The Role of Premagmatic Rifting in Shaping a Volcanic Continental Margin: An Example From the Eastern North American Margin

The Role of Premagmatic Rifting in Shaping a Volcanic Continental Margin: An Example From the Eastern North American Margin

Both magmatic and tectonic processes contribute to the formation of volcanic continental margins. Such margins are thought to undergo extension across a narrow zone of lithospheric thinning (~100 km). New observations based on existing and reprocessed data from the Eastern North American Margin cont...

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Veröffentlicht in:Journal of geophysical research. Solid earth 2020-11, Vol.125 (11), p.n/a, Article 2020
Hauptverfasser: Lang, G., Brink, U. S., Hutchinson, D. R., Mountain, G. S., Schattner, U.
Format: Artikel
Sprache:eng
Schlagworte:
Canyons
Central Atlantic
continental breakup
Continental margins
Crustal thickness
Drilling
Eastern North American Margin
Geochemistry & Geophysics
Geophysics
inherited rheology
Lithosphere
lithosphere thinning
Magma
Physical Sciences
Reflectors
Refraction
Rheological properties
Rheology
Rifting
Science & Technology
Sedimentation
Seismic data
Seismological data
Submarine banks
Tectonic processes
Tectonics
Thickness
Thinning
volcanic continental margin
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Zusammenfassung:Both magmatic and tectonic processes contribute to the formation of volcanic continental margins. Such margins are thought to undergo extension across a narrow zone of lithospheric thinning (~100 km). New observations based on existing and reprocessed data from the Eastern North American Margin contradict this hypothesis. With ~64,000 km of 2‐D seismic data tied to 40 wells combined with published refraction, deep reflection, receiver function, and onshore drilling efforts, we quantified along‐strike variations in the distribution of rift structures, magmatism, crustal thickness, and early post‐rift sedimentation under the shelf of Baltimore Canyon Trough (BCT), Long Island Platform, and Georges Bank Basin (GBB). Results indicate that BCT is narrow (80–120 km) with a sharp basement hinge and few rift basins. The seaward dipping reflectors (SDR) there extend ~50 km seaward of the hinge line. In contrast, the GBB is wide (~200 km), has many syn‐rift structures, and the SDR there extend ~200 km seaward of the hinge line. Early post‐rift depocenters at the GBB coincide with thinner crust suggesting “uniform” thinning of the entire lithosphere. Models for the formation of volcanic margins do not explain the wide structure of the GBB. We argue that crustal thinning of the BCT was closely associated with late syn‐rift magmatism, whereas the broad thinning of the GBB segment predated magmatism. Correlation of these variations to crustal terranes of different compositions suggests that the inherited rheology determined the premagmatic response of the lithosphere to extension. Key Points Rift structure, crustal thickness, and distribution of breakup volcanism of the Eastern North American volcanic margin are presented Georges Bank Basin experienced substantial premagmatic thinning, whereas Baltimore Canyon Trough thinning was magma assisted Inherited distribution of crustal rheology determined the nature and intensity of premagmatic strain
ISSN:2169-9313
2169-9356
DOI:10.1029/2020JB019576