.Earth and Planetary Science Letters 154 1998 221–235 Depleted spinel harzburgite xenoliths in Tertiary dykes from East Greenland: Restites from high degree melting

A new collection of mantle xenoliths in Tertiary dykes from the Wiedemann Fjord area in Southeast Greenland shows that this part of the central Greenland craton is underlain by highly depleted peridotites. The samples are mostly spinel .harzburgites with highly forsteritic olivines Fo, average Fo. T...

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Bibliographic Details
Main Authors: Stefan Bernstein A, Peter B. Kelemen B, C. Kent Brooks A
Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
Published: 1997
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Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.487.9419
http://science.whoi.edu/labs/mclean210/kelemen/pages/Bernstein et al xen EPSL 98.pdf
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Summary:A new collection of mantle xenoliths in Tertiary dykes from the Wiedemann Fjord area in Southeast Greenland shows that this part of the central Greenland craton is underlain by highly depleted peridotites. The samples are mostly spinel .harzburgites with highly forsteritic olivines Fo, average Fo. This, together with unusually high modal olivine87 – 94 92.7 .contents 70–)95 % , places the Wiedemann harzburgites in a unique compositional field. Relative to depleted Kaapvaal harzburgites with comparable Fo in olivine, the Wiedemann samples have considerably lower bulk SiO average 42.6 wt%2.versus 44–49 wt %. Spinel compositions are similar to those in other sub-cratonic harzburgites. Pyroxene equilibrium temperatures average 8508C, which is above an Archaean cratonic geotherm at an inferred pressure of 1–2 GPa, but low enough so that it is unlikely that the xenoliths represent residual peridotites created during Tertiary magmatism. Among mantle samples, the Wiedemann harzburgites are, in terms of their bulk composition, most similar to harzburgites from the . .ophiolites of Papua New Guinea PNG and New Caledonia NC. One hypothesis is that the Wiedemann harzburgites, along with PNG and NC harzburgites, formed via dissolution of pyroxene from previously depleted peridotites, possibly beneath a volcanic arc. If so, higher spinel CrrAl in Wiedemann samples may reflect a deeper origin compared to PNG and NC peridotites. Alternatively, using proposed primitive mantle compositions as a protolith, the Wiedemann harzburgites can be modeled as the residue after extraction of some 40 % melt. The composition of this calculated hypothetical melt in terms of CaO, Al O, FeO, MgO and SiO is similar to published experimental data on high degree melts of peridotite at 2–32 3 2