John, Scherer, Haase & Schenk (2004): Earth and Planetary
Science Letters, 227, 441-456.
Trace element fractionation during fluid-induced eclogitization in
a subducting slab: trace element and Lu-Hf / Sm-Nd isotope
systematics
Spatially closely associated gabbros and eclogites of central
Zambia represent relics of subducted oceanic crust in a suture
zone. The eclogites, which formed at 630-690 °C and 2.6-2.8 GPa,
yield Lu-Hf ages between 607±14 and 659±14 Ma,
suggesting that subduction was active for at least 24 Myr. The trace
element- and isotope compositions of the gabbros and eclogites range
from those of incompatible-element depleted gabbros from the lower
oceanic crust to those of enriched ocean-island basalts. Several
eclogites display a large fractionation of the light rare earth
elements from heavy rare earth- and high field strength elements, an
effect that cannot be of magmatic origin but must have resulted from
the passage of fluids through the rocks during metamorphism. In some
samples, fluid pathways are marked by veins of eclogite facies
minerals. Garnet-whole rock ages based on the Sm-Nd (relatively
mobile) and Lu-Hf (relatively immobile) systems are identical,
consistent with light rare earth elements being fractionated during
eclogitization. Modeling using fluid-mineral partition coefficients
suggests that the fractionated rocks have reacted with an amount of
fluid equal up to 80% of their mass. The most likely source for such a
large volume of fluid is the serpentinized lithospheric mantle of the
subducting slab. The Zambian eclogites and their veins represent
relict fluid pathways through subducted oceanic crust and provide
direct evidence for channelized fluid flow and element transport
within a slab. The transformation of dry, metastable slab gabbros to
eclogites upon fluid-infiltration, accompanied by the transport of
fluid-mobile elements, could be responsible for generating the slab
component in arc magmas.
