The Paleozoic Evolution of the Olga Basin Region, Northern Barents Sea: A Link to the Timanian Orogeny

Klitzke, Peter; Franke, Dieter; Ehrhardt, A.; Lutz, Rüdiger; Reinhardt, Lutz; Heyde, Ingo; Faleide, Jan Inge

doi:10.1029/2018gc007814

Cited by 33 publications

(39 citation statements)

References 79 publications

(210 reference statements)

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“…North of the Olga Basin (77°N), the trend of faults and lineaments associated with the structure of crystalline basement is roughly SW–NE to SSW–NNE, following the general trend of the mid‐Carboniferous rifts within the Caledonian domain (Faleide et al, 2008; Grogan et al, 1999). Southward structures are NW–SE oriented following the Timanian structural trend (Faleide et al, 2018; Hassaan et al, 2020; Klitzke et al, 2019; Riztmann & Faleide, 2009).…”

Section: Resultsmentioning

confidence: 99%

“…In the north, large parts of the Kong Karl Platform are marked by NNE trending anticlines ( at x = 50 km in Figures 1b and 1d ) developed above normal faults (Grogan et al, 1999). These structures correlate with the NNE–SSW strike of Caledonian thrusts and nappes in the north (Barrère et al, 2009, 2011; Gernigon et al, 2014; Gernigon & Brönner, 2012; Klitzke et al, 2019). The faults are mainly extensional and their ages are Paleozoic (Kairanov et al, 2018).…”

Section: Observationsmentioning

confidence: 93%

“…The graben system follows the NW‐SE orientation of the Timanian terrane grain that extends from the Pechora system to the Norwegian SE Barents Sea (Gernigon et al, 2018; Roberts & Siedlecka, 2002; Shulgin et al, 2018). Based on the analysis of magnetic and gravity anomaly trends, Klitzke et al (2019) proposed the Timanian terrane extends further north, incorporating the Olga‐Sørkapp Basin system. The transect ends at the border of the Finnmark Platform and is marked by shallowing of sediment layers approaching the Fennoscandian craton.…”

Section: Observationsmentioning

confidence: 99%

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Deformation Analysis in the Barents Sea in Relation to Paleogene Transpression Along the Greenland‐Eurasia Plate Boundary

et al. 2020

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Late Cretaceous-Cenozoic contractional structures are widespread in the Barents Sea. While the exact dating of the deformation is unclear, it can only be inferred that the contraction is younger than the early Cretaceous. One likely contractional mechanism is related to Greenland Plate kinematics at Paleogene times. We use a thin sheet finite element modeling approach to compute deformation within the Barents Sea in response to the Greenland-Eurasia relative motions during the Paleogene. The analytical solution for the 3-D folding of sediments above basement faults is used to assess possibilities for folding. Two existing Greenland Plate kinematic models, differing slightly in the timing, magnitude, and direction of motion, are tested. Results show that the Greenland Plate's general northward motion promotes growing anticlines in the entire Barents Sea shelf. Our numerical models suggest that the fan-shaped pattern of cylindrical anticlines in the Barents Sea can be associated with the Eurekan deformation concurrent to the initial rifting and early seafloor spreading in the northeast Atlantic. The main contraction phase in the SW Barents Sea coincides with the timing of continental breakup, whereas the peak of deformation predicted for the NW Barents Sea occurred at later times. Svalbard has experienced a prolonged period of compressional deformation. We conclude that Paleogene Greenland Plate kinematics are a likely candidate to explain contractional structures in the Barents Sea.

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Section: Resultsmentioning

confidence: 99%

Section: Observationsmentioning

confidence: 93%

Section: Observationsmentioning

confidence: 99%

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Deformation Analysis in the Barents Sea in Relation to Paleogene Transpression Along the Greenland‐Eurasia Plate Boundary

et al. 2020

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“…The Timanian fold-and-thrust belt records ocean-continent collisions along the northern margin of Baltica and the accretion of island arc complexes, terranes and microcontinents at ~0.62-0.55 Ga stretching from the Scandinavian Arctic to the Arctic Urals (Roberts and Siedlecka 2002;Gee and Pease 2004;Gee et al 2006Gee et al , 2008. The Trollfjorden-Komagelva Fault Zone is a major Timanian structure extending from the Urals across the Timan Range to northernmost Norway, where it was later reworked by the Caledonides (Gernigon and Brönner 2012;Gernigon et al 2014Gernigon et al , 2018Klitzke et al 2019). Neoproterozoic Timanian basement terranes, metasediments and volcanic sequences were drilled in the Pechora Basin (Roberts and Siedlecka 2002;Dovzhikova et al 2004).…”

Section: The Timanian Orogenymentioning

confidence: 99%

“…The Timanian suture may be deeply buried in the central Barents Sea (Gernigon et al 2018) possibly associated with high velocity-high density lower crustal rocks (Shulgin et al 2018). Basement structures in the eastern and central Barents Sea show a persistent NW-SE oriented Timanian fabric throughout the region (Gee et al 2006(Gee et al , 2008Pease 2011;Klitzke et al 2019). The Torellian orogeny on Svalbard may be a Timanian equivalent or prolongation (Majka et al 2008).…”

Section: The Timanian Orogenymentioning

confidence: 99%

Structural inheritance in the North Atlantic

Schiffer

Doré²,

Foulger

et al. 2020

Earth-Science Reviews

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The North Atlantic, extending from the Charlie Gibbs Fracture Zone to the north Norway-Greenland-Svalbard margins, is regarded as both a classic case of structural inheritance and an exemplar for the Wilson-cycle concept. This paper examines different aspects of structural inheritance in the Circum-North Atlantic region: 1) as a function of rejuvenation from lithospheric to crustal scales, and 2) in terms of sequential rifting and opening of the ocean and its margins, including a series of failed rift systems. We summarise and evaluate the role of fundamental lithospheric structures such as mantle fabric and composition, lower crustal inhomogeneities, orogenic belts, and major strike-slip faults during breakup. We relate these to the development and shaping of the NE Atlantic rifted margins, localisation of magmatism, and microcontinent release. We show that, although inheritance is common on multiple scales, the Wilson Cycle is at best an imperfect model for the Circum-North Atlantic region. Observations from the NE Atlantic suggest depth dependency in inheritance (surface, crust, mantle) with selective rejuvenation depending on timescales , stress field orientations and thermal regime. Specifically, post-Caledonian reactivation to form the North Atlantic rift systems essentially followed pre-existing orogenic crustal structures, while eventual breakup reflected a change in stress field and exploitation of a deeper-seated, lithospheric-scale shear fabrics. We infer that, although collapse of an orogenic belt and eventual transition to a new ocean does occur, it is by no means inevitable.

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Eastern Europe: The Timanian and Uralian Orogens

Pease¹

2021

Encyclopedia of Geology

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The Paleozoic Evolution of the Olga Basin Region, Northern Barents Sea: A Link to the Timanian Orogeny

Cited by 33 publications

References 79 publications

Deformation Analysis in the Barents Sea in Relation to Paleogene Transpression Along the Greenland‐Eurasia Plate Boundary

Deformation Analysis in the Barents Sea in Relation to Paleogene Transpression Along the Greenland‐Eurasia Plate Boundary

Structural inheritance in the North Atlantic

Eastern Europe: The Timanian and Uralian Orogens

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