Processes in High-Mg, High-T Magmas: Evidence from Olivine, Chromite and Glass in Palaeogene Picrites from West Greenland

doi:10.1093/petrology/41.7.1071

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Journal of Petrology Volume 41 Number 7 Pages 1071-1098 2000
© Oxford University Press 2000

Processes in High-Mg, High-T Magmas: Evidence from Olivine, Chromite and Glass in Palaeogene Picrites from West Greenland

LOTTE M. LARSEN¹^,* and ASGER K. PEDERSEN²

¹GEOLOGICAL SURVEY OF DENMARK AND GREENLAND, THORAVEJ 8, DK-2400 COPENHAGEN NV, DENMARK
²GEOLOGICAL MUSEUM, ØSTER VOLDGADE 5–7, DK-1350 COPENHAGEN K, DENMARK

Uncontaminated volcanic rocks from the 60 Ma Vaigat Formation,West Greenland, contain 6·5–30 wt % MgO, averaging15·5 wt % MgO. Olivine (mg-number 77·4–93·3)forms diverse assemblages of zoned phenocrysts and xenocrystsshowing evidence for equilibrium and fractional crystallization,oxidation, partial to complete re-equilibration, as well asmagma mixing. The olivine crystals contain glass inclusionsand have high contents of Ca and Cr, indicating that all olivineswith up to mg-number 93·0 crystallized from melts. Associatedchromites (mg-number 45·4–77·2) are essentiallyunzoned and in equilibrium with the olivines. Matrix glassesfrom pillow breccias have 6·7–8·8 wt % MgOand quenched close to 1200°C with oxidation states one log-unitabove the NNO (nickel–nickel oxide) buffer. Compositionaldifferences between the glasses from different volcanic membersare inherited from the primary melts. The magmas erupted ascrystal-charged melts, and liquids with more than $~$ 14 wt % MgOwere not erupted. The compositions of the unerupted parentalmelts were calculated by stepwise addition of equilibrium olivineto the matrix glasses, and these melts had 20–21 wt %MgO and liquidus temperatures of 1515–1560°C. Theyhad lower FeO^* than the erupted rocks with 20–21 wt %MgO because the rocks contain more iron-rich olivine than themelts would have had. The accumulated primary melts ascendedthrough a lithospheric lid of $~$ 100 km thickness, and we envisagethat major crystallization took place from $~$ 45 km depth and tothe surface. Magma batches ascended in narrow dyke-like conduitsand fractionated high-Mg olivine and chromite at deep levelsand less magnesian crystals at shallower levels. At high ascentvelocities numerous olivine crystals were carried in suspensionto the surface, even some from deep levels, whereas during slowerascent most olivines settled out before eruption. Pulsatingascent rates led to mixing of magma batches in various stagesof fractionation. On average, 13 wt % olivine was left withinthe crust, presumably as olivine-plated conduit walls. The conduitsystems are similar to the crystal-rich narrow magma chamberssuggested for mid-ocean ridges but are of much greater verticalextent.

KEY WORDS: chromite; glass; Greenland; olivine; picrite

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