation et recristallisation du quartz. L'accroissement de la température de l'ENE vers l'WSW ainsi que du N vers le S a donné lieu à des mécanismes de déformation de caractère de plus en plus ductile. La phase de plissement et de charriage a été suivie par un régime de cisaillements décrochants sénestres le long de plans et de shear-zones subverticaux. Les auteurs proposent un modèle de l'évolution tectonique des Sierras Australes et discutent de son insertion dans la reconstruction du Gondwana.

Notes: Zusammenfassung Das präkambrische Basement sowie die alt- und jungpaläozoischen Deckschichten der Sierras Australes wurden während des Mittl. bis Ob. Perm von einer NE vergenten Faltung und Scherung erfaßt. Strain-Abschätzungen deuten auf eine minimale Plättung und laterale Verkürzung der Sedimentfolge von ca. 20% bzw. 24%. Die fortlaufende relationale Deformation in den ersten und zweiten Scher- und Überschiebungszonen ist durch zweite und dritte Faltung mit Scherung dokumentiert. Der Sierras Australes-Faltengürtel geht nach SW in einen Falten-Überschiebungsgürtel über, dessen nach NE gerichtete Imbrikationen das Basement einbeziehen. Daten der Illit-Kristallinität und Quarz-Deformation/-Rekristallisation zeigen, daß die Deformationen von anchizonaler bis seicht-grünschieferfazieller Metamorphose begleitet und überdauert wurden. Mit der von ENE nach WSW bzw. N nach S zunehmenden Temperierung setzten verschiedene Deformationsmechanismen ein. Sie ermöglichten eine zunehmend duktile Verformung der Gesteinsfolgen. Auf die Faltungen und Auf-/Überschiebungen folgten Lateralverschiebungen an subvertikalen Scherflächen und -zonen unter einem sinistralen transpressiven Regime. Für die tektonische Entwicklung der Sierras Australes wird ein Modell vorgeschlagen, und die Folgerungen für die Stellung in der Gondwana-Rekonstruktion werden angeführt.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01879216

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The Eurekan deformation in the Arctic: an outline (2016)

Piepjohn, K., von Gosen, W., Tessensohn, F.

Geological Society of London

In: Journal of the Geological Society

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Publication Date: 2016-11-09

Description: The evolution of the Eurekan deformation zones in the Arctic is closely related to the development of the circum-Greenland plate boundaries in Early Cenozoic times (53 – 34 Ma). Mostly, the Eurekan Orogeny or deformation has been interpreted as a predominantly compressive tectonic event, but the Eurekan deformational history in the Arctic was not the result of a single tectonic episode. It rather represents a complex sequence of successive tectonic stages, which produced a number of intra-continental deformation zones with changing, sometimes opposing, lateral, oblique and convergent kinematics in the Canadian Arctic Archipelago, north and NE Greenland, and Svalbard. The interaction between the continental plates, especially in combination with the development of transform faults, resulted onshore in the formation of several complex deformation zones and areas of Eurekan deformation. The Eurekan deformation can be divided into two major tectonic stages: the first phase in the Early Eocene was dominated by orthogonal compression in the West Spitsbergen Fold-and-Thrust Belt along the west margin of the Barents Shelf and contemporaneous sinistral strike-slip tectonics along the Wegener Fault and on Ellesmere Island, whereas the second phase in the Late Eocene was characterized by dextral strike-slip and compression on Ellesmere Island and contemporaneous dextral transpression and transtension along the De Geer Fracture Zone or Hornsund Fault Complex between NE Greenland and Spitsbergen.

Print ISSN: 0016-7649

Topics: Geosciences

Published by Geological Society of London

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Structural transect through Ellesmere Island (Canadian Arctic): superimposed Palaeozoic Ellesmerian and Cenozoic Eurekan deformation (2017)

Piepjohn, K., von Gosen, W.

Geological Society (of London)

In: Special Publications / Geological Society London

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Publication Date: 2017-09-30

Description: The 400 km long transect through Ellesmere Island is located perpendicular to the North American continental margin between the Arctic Ocean in the NNW and the Greenland–Canadian Shield in the SSE. It provides an insight into the structural architecture and tectonic history of the upper parts of the continental crust. The northernmost segment of the transect is dominated by the composite Pearya Terrane, which amalgamated with the Laurentian margin during the Late Devonian–Early Carboniferous Ellesmerian Orogeny. The Neoproterozoic to Devonian Franklinian Basin is exposed south of the terrane boundary and most probably overlies the crystalline basement of the Greenland–Canadian Shield. The structures along the transect in this area are dominated by kilometre-scale Ellesmerian folding of the Franklinian Basin deposits above a deep-seated detachment, which is suggested to be located at the boundary between the basement of the Canadian Shield and the overlying 〉8 km thick Franklinian Basin. Following the development of the Late Mississippian–Palaeogene Sverdrup Basin, the complex Eurekan deformation reactivated Ellesmerian thrust faults and probably parts of the associated deep-seated detachment. In addition, large Eurekan strike-slip faults affected and displaced pre-Eocene deposits and tectonic structures, particularly in the northern part of the transect. Supplementary material: The complete transect (Segment 1 to 5) through Ellesmere Island between the Arctic Ocean in the NNW and Kane Basin in the SSE is available at https://doi.org/10.6084/m9.figshare.c.3783608

Print ISSN: 0305-8719

Electronic ISSN: 2041-4927

Topics: Geosciences

Published by Geological Society (of London)

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Mesozoic structural evolution of the New Siberian Islands (2017)

Piepjohn, K., Lorenz, H., Franke, D., Brandes, C., von Gosen, W., Gaedicke, C., Labrousse, L., Sobolev, N. N., Solobev, P., Suan, G., Mrugalla, S., Talarico, F., Tolmacheva, T.

Geological Society (of London)

In: Special Publications / Geological Society London

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Publication Date: 2017-09-30

Description: The New Siberian Islands are affected by a number of Mesozoic tectonic events. The oldest event (D1a) is characterized by NW-directed thrusting within the South Anyui Suture Zone combined with north–south-trending sinistral strike-slip in the foreland during the Early Cretaceous. This compressional deformation was followed by dextral transpression along north–south-trending faults, which resulted in NE–SW shortening in the Kotelny Fold Zone (D1b). The dextral deformation can be related to a north–south-trending boundary fault zone west of the New Siberian Islands, which probably represented the Laptev Sea segment of the Amerasia Basin Transform Fault in pre-Aptian–Albian times. The presence of a transform fault west of the islands may be an explanation for the long and narrow sliver of continental lithosphere of the Lomonosov Ridge and the sudden termination of the South Anyui Suture Zone against the present Laptev Sea Rift System. The intrusion of magmatic rocks 114 myr ago was followed by NW–SE-trending sinistral strike-slip faults of unknown origin (D2). In the Late Cretaceous–Paleocene, east–west extension (D3) west of the New Siberian Islands initiated the development of the Laptev Sea Rift System, which continues until today and is largely related to the development of the Eurasian Basin.

Print ISSN: 0305-8719

Electronic ISSN: 2041-4927

Topics: Geosciences

Published by Geological Society (of London)

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Geochronology of igneous rocks in the Sierra Norte de Cordoba (Argentina): Implications for the Pampean evolution at the western Gondwana margin (2014)

von Gosen, W., McClelland, W. C., Loske, W., Martinez, J. C., Prozzi, C.

Geological Society of America (GSA)

In: Lithosphere

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Publication Date: 2014-08-01

Description: U-Pb zircon data (secondary ion mass spectrometry [SIMS] and thermal ionization mass spectrometry [TIMS] analyses) from igneous rocks with differing structural fabrics in the Sierra Norte de Córdoba, western Argentina, suggest that the sedimentary, tectonic, and magmatic history in this part of the Eastern Sierras Pampeanas spans the late Neoproterozoic–Early Cambrian. A deformed metarhyolite layer in metaclastic sedimentary rocks gives a crystallization age of 535 ± 5 Ma, providing a limit on the timing of the onset of D 1 deformation and metamorphism. The new data coupled with published Neoproterozoic zircon dates from a rhyolite beneath the metaclastic section and detrital zircon ages from the section indicate a late Neoproterozoic to Early Cambrian depositional age, making this section time equivalent with the Puncoviscana Formation (sensu lato) of northwest Argentina. A synkinematic granite porphyry gives a crystallization age of 534 ± 5 Ma, providing a limit on the age of dextral mylonitization in the Sierra Norte area (D 2 event). The new age is consistent with ages of 533 ± 4 Ma from a mylonitic granite with dextral sense-of-shear fabrics and 531 ± 4 Ma from a late-synkinematic dacitic porphyry, which broadly indicates the final age of dextral deformation. A crystallization age of zircons from the postkinematic, high-level El Tío granite (530 ± 4 Ma) suggests that both stages of Pampean deformation and regional metamorphism, accompanied by synkinematic intrusions, were followed by uplift and took place during a very short time span in the Early Cambrian. This is supported by zircon dates of 523 ± 5 Ma from a rhyolite to dacite in the western part of the Rodeito area and dates from the undeformed El Escondido rhyolite and granite of 519 ± 4 Ma and 521 ± 4 Ma, respectively. These three crystallization ages also indicate that ductile dextral shearing and mylonitization associated with the Pampean D 2 event terminated in the Early Cambrian. Both stages of Pampean deformation in this segment of the western pre-Andean Gondwana margin seem to represent a continuous event that can be related to oblique dextral convergence between the overriding plate in the east and the subducting and finally colliding plate in the west. The postkinematic intrusions and extrusions are related to the late stage of the Pampean magmatic history, which terminated before Early Ordovician (Famatinian) time.

Print ISSN: 1941-8264

Electronic ISSN: 1947-4253

Topics: Geosciences

Published by Geological Society of America (GSA)

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Integrated crustal-geological cross-section of Ellesmere Island (2017)

Stephenson, R., Piepjohn, K., Schiffer, C., Von Gosen, W., Oakey, G. N., Anudu, G.

Geological Society (of London)

In: Special Publications / Geological Society London

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Publication Date: 2017-05-25

Description: The crustal seismic velocity model (based on receiver functions) of Ellesmere Island and the structural geological cross-section of Ellesmere Island, both documented and discussed elsewhere in this volume, are here integrated into a crustal-scale transect crossing all the main tectonic domains. The velocity model satisfies much of the observed gravity field, but implies minor modifications with potentially important implications for characterizing the lower crust over the transect. The crust of the Pearya Terrane includes a high-velocity and high-density lower crustal body, suggested to represent a mafic underplate linked to the emplacement of the High Arctic Large Igneous Province. A similar body also lies directly beneath the Hazen Plateau, but this is more likely to be inherited from earlier tectonic stages than to be linked to the High Arctic Large Igneous Province. A large-scale basement-involving thrust, possibly linked to a deep detachment of Ellesmerian age, lies immediately south of the Pearya Terrane and forms the northern backdrop to a crustal-scale pop-up structure that accommodates Eurekan-aged shortening in northern Ellesmere Island. The thickest crust and deepest Moho along the transect are below the Central Ellesmerian fold belt, where the Moho is flexured downwards to the north to a depth of about 48 km beneath the load of the structurally thickened supracrustal strata of the fold belt.

Print ISSN: 0305-8719

Electronic ISSN: 2041-4927

Topics: Geosciences

Published by Geological Society (of London)

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