Trace element and Nd-Sr isotopic composition of ultramafic lamprophyres from the East Antarctic Beaver Lake area

The trace element and Nd-Sr isotopic compositions of Cretaceous (110-117 Ma ) ultramafic lamprophyres from the Beaver Lake area in East Antarctica, whi ch are developed as sill, dyke and plug intrusions. have been investigated. Rare earth elements of lamprophyres are strongly fractionated, with LREE > 100 times chondrite, whereas HREE are < 10 times chondrite, presumably ind icating the presence of residual garnet in the source region. A characteris tic feature of the Beaver Lake rocks is low concentrations of Zr and Hf (Zr , 50-150 ppm: Hf, 1.0-5.0 ppm) and to a lesser extent Nb (17-90 ppm) which cause strong negative anomalies in the normalized trace element patterns. E ruption age-corrected Nd isotope values vary within narrow ranges (epsilon Nd-(t) = + 2.1 to + 4.3), whereas Sr isotope values show more variation (Sr -87/Sr-86((t)) = 0.704336-0.706431), similar to the isotopic compositions o f other ultramafic lamprophyres. The genesis of the ultramafic lamprophyres is explained as a result of the gradual widening of the Lambert-Amery rift during the Phanerozoic. An increase in the geothermal gradient from cold c ontinental conditions beneath the Archean block to the west may have result ed in grazing of the peridotite solidus at depths greater than 110 km. The initial carbonate-rich melts migrated upwards and froze as carbonate-bearin g veins in the overlying lithosphere. Later upward and outward migration of the asthenosphere beneath the rift caused remelting of the veined region, resulting in melts of ultramafic lamprophyre composition with a mixed geoch emical abundance and isotope signature from carbonate-rich veins and deplet ed peridotite wall-rock. The CO2-rich component of the lamprophyres is deri ved principally from the vein assemblage, from which phlogopite gives rise to the variable Sr isotopes, and baddeleyite to the differing Zr and Hf abu ndances. The difference between the lamprophyre facies of the Beaver Lake i ntrusions can be explained by minor amounts of olivine and Cr-spinel fracti onation. (C) 2001 Elsevier Science B.V, All rights reserved.