INTERACTION BETWEEN CONTINENTAL LITHOSPHERE AND THE ICELAND PLUME-SR-ND-PB ISOTOPE GEOCHEMISTRY OF TERTIARY BASALTS, NE GREENLAND

Volcanic rocks associated with Atlantic opening in northern east Green land (73-76-degrees-N) form a approximately 1-km thickness of basaltic lavas located on the coast some 400 km north of the major basalt accu mulations of the Blosseville Coast (< 70-degrees-N). The Lower Lava Se ries, which makes up the lower half of the sequence at Hold with Hope and all of that at Wollaston Forland, is composed of homogeneous quart z tholeiites (5-8% MgO). These are mildly light rare earth element (LR EE) enriched (La/Yb(N) 22.06 +/- 0.45, 1 S.D.) and show strong chemica l and Pb-Nd-Sr isotopic similarities to Icelandic tholeiites. They are distinguished from Atlantic mid-ocean ridge basalt (MORB) in having l ess radiogenic Pb and Nd, higher DELTA8/4 and lower DELTA7/4, and depl etion in K and Rb relative to other incompatible elements, and show no evidence of a MORB asthenosphere component in their source. A single nephelinite in the Lower Series has essentially similar isotopic chara cteristics and K, Rb depletion. The tholeiites were derived from the h ot head of the Iceland plume, which had spread laterally within the up per mantle, and represent large melt fractions (15-20%) from spinel-fa cies mantle combined with small melt fractions (approximately 2.2%) fr om the garnet facies. Pb isotopic data indicate that the Iceland plume contains no MORB asthenospheric component, and is therefore most unli kely to arise from enriched streaks in the convecting upper mantle. Th e K, Rb depletion is shared with the HIMU ocean islands, and suggests a similar origin for the Iceland plume in subduction-processed oceanic crust. The relatively low Pb-206/Pb-204 ratios, and near-MORB Sr-Nd i sotopes, suggest that Iceland overlies an immature HIMU plume. The con formably overlying upper half of the Hold with Hope sequence (the Uppe r Lava Series) is extremely heterogeneous, being mainly olivine and qu artz tholeiites (4.5-9.5% MgO in inferred melt compositions, and up to 27% in accumulative lavas), with occasional undersaturated compositio ns. The latter are concentrated near the base of the Upper Series, and are associated with strongly incompatible-element-enriched tholeiites . These enriched samples have La/Yb(N) from 7.3 to 28.5, with most tho leiites - 13, and the undersaturated rocks > 23. They are isotopically heterogeneous, with a basanite resembling Icelandic compositions, and an alkali basalt having much less radiogenic Pb and Nd. The bulk of t he Upper Series tholeiites has a limited La/Yb(N) range (4.7-7.3) but a wide range in isotope ratios, from almost Icelandic values to Sr-87/ Sr-86(50)=7100, Pb-206/Pb-204(50) = 18.7, and Nd-143/Nd-144(50) = 0.51 247. This isotopic range is well correlated with SiO2, Ce/Pb, and K/Nb , in a manner suggesting crustal assimilation-fractional crystallizati on (AFC) relationships. The mantle-derived end-member of the Upper Ser ies is displaced to slightly less radiogenic Nd than the Lower Series samples, perhaps through mixing with a small component from the subcon tinental lithospheric mantle. A larger proportion of this melt was der ived from garnet-facies mantle than for Lower Series samples, and melt fractions were smaller in both garnet and spinel stability fields. As isotopic compositions similar to those of Icelandic lavas are found i n each of the three stratigraphic groups (Lower Series, basal enriched Upper Series, and normal Upper Series tholeiites), the range in incom patible element enrichment exemplified by La/Yb(N), correlated with Si saturation, is taken to reflect averaged degree of partial melting. L arge average melt fractions from the Icelandic plume that form the Low er Series lavas were probably generated to the east of the present out crop, where extensive lithospheric thinning related to Mesozoic riftin g permitted ascent of the plume head to high levels. Increasing melt f ractions upward through the Upper Series are thought to result from th e progressive disruption of the lithospheric mantle under NE Greenland by continued plume-induced rifting and by penetration of melts from t he plume head. The more homogeneous upper part of the Upper Series ind icates extensive melting in a section of the plume head which had entr ained minor lithospheric material. The melts subsequently ponded in th e continental crust and underwent accumulation, assimilation, and frac tionation.