The mid-Norwegian margin: a discussion of crustal lineaments, mafic intrusions, and remnants of the Caledonian root by 3D density modelling and structural interpretation

Ebbing, J.; Lundin, Erik; Olesen, Odleiv; Hansen, E. K.

doi:10.1144/0016-764905-029

Cited by 65 publications

(82 citation statements)

References 42 publications

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“…More recently acquired refraction data (Breivik et al, 2011;Kvarven et al, 2014) and potential field-based crustal models provide additional constraints (e.g., Ebbing et al, 2006;Ebbing & Olesen, 2010). Recent works on hyperextended margins elsewhere have presented a number of concepts that should be considered when discussing the Norwegian margin (e.g., Blaich et al, 1997;Osmundsen & Ebbing, 2008;Péron-Pinvidic et al, 2013).…”

Section: Figure 1 Map Of the Mid Norway Rifted Margin Showing Main Smentioning

confidence: 99%

“…To constrain the crustal thickness along the seismic reflection profiles used in this study, we have used existing 3D geophysical models of the Mid-Norwegian margin as a basis (e.g., Ebbing et al, 2006Ebbing et al, , 2009Reynisson et al, 2011Kvarven et al, 2014. We have employed the gravity and magnetic data described above and the IGMAS, which calculates the potential field effect of a crustal model by triangulation between modelling planes (Götze & Lahmeyer, 1988), to expand and refine the 3D models used in previous works (see Ebbing et al, 2006;Osmundsen & Ebbing, 2008;Reynisson et al, 2011 for details). The most important parameters in the construction of the 3D model are the crustal geometry and petrophysical properties (density, magnetic susceptibility and Q-ratio) for the crust and upper mantle.…”

Section: D Potential-field Based Crustal Modelmentioning

confidence: 99%

“…The deep structure of the Møre margin has been updated using the results of three modelled OBS profiles by Kvarven et al (2014). For a more detailed discussion on velocity, density and magnetic parameters, see Ebbing et al (2006Ebbing et al ( , 2009 and Kvarven et al (2014). The modelled parameters for the different stratigraphic units and crystalline crustal types (Table 2) were based on data obtained from basement 2011; Franke, 2012;Péron-Pinvidic et al, 2013;Savva et al, 2014;Stica et al, 2014;Tugend et al, 2014).…”

Section: D Potential-field Based Crustal Modelmentioning

confidence: 99%

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Extension, hyperextension and mantle exhumation offshore Norway: a discussion based on 6 crustal transects

Osmundsen¹,

Péron‐Pinvidic²,

Ebbing³

et al. 2017

NJG

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In spite of its classification as `magmatic´, the rifted margin off Mid Norway evolved as a hyperextended margin in Late Jurassic and Cretaceous time, with a pre-breakup structural evolution that resembles that of magma-poor margins. Because the distal margin was not drilled to crystalline basement, considerable uncertainty exists with respect to the distribution of lithologies at depth. In this contribution, we discuss the implications of various scenarios for deep-seated lithologies and evaluate the possibilities for mantle exhumation in the deep margin offshore Norway. A suite of JurassicCretaceous, very large-magnitude, extensional faults that exhumed successively deeper structural levels seawards are well imaged in recent long-offset seismic reflection data. Based on these key profiles, we document the structural configuration that created the extremely sharply tapered south Møre margin as well as subhorizontal detachment faults in the distal Vøring margin. The latter were associated with rotated extensional allochthon and supradetachment basins and contributed to the exhumation of very deep levels including rocks from the lower crust and/or upper mantle. In the outer margin, truncation and excision of this system by a new set of incising detachment faults occurred later in the Cretaceous and the earliest Cenozoic. We discuss the relationships between these detachment systems under the distal and outer margins and positive structural features such as the Rån and Gjallar ridges. The interpretation of basement lithologies at depth in the distal margin is ambiguous due to overlap in physical properties. Based on a process-oriented evaluation of the different interpretation scenarios, we favour a model where mantle windows were exhumed in the footwalls of some of the master faults in the Cretaceous.

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Section: Figure 1 Map Of the Mid Norway Rifted Margin Showing Main Smentioning

confidence: 99%

Section: D Potential-field Based Crustal Modelmentioning

confidence: 99%

Section: D Potential-field Based Crustal Modelmentioning

confidence: 99%

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Extension, hyperextension and mantle exhumation offshore Norway: a discussion based on 6 crustal transects

Osmundsen¹,

Péron‐Pinvidic²,

Ebbing³

et al. 2017

NJG

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show abstract

“…These are plotted in Figure 10, the values broadly derived from the work of Ebbing et al (2006). From the depth to basement map we generated a total sediment thickness map.…”

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confidence: 99%

Potential mechanisms for the genesis of Cenozoic domal structures on the NE Atlantic margin: pros, cons and some new ideas

Doré¹,

Lundin

Kusznir

et al. 2008

100

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“…In the central segment of the Vøring margin, HVLC with a thickness of up to 8 km has been mapped by many seismic refraction and reflection experiments, and additionally constrained using gravity data and isostatic modelling (e.g. Gernigon et al 2003Gernigon et al , 2004Ebbing et al 2006;Mjelde et al 2009a;Reynisson et al 2010). HVLC has also been detected on the Møre margin, south of the Jan Mayen Lineament, and in that area an additional zone has been detected in the east, close to the shelf edge (Kvarven et al 2014).…”

Section: Norwegian Marginmentioning

confidence: 99%

Controls on the location of compressional deformation on the NW European margin

Kimbell

Stewart

Gradmann

et al. 2016

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The distribution of Cenozoic compressional structures along the NW European margin has been compared with maps of the thickness of the crystalline crust derived from a compilation of seismic refraction interpretations and gravity modelling, and with the distribution of high-velocity lower crust and/or partially serpentinized upper mantle detected by seismic experiments. Only a subset of the mapped compressional structures coincide with areas susceptible to lithospheric weakening as a result of crustal hyperextension and partial serpentinization of the upper mantle. Notably, partially serpentinized upper mantle is well documented beneath the central part of the southern Rockall Basin, but compressional features are sparse in that area. Where compressional structures have formed but the upper mantle is not serpentinized, simple rheological modelling suggests an alternative weakening mechanism involving ductile lower crust and lithospheric decoupling. The presence of pre-existing weak zones (associated with the properties of the gouge and overpressure in fault zones) and local stress magnitude and orientation are important contributing factors.Gold Open Access: This article is published under the terms of the CC-BY 3.0 license.

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The mid-Norwegian margin: a discussion of crustal lineaments, mafic intrusions, and remnants of the Caledonian root by 3D density modelling and structural interpretation

Cited by 65 publications

References 42 publications

Extension, hyperextension and mantle exhumation offshore Norway: a discussion based on 6 crustal transects

Extension, hyperextension and mantle exhumation offshore Norway: a discussion based on 6 crustal transects

Potential mechanisms for the genesis of Cenozoic domal structures on the NE Atlantic margin: pros, cons and some new ideas

Controls on the location of compressional deformation on the NW European margin

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