Palaeogene Continental to Oceanic Magmatism on the SE Greenland Continental Margin at 63{degrees}N: a Review of the Results of Ocean Drilling Program Legs 152 and 163

doi:10.1093/petrology/41.7.951

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Journal of Petrology Volume 41 Number 7 Pages 951-966 2000
© Oxford University Press 2000

Palaeogene Continental to Oceanic Magmatism on the SE Greenland Continental Margin at 63°N: a Review of the Results of Ocean Drilling Program Legs 152 and 163

J. G. FITTON¹^,*, L. M. LARSEN², A. D. SAUNDERS³, B. S. HARDARSON¹^,4 and P. D. KEMPTON⁵

¹DEPARTMENT OF GEOLOGY AND GEOPHYSICS, UNIVERSITY OF EDINBURGH, WEST MAINS ROAD, EDINBURGH EH9 3JW, UK
²GEOLOGICAL SURVEY OF DENMARK AND GREENLAND, THORAVEJ 8, DK-2400 COPENHAGEN NV, DENMARK
³DEPARTMENT OF GEOLOGY, UNIVERSITY OF LEICESTER, LEICESTER LE1 7RH, UK
⁴SCOTTISH UNIVERSITIES ENVIRONMENTAL RESEARCH CENTRE, EAST KILBRIDE G75 0QF, UK
⁵NERC ISOTOPE GEOSCIENCES LABORATORY, KEYWORTH, NOTTINGHAM NG12 5GG, UK

Drilling along a 63°N transect off SE Greenland during OceanDrilling Program (ODP) Legs 152 and 163 recovered a successionof volcanic rocks representing all stages in the break-up ofthe volcanic rifted margin. The rocks range from pre-break-upcontinental tholeiitic flood basalt, through syn-break-up picrite,to truly oceanic basalt forming the main part of the seaward-dippingreflector sequence (SDRS). All the lava flows recovered fromthe transect were erupted in a subaerial environment. ⁴⁰Ar–³⁹Ardating shows that the earliest magmas were erupted at $~$ 61 Maand has confirmed that the main part of the SDRS was eruptedduring C24r (56–53 Ma) following continental break-up.Magma represented by the pre-break-up lava flows was storedin crustal reservoirs where it evolved by fractional crystallizationand assimilation of continental crust. Trace element and radiogenicisotope data show that the contaminant changed, through time,from lower-crustal granulite to a mixture of granulite and amphibolite,suggesting storage of magma at progressively shallower levelsin the crust. The degree of contamination declined rapidly asbreak-up proceeded, and the youngest rocks sampled in the transectare uncontaminated by continental basement. Variation of, forexample, Sc/Zr and Sm/Lu through the succession suggests a shallowingof the top of the mantle melting zone, accompanied by an increasein the average degree of melting with time from $~$ 4% to $~$ 12%. Thesemodest degrees of melting imply mantle temperatures only $~$ 100°Chotter than normal upper mantle. Upwelling mantle must thereforehave been fed dynamically to the melt zone to generate the igneouscrust of 18 km thickness deduced from seismic and gravity studies.N-MORB-like magmas dominated the earliest part of the successionalthough a few flows of ‘Icelandic’ basalt wereerupted in the pre-break-up phase. In contrast, the post-break-upmagmas had an Icelandic mantle source. This suggests that thedeveloping head of the ancestral Iceland plume was compositionallyzoned, with a core of Icelandic mantle surrounded by a thickouter zone of hot, depleted upper mantle.

KEY WORDS: flood basalt; geochemistry; Greenland; Palaeogene; Sr–Nd–Pb isotopes

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