Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening

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Standard

Structure of the SE Greenland margin from seismic reflection and refraction data : Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening. / Hopper, John R.; Dahl-Jesnen, Trine; Holbrook, W. Steven; Larsen, Hans Christian; Lizarralde, Dan; Korenaga, Jun; Kent, Graham M.; Kelemen, Peter B.

I: Journal of Geophysical Research: Solid Earth, Bind 108, Nr. 5, 10.05.2003, s. EPM 13-1 - 13-22.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Hopper, JR, Dahl-Jesnen, T, Holbrook, WS, Larsen, HC, Lizarralde, D, Korenaga, J, Kent, GM & Kelemen, PB 2003, 'Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening', Journal of Geophysical Research: Solid Earth, bind 108, nr. 5, s. EPM 13-1 - 13-22.

APA

Hopper, J. R., Dahl-Jesnen, T., Holbrook, W. S., Larsen, H. C., Lizarralde, D., Korenaga, J., Kent, G. M., & Kelemen, P. B. (2003). Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening. Journal of Geophysical Research: Solid Earth, 108(5), EPM 13-1 - 13-22.

Vancouver

Hopper JR, Dahl-Jesnen T, Holbrook WS, Larsen HC, Lizarralde D, Korenaga J o.a. Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening. Journal of Geophysical Research: Solid Earth. 2003 maj 10;108(5):EPM 13-1 - 13-22.

Author

Hopper, John R. ; Dahl-Jesnen, Trine ; Holbrook, W. Steven ; Larsen, Hans Christian ; Lizarralde, Dan ; Korenaga, Jun ; Kent, Graham M. ; Kelemen, Peter B. / Structure of the SE Greenland margin from seismic reflection and refraction data : Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening. I: Journal of Geophysical Research: Solid Earth. 2003 ; Bind 108, Nr. 5. s. EPM 13-1 - 13-22.

Bibtex

@article{acadb2796efe42e992c60a8c1f99c1e5,
title = "Structure of the SE Greenland margin from seismic reflection and refraction data: Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening",
abstract = "Seismic reflection and refraction data from the SE Greenland margin provide a detailed view of a volcanic rifted margin from Archean continental crust to near-to-average oceanic crust over a spatial scale of 400 km. The SIGMA III transect, located ∼600 km south of the Greenland-Iceland Ridge and the presumed track of the Iceland hot spot, shows that the continent-ocean transition is abrupt and only a small amount of crustal thinning occurred prior to final breakup. Initially, 18.3 km thick crust accreted to the margin and the productivity decreased through time until a steady state ridge system was established that produced 8-10 km thick crust. Changes in the morphology of the basaltic extrusives provide evidence for vertical motions of the ridge system, which was close to sea level for at least 1 m.y. of subaerial spreading despite a reduction in productivity from 17 to 13.5 km thick crust over this time interval. This could be explained if a small component of active upwelling associated with thermal buoyancy from a modest thermal anomaly provided dynamic support to the rift system. The thermal anomaly must be exhaustible, consistent with recent suggestions that plume material was emplaced into a preexisting lithospheric thin spot as a thin sheet. Exhaustion of the thin sheet led to rapid subsidence of the spreading system and a change from subaerial, to shallow marine, and finally to deep marine extrusion in ∼2 m.y. is shown by the morphological changes. In addition, comparison to the conjugate Hatton Bank shows a clear asymmetry in the early accretion history of North Atlantic oceanic crust. Nearly double the volume of material was emplaced on the Greenland margin compared to Hatton Bank and may indicate east directed ridge migration during initial opening.",
keywords = "Asymmetric spreading, Continental breakup, Greenland margin, Mantle dynamics, Volcanic rifted margin",
author = "Hopper, {John R.} and Trine Dahl-Jesnen and Holbrook, {W. Steven} and Larsen, {Hans Christian} and Dan Lizarralde and Jun Korenaga and Kent, {Graham M.} and Kelemen, {Peter B.}",
year = "2003",
month = may,
day = "10",
language = "English",
volume = "108",
pages = "EPM 13--1 -- 13--22",
journal = "Journal of Geophysical Research: Solid Earth",
issn = "0148-0227",
publisher = "American Geophysical Union",
number = "5",

}

RIS

TY - JOUR

T1 - Structure of the SE Greenland margin from seismic reflection and refraction data

T2 - Implications for nascent spreading center subsidence and asymmetric crustal accretion during North Atlantic opening

AU - Hopper, John R.

AU - Dahl-Jesnen, Trine

AU - Holbrook, W. Steven

AU - Larsen, Hans Christian

AU - Lizarralde, Dan

AU - Korenaga, Jun

AU - Kent, Graham M.

AU - Kelemen, Peter B.

PY - 2003/5/10

Y1 - 2003/5/10

N2 - Seismic reflection and refraction data from the SE Greenland margin provide a detailed view of a volcanic rifted margin from Archean continental crust to near-to-average oceanic crust over a spatial scale of 400 km. The SIGMA III transect, located ∼600 km south of the Greenland-Iceland Ridge and the presumed track of the Iceland hot spot, shows that the continent-ocean transition is abrupt and only a small amount of crustal thinning occurred prior to final breakup. Initially, 18.3 km thick crust accreted to the margin and the productivity decreased through time until a steady state ridge system was established that produced 8-10 km thick crust. Changes in the morphology of the basaltic extrusives provide evidence for vertical motions of the ridge system, which was close to sea level for at least 1 m.y. of subaerial spreading despite a reduction in productivity from 17 to 13.5 km thick crust over this time interval. This could be explained if a small component of active upwelling associated with thermal buoyancy from a modest thermal anomaly provided dynamic support to the rift system. The thermal anomaly must be exhaustible, consistent with recent suggestions that plume material was emplaced into a preexisting lithospheric thin spot as a thin sheet. Exhaustion of the thin sheet led to rapid subsidence of the spreading system and a change from subaerial, to shallow marine, and finally to deep marine extrusion in ∼2 m.y. is shown by the morphological changes. In addition, comparison to the conjugate Hatton Bank shows a clear asymmetry in the early accretion history of North Atlantic oceanic crust. Nearly double the volume of material was emplaced on the Greenland margin compared to Hatton Bank and may indicate east directed ridge migration during initial opening.

AB - Seismic reflection and refraction data from the SE Greenland margin provide a detailed view of a volcanic rifted margin from Archean continental crust to near-to-average oceanic crust over a spatial scale of 400 km. The SIGMA III transect, located ∼600 km south of the Greenland-Iceland Ridge and the presumed track of the Iceland hot spot, shows that the continent-ocean transition is abrupt and only a small amount of crustal thinning occurred prior to final breakup. Initially, 18.3 km thick crust accreted to the margin and the productivity decreased through time until a steady state ridge system was established that produced 8-10 km thick crust. Changes in the morphology of the basaltic extrusives provide evidence for vertical motions of the ridge system, which was close to sea level for at least 1 m.y. of subaerial spreading despite a reduction in productivity from 17 to 13.5 km thick crust over this time interval. This could be explained if a small component of active upwelling associated with thermal buoyancy from a modest thermal anomaly provided dynamic support to the rift system. The thermal anomaly must be exhaustible, consistent with recent suggestions that plume material was emplaced into a preexisting lithospheric thin spot as a thin sheet. Exhaustion of the thin sheet led to rapid subsidence of the spreading system and a change from subaerial, to shallow marine, and finally to deep marine extrusion in ∼2 m.y. is shown by the morphological changes. In addition, comparison to the conjugate Hatton Bank shows a clear asymmetry in the early accretion history of North Atlantic oceanic crust. Nearly double the volume of material was emplaced on the Greenland margin compared to Hatton Bank and may indicate east directed ridge migration during initial opening.

KW - Asymmetric spreading

KW - Continental breakup

KW - Greenland margin

KW - Mantle dynamics

KW - Volcanic rifted margin

UR - http://www.scopus.com/inward/record.url?scp=0041382666&partnerID=8YFLogxK

M3 - Journal article

AN - SCOPUS:0041382666

VL - 108

SP - EPM 13-1 - 13-22

JO - Journal of Geophysical Research: Solid Earth

JF - Journal of Geophysical Research: Solid Earth

SN - 0148-0227

IS - 5

ER -

ID: 355634113