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The Iceland Microcontinent and a continental Greenland-Iceland-Faroe Ridge

Foulger, Gillian R.; Doré, Tony; Emeleus, C. Henry; Franke, Dieter; Geoffroy, Laurent; Gernigon, Laurent; Hey, Richard; Holdsworth, Robert E.; Hole, Malcolm; Höskuldsson, Ármann; Julian, Bruce; Kusznir, Nick; Martinez, Fernando; McCaffrey, Ken J.W.; Natland, James H.; Peace, Alex; Petersen, Kenni; Schiffer, Christian; Stephenson, Randell; Stoker, Martyn

The Iceland Microcontinent and a continental Greenland-Iceland-Faroe Ridge Thumbnail


Authors

Gillian R. Foulger

Tony Doré

C. Henry Emeleus

Dieter Franke

Laurent Geoffroy

Laurent Gernigon

Richard Hey

Robert E. Holdsworth

Malcolm Hole

Ármann Höskuldsson

Bruce Julian

Nick Kusznir

Fernando Martinez

James H. Natland

Alex Peace

Kenni Petersen

Christian Schiffer

Randell Stephenson

Martyn Stoker



Abstract

The breakup of Laurasia to form the Northeast Atlantic Realm was the culmination of a long period of tectonic unrest extending back to the Late Palaeozoic. Breakup was prolonged and complex and disintegrated an inhomogeneous collage of cratons sutured by cross-cutting orogens. Volcanic rifted margins formed, which are blanketed by lavas and underlain variously by magma-inflated, extended continental crust and mafic high-velocity lower crust of ambiguous and probably partly continental provenance. New rifts formed by diachronous propagation along old zones of weakness. North of the Greenland-Iceland-Faroe Ridge the newly forming rift propagated south along the Caledonian suture. South of the Greenland-Iceland-Faroe Ridge it propagated north through the North Atlantic Craton along an axis displaced ~ 150 km to the west of the northern rift. Both propagators stalled where the confluence of the Nagssugtoqidian and Caledonian orogens formed a transverse barrier. Thereafter, the ~ 400-km-wide latitudinal zone between the stalled rift tips extended in a distributed, unstable manner along multiple axes of extension that frequently migrated or jumped laterally with shearing occurring between them in diffuse transfer zones. This style of deformation continues to the present day. It is the surface expression of underlying magma-assisted stretching of ductile mid- and lower continental crust which comprises the Icelandic-type lower crust that underlies the Greenland-Iceland-Faroe Ridge. This, and probably also one or more full-crustal-thickness microcontinents incorporated in the Ridge, are capped by surface lavas. The Greenland-Iceland-Faroe Ridge thus has a similar structure to some zones of seaward-dipping reflectors. The contemporaneous melt layer corresponds to the 3–10 km thick Icelandic-type upper crust plus magma emplaced in the ~ 10–30-km-thick Icelandic-type lower crust. This model can account for seismic and gravity data that are inconsistent with a gabbroic composition for Icelandic-type lower crust, and petrological data that show no reasonable temperature or source composition could generate the full ~ 40-km thickness of Icelandic-type crust observed. Numerical modeling confirms that extension of the continental crust can continue for many tens of Myr by lower-crustal flow from beneath the adjacent continents. Petrological estimates of the maximum potential temperature of the source of Icelandic lavas are up to 1450 °C, no more than ~ 100 °C hotter than MORB source. The geochemistry is compatible with a source comprising hydrous peridotite/pyroxenite with a component of continental mid- and lower crust. The fusible petrology, high source volatile contents, and frequent formation of new rifts can account for the true ~ 15–20 km melt thickness at the moderate temperatures observed. A continuous swathe of magma-inflated continental material beneath the 1200-km-wide Greenland-Iceland-Faroe Ridge implies that full continental breakup has not yet occurred at this latitude. Ongoing tectonic instability on the Ridge is manifest in long-term tectonic disequilibrium on the adjacent rifted margins and on the Reykjanes Ridge, where southerly migrating propagators that initiate at Iceland are associated with diachronous swathes of unusually thick oceanic crust. Magmatic volumes in the NE Atlantic Realm have likely been overestimated and the concept of a monogenetic North Atlantic Igneous Province needs to be reappraised. A model of complex, piecemeal breakup controlled by pre-existing structures that produces anomalous volcanism at barriers to rift propagation and distributes continental material in the growing oceans fits other oceanic regions including the Davis Strait and the South Atlantic and West Indian oceans.

Citation

Foulger, G. R., Doré, T., Emeleus, C. H., Franke, D., Geoffroy, L., Gernigon, L., …Stoker, M. (2020). The Iceland Microcontinent and a continental Greenland-Iceland-Faroe Ridge. Earth-Science Reviews, 206, Article 102926. https://doi.org/10.1016/j.earscirev.2019.102926

Journal Article Type Article
Acceptance Date Aug 8, 2019
Online Publication Date Aug 9, 2019
Publication Date 2020-07
Deposit Date Sep 2, 2019
Publicly Available Date Aug 9, 2020
Journal Earth-Science Reviews
Print ISSN 0012-8252
Publisher Elsevier
Peer Reviewed Peer Reviewed
Volume 206
Article Number 102926
DOI https://doi.org/10.1016/j.earscirev.2019.102926
Public URL https://durham-repository.worktribe.com/output/1288951

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