Moho and basement depth in the NE Atlantic Ocean based on seismic refraction data and receiver functions

Funck, Thomas; Geissler, Wolfram; Kimbell, G. S.; Gradmann, Sofie; Gaina, Carmen; McDermott, Ken; Petersen, Uni K.

doi:10.1144/sp447.1

Cited by 45 publications

(44 citation statements)

References 156 publications

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“…The mid-Norwegian margin is densely sampled by seismic refraction lines (see figure 2 in Funck et al 2016) but individual profiles are rather short and do not cover the entire margin from the proximal to the distal domain. Hence, composite profiles were constructed to illustrate the crustal structure of the three margin segments (Fig.…”

Section: Mid-norwegian Continental Marginmentioning

confidence: 99%

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A review of the NE Atlantic conjugate margins based on seismic refraction data

Funck

Gaina

Geissler

et al. 2016

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The NE Atlantic region evolved through several rift episodes, leading to break-up in the Eocene that was associated with voluminous magmatism along the conjugate margins of East Greenland and NW Europe. Existing seismic refraction data provide good constraints on the overall tectonic development of the margins, despite data gaps at the NE Greenland shear margin and the southern Jan Mayen microcontinent. The maximum thickness of the initial oceanic crust is 40 km at the Greenland-Iceland-Faroe Ridge, but decreases with increasing distance to the Iceland plume. High-velocity lower crust interpreted as magmatic underplating or sill intrusions is observed along most margins but disappears north of the East Greenland Ridge and the Lofoten margin, with the exception of the Vestbakken Volcanic Province at the SW Barents Sea margin. South of the narrow Lofoten margin, the European side is characterized by wide margins. The opposite trend is seen in Greenland, with a wide margin in the NE and narrow margins elsewhere. The thin crust beneath the basins is generally underlain by rocks with velocities of .7 km s 21 interpreted as serpentinized mantle in the Porcupine and southern Rockall basins; while off Norway, alternative interpretations such as eclogite bodies and underplating are also discussed.Gold Open Access: This article is published under the terms of the CC-BY 3.0 license.

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Section: Mid-norwegian Continental Marginmentioning

confidence: 99%

“…Conjugate margin transects are compiled to present the full rift system and to check for any inconsistencies in the models or interpretations. A full listing of the available seismic refraction lines in the study region is given in Funck et al (2016, their fig. 2 and table 1).…”

mentioning

confidence: 99%

A review of the NE Atlantic conjugate margins based on seismic refraction data

Funck

Gaina

Geissler

et al. 2016

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“…5), and the seafloor spreading rates and asymmetry (Fig. 4), are described in detail in Funck et al (2016) and Gaina et al (this volume, in review).…”

Section: Region I: South Of Iceland and North Of The Bight Fracture Zonementioning

confidence: 99%

“…These conditions would suggest that the identified bathymetric features might be oceanic core complexes (OCC). Oceanic core complexes are bathymetric features composed (1) the magnetic anomaly grid (Gaina et al, this volume, in review); (2) the crustal thickness derived from seismic refraction data (Funck et al 2016); (3) the crustal thickness from gravity inversion (Haase et al, this volume, in press); (4) half seafloor spreading rates; and (5) seafloor spreading asymmetry (Gaina et al, this volume, in review of mantle rocks exposed on the seafloor by large detachment faulting. These tectonic features can have lengths up to 150 km and widths up to 15 km, with a height of between 500 and 1500 km (MacLeod et al 2009).…”

Section: Soifs and Oceanic Crust Formationmentioning

confidence: 99%

Seamounts and oceanic igneous features in the NE Atlantic: a link between plate motions and mantle dynamics

Gaina

Blischke

Geissler

et al. 2016

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A new regional compilation of seamount-like oceanic igneous features (SOIFs) in the NE Atlantic points to three distinct oceanic areas of abundant seamount clusters. Seamounts on oceanic crust dated 54-50 Ma are formed on smooth oceanic basement, which resulted from high spreading rates and magmatic productivity enhanced by higher than usual mantle plume activity. Late Eocene-Early Miocene SOIF clusters are located close to newly formed tectonic features on rough oceanic crust in the Irminger, Iceland and Norway basins, reflecting an unstable tectonic regime prone to local readjustments of mid-ocean ridge and fracture zone segments accompanied by extra igneous activity. A SOIF population observed on Mid-Miocene-Present rough oceanic basement in the Greenland and Lofoten basins, and on conjugate Kolbeinsey Ridge flanks, coincides with an increase in spreading rate and magmatic productivity. We suggest that both tectonic/kinematic and magmatic triggers produced Mid-Miocene-Present SOIFs, but the Early Miocene westwards ridge relocation may have played a role in delaying SOIF formation south of the Jan Mayen Fracture Zone. We conclude that Iceland plume episodic activity combined with regional changes in relative plate motion led to local mid-ocean ridge readjustments, which enhanced the likelihood of seamount formation.

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“…Funck et al (2016a) undertook a review and compilation of all existing refraction profiles in the NE Atlantic. The resulting seismic refraction database, combined with results from receiver functions and gravity information, was then used to compile various maps, such as the top-basement and Moho depths (Funck et al 2016b), from which a crustal thickness map was derived, providing a consistent comparison of conjugate and alongstrike variations in structure.…”

Section: Crustal Structurementioning

confidence: 99%