The amalgamation of Pangea: Paleomagnetic and geological observations revisited

The supercontinent Pangea formed by the subduction of the Iapetus and Rheic oceans between Gondwana, Laurentia, and Baltica during mid-to-late Paleozoic times. However, there remains much debate regarding how this amalgamation was achieved. Most paleogeographic models based on paleomagnetic data argue that the juxtaposition of Gondwana and Laurussia (Laurentia-Baltica) was achieved via long-lasting highly oblique convergence in the late Paleozoic. In contrast, many geology-based reconstructions suggest that the collision between the two continents was likely initiated via a Gondwanan promontory comprising the Iberian, Armorican, and Bohemian massifs, and parts of the basement units in the Alpine orogen during the Early Devonian. To help resolve this discrepancy, we present an updated compilation of high-quality paleopoles of mid-to-late Paleozoic ages (spanning Middle Ordovician and Carboniferous times) from Gondwana, Laurentia, and Baltica. These paleopoles were evaluated with the Van der Voo selection criteria, corrected for inclination error where necessary, and were used to revise their apparent polar wander (APW) paths. The revised APW paths were constructed using an innovative approach in which age errors, A95 ovals, and Q-factors of individual paleopoles are taken into account. By combining the resulting APW paths with existing geological data and field relationships in the European Variscides, we provide mid-to-late Paleozoic paleogeographic reconstructions which indicate that the formation of Pangea was likely initiated at 400 Ma via the collision between Laurussia and a ribbon-like Gondwanan promontory that was itself formed by a scissor-like opening of the Paleotethys Ocean, and that the amalgamation culminated in the mostly orthogonal convergence between Gondwana and Laurussia.

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Paleomagnetism and age of three Canadian Rocky Mountain diatremes

Canadian Journal of Earth Sciences ◽

10.1139/e92-005 ◽

1992 ◽

Vol 29 (1) ◽

pp. 35-47 ◽

Cited By ~ 15

Author(s):

P. Jane Wynne ◽

E. Irving ◽

Daniel J. Schulze ◽

Douglas C. Hall ◽

Hewart H. Helmstaedt

Keyword(s):

North America ◽

Rocky Mountains ◽

Rocky Mountain ◽

Canadian Rocky Mountains ◽

Early Devonian ◽

Polar Wander ◽

Middle Ordovician ◽

Normal Polarity ◽

The Cross ◽

Age Estimates

Paleomagnetic results, and age estimates derived from them, arc presented for three diatremes, using as a basis of comparison the combined apparent polar wander (APW) path for North America and Europe of Van der Voo. The Cross diatreme of the Front Ranges of the Canadian Rocky Mountains has yielded a radiometric age of 241 Ma (earliest Triassic) and is hosted by the flat-lying Pennsylvanian Tunnel Mountain Formation. It has normal polarity magnetization and yields a paleopole correctly placed according to its radiometric age on the APW path. The Blackpool diatreme (for which no radiometric age is available), which is located in the Main Ranges of the Rocky Mountains, is known to be post-Late Ordovician because it is hosted by rocks of that age. It also has magnetization of normal polarity and yields a paleopole that, when calculated with respect to present horizontal, is coincident with the latest Cretaceous to Paleocene paleopole for North America. The paleopole, when calculated with respect to bedding, lies on the Middle Ordovician portion of the combined APW path. A clockwise rotation of 10° brings the paleopole into agreement with the latest Ordovician. Hence, from a paleomagnetic standpoint, a latest Cretaceous to Paleocene or latest Ordovician age is possible. The HP pipe (radiometric age 391 ± 5 Ma or Early Devonian), previously studied by D. T. A. Symons and M. T. Lewchuk, is hosted in limestones of Upper Cambrian to Middle Ordovician age. It has reversed polarity and yields a paleopole that, when compared with the combined APW path, suggests an age of mid-Permian, although errors are such that it could be somewhat younger, roughly coeval with the Cross diatreme. We conclude, therefore, that the radiometric age estimated for the HP pipe could be too old by about 130 million years.

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The earliest ostracods from the Ordovician of the Prague Basin, Czech Republic

Acta Geologica Polonica ◽

10.2478/agp-2014-0021 ◽

2014 ◽

Vol 64 (4) ◽

pp. 367-392 ◽

Cited By ~ 5

Author(s):

Karolína Lajblová ◽

Petr Kraft

Keyword(s):

Czech Republic ◽

Bohemian Massif ◽

Massif Central ◽

Central European ◽

Middle Ordovician ◽

Prague Basin ◽

Barrandian Area ◽

Fossil Assemblages ◽

European Variscides

Abstract The earliest ostracods from the Bohemian Massif (Central European Variscides) have been recorded from the Middle Ordovician of the Prague Basin (Barrandian area), in the upper Klabava Formation, and became an abundant component of fossil assemblages in the overlying Šarka Formation. Both early ostracod associations consist of eight species in total, representing mainly eridostracans, palaeocopids, and binodicopids. The revision, description, or redescription of all species and their distribution in the basin is provided. Their diversification patterns and palaeogeographical relationships to ostracod assemblages from other regions are discussed.

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Paleo-environment and reservoir evolution of the Middle Ordovician Kelimoli Formation in the northern Tianhuan area, Ordos Basin, China: implications for high-quality reservoir development

Australian Journal of Earth Sciences ◽

10.1080/08120099.2018.1447996 ◽

2018 ◽

Vol 65 (4) ◽

pp. 535-555

Author(s):

S. W. Mao ◽

J. M. Li ◽

Z. D. Bao ◽

W. Liu ◽

Z. C. Wang ◽

...

Keyword(s):

Ordos Basin ◽

High Quality ◽

Middle Ordovician ◽

Reservoir Development ◽

Reservoir Evolution ◽

High Quality Reservoir

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Fabrication of Crystalline Microresonators of High Quality Factors with a Controllable Wedge Angle on Lithium Niobate on Insulator

Nanomaterials ◽

10.3390/nano9091218 ◽

2019 ◽

Vol 9 (9) ◽

pp. 1218 ◽

Cited By ~ 9

Author(s):

Jianhao Zhang ◽

Zhiwei Fang ◽

Jintian Lin ◽

Junxia Zhou ◽

Min Wang ◽

...

Keyword(s):

Lithium Niobate ◽

Femtosecond Laser ◽

Wedge Angle ◽

Quality Factors ◽

High Quality ◽

Surface Smoothness ◽

High Q ◽

Q Factors

We report the fabrication of crystalline microresonators of high quality (Q) factors with a controllable wedge angle on lithium niobate on insulator (LNOI). Our technique relies on a femtosecond laser assisted chemo-mechanical polish, which allows us to achieve ultrahigh surface smoothness as critically demanded by high Q microresonator applications. We show that by refining the polish parameters, Q factors as high as 4.7 × 107 can be obtained and the wedge angle of the LNOI can be continuously tuned from 9° to 51°.

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Évolution paléogéographique de la marge nord-ouest de l'Afrique du Cambrien à la fin du Carbonifère (du Maroc au Libéria)

Canadian Journal of Earth Sciences ◽

10.1139/e91-101 ◽

1991 ◽

Vol 28 (7) ◽

pp. 1121-1130 ◽

Cited By ~ 6

Author(s):

Michel Villeneuve ◽

Jean-Jacques Cornée

Keyword(s):

West African ◽

The West ◽

Lower Paleozoic ◽

West African Craton ◽

Middle Cambrian ◽

Early Devonian ◽

Middle Ordovician ◽

The North ◽

Marine Platform ◽

General Regression

Paleogeographic reconstructions of Paleozoic time are presented for the northwest margin of the West-African Craton. An extensional regime and a marine transgression were dominant during the Early Cambrian. During the Middle Cambrian, the Rokélides orogen was responsible for the sea regression to the south, while the proto-Atlantic opening was active to the north of the Reguibat shield. A large stable marine platform was present during Early and Middle Ordovician. A general regression and the formation of the West-African Inlandsis took place during the Late Ordovician. During Silurian time, this sea transgressed over most of the African platform. Incipient Hercynian deformations during the Early Devonian produced horsts and grabens in Morocco. At the end of the Devonian and the beginning of the Carboniferous, the sea was restricted to isolated basins and tectonic trenches. Collision between West Africa and North America during the Late Carboniferous transformed the Lower Paleozoic margin into an Hercynian orogenic belt, whose structure is controlled by the presence of crustal blocks, generated as early as the Cambrian, and probably reflecting, in turn, older Panafrican zones of weakness. [Translated by the Journal]

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Permian Hyolithida from Australia: the last of the hyoliths?

Journal of Paleontology ◽

10.1017/s0022336000058212 ◽

2009 ◽

Vol 83 (1) ◽

pp. 147-152 ◽

Cited By ~ 3

Author(s):

John M. Malinky

Keyword(s):

Population Size ◽

Upper Permian ◽

Late Paleozoic ◽

Early Cambrian ◽

Progressive Decline ◽

Early Devonian ◽

Extinction Event ◽

Permian Extinction ◽

Abundance And Diversity ◽

Geologic Record

Class Hyolitha Marek, 1963 encompassing the Order Hyolithida Sysoev, 1957 (Early Cambrian to Upper Permian) and Order Orthothecida Marek, 1966 (Early Cambrian to Early Devonian) consists of a group of conical, calcareous-shelled invertebrates of controversial affinity. One opponent view holds that hyoliths may be reasonably accommodated under the Phylum Mollusca (Malinky and Yochelson, 2007 and references therein), whereas another supports separate phylum status under the name Hyolitha (Pojeta, 1987 and references therein). Hyolith abundance and diversity attain a maximum in the Cambrian, followed by a progressive decline up to their Permian extinction (Fisher, 1962; Wills, 1993). Their demise was part of the extinction event of the Late PermianlEarly Triassic. The cause(s) of this event remains controversial (Erwin et al., 2002), and no imprint remains in the geologic record of the specific circumstances surrounding the disappearance of the hyoliths, though it is highly probable that reduced population size was a contributing factor. Given the overall rarity of Late Paleozoic hyoliths, every occurrence is worthy of note to better understand patterns of hyolith diversity and abundance in the Late Paleozoic, the geographic and stratigraphic distribution of hyolith taxa and circumstances related to their extinction. The species from the Upper Permian described herein is among the youngest, if not the youngest, members of class Hyolitha.

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