Deep crustal structure and magmatic processes: the inception of seafloor spreading in the Norwegian-Greenland Sea

doi:10.1144/GSL.SP.1988.039.01.05

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Geological Society, London, Special Publications

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Geological Society, London, Special Publications; 1988; v. 39; p. 35-48;
DOI: 10.1144/GSL.SP.1988.039.01.05
© 1988 Geological Society of London

Dipping Reflectors and NE Atlantic Evolution

Deep crustal structure and magmatic processes: the inception of seafloor spreading in the Norwegian-Greenland Sea

J. C. Mutter & C. M. Zehnder

Lamont-Doherty Geological Observatory of Columbia University, Palisades, NY 10964-0190, USA
Department of Geological Sciences, Columbia University, New York, USA

An extensive investigation into the deep crustal structure ofthe conjugate Norwegian and E Greenland margins utilizing two-shipExpanded Spread and Wide Aperture CDP Profiling has led to theidentification of a unique suite of crustal structures developedduring the onset of seafloor spreading. On both margins, a regionof low velocity crust was found proximal to marginal escarpments.Immediately seaward of the low velocity crustal block seaward-dippingreflectors occur within thick crust that is interpreted to bewholly igneous, a product of voluminous melt production enhancedby convective partial melting processes. This earliest formedoceanic crust is actually several kilometres thicker than thelow velocity crust or the adjacent continental crust. Normaloceanic crustal thicknesses are not produced until about 5 Myafter the initiation of spreading when convective partial meltinghas abated and the magma budget has reduced. The extrusive unitreduces to normal thicknesses long before the intrusive andplutonic section, indicating that the thickening or thinningof oceanic crust is accomplished primarily by variations inthe latter.

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